Product Folder Sample & Buy Technical Documents Tools & Software Support & Community DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DRA75x, DRA74x Infotainment Applications Processor Silicon Revision 2.0 1 Device Overview 1.1 Features 1 • Architecture Designed for Infotainment Applications • Video, Image, and Graphics Processing Support – Full-HD Video (1920 × 1080p, 60 fps) – Multiple Video Input and Video Output – 2D and 3D Graphics • ARM® Dual Cortex®-A15 Microprocessor Subsystem • Up to two C66x™ Floating-Point VLIW DSP – Fully Object-Code Compatible With C67x™ and C64x+™ – Up to Thirty-two 16 x 16-Bit Fixed-Point Multiplies per Cycle • Up to 2.5MB of On-Chip L3 RAM • Level 3 (L3) and Level 4 (L4) Interconnects • Two DDR2/DDR3/DDR3L Memory Interface (EMIF) Modules – Supports up to DDR2-800 and DDR3-1066 – Up to 2GB Supported per EMIF • Two ARM® Dual Cortex®-M4 Image Processing Units (IPUs) • Up to Two Embedded Vision Engines (EVEs) • IVA Subsystem • Display Subsystem – Display Controller With DMA Engine and up to Three Pipelines – HDMI™ Encoder: HDMI 1.4a and DVI 1.0 Compliant • Video Processing Engine (VPE) • 2D-Graphics Accelerator (BB2D) Subsystem – Vivante™ GC320 Core • Dual-Core PowerVR® SGX544™ 3D GPU • Three Video Input Port (VIP) Modules – Support for up to 10 Multiplexed Input Ports • General-Purpose Memory Controller (GPMC) • Enhanced Direct Memory Access (EDMA) Controller • 2-Port Gigabit Ethernet (GMAC) • Sixteen 32-Bit General-Purpose Timers • 32-Bit MPU Watchdog Timer • Five Inter-Integrated Circuit (I2C) Ports • HDQ™/1-Wire® Interface • SATA Interface • Media Local Bus (MLB) Subsystem • Ten Configurable UART/IrDA/CIR Modules • Four Multichannel Serial Peripheral Interfaces (MCSPIs) • Quad SPI (QSPI) • Multichannel Audio Serial Port (MCASP) • SuperSpeed USB 3.0 Dual-Role Device • PCI-Express® 2.0 Subsystems With Two 5-Gbps Lanes – One 2-lane Gen2-Compliant Port – or Two 1-lane Gen2-Compliant Ports • Dual Controller Area Network (DCAN) Modules – CAN 2.0B Protocol • Up to 247 General-Purpose I/O (GPIO) Pins • Real-Time Clock Subsystem (RTCSS) • Devise security features – Hardware Crypto accelerators and DMA – Firewalls – JTAG lock – Secure keys – Secure ROM and boot • Power, Reset, and Clock Management • On-Chip Debug With CTools Technology • 28-nm CMOS Technology • 23 mm × 23 mm, 0.8-mm Pitch, 760-Pin BGA (ABC) 1 An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications, intellectual property matters and other important disclaimers. PRODUCTION DATA. DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 1.2 • • • • Applications Human-Machine Interface (HMI) Navigation Digital and Analog Radio Rear Seat Entertainment 1.3 www.ti.com • • • Multimedia Playback Web Browsing ADAS Integration Description DRA75x and DRA74x (Jacinto 6) infotainment applications processors are built to meet the intense processing needs of the modern infotainment-enabled automobile experiences. The device enables Original-Equipment Manufacturers (OEMs) and Original-Design Manufacturers (ODMs) to quickly implement innovative connectivity technologies, speech recognition, audio streaming, and more. Jacinto 6 devices bring high processing performance through the maximum flexibility of a fully integrated mixed processor solution. The devices also combine programmable video processing with a highly integrated peripheral set. Programmability is provided by dual-core ARM Cortex-A15 RISC CPUs with Neon™ extension, TI C66x VLIW floating-point DSP core, and Vision AccelerationPac (with one or more EVEs). The ARM allows developers to keep control functions separate from other algorithms programmed on the DSP and coprocessors, thus reducing the complexity of the system software. Additionally, TI provides a complete set of development tools for the ARM, DSP, and EVE coprocessor, including C compilers and a debugging interface for visibility into source code. The DRA75x and DRA74x Jacinto 6 processor family is qualified according to the AEC-Q100 standard. Device Information 2 PART NUMBER PACKAGE BODY SIZE DRA74x FCBGA (760) 23.0 mm × 23.0 mm DRA75x FCBGA (760) 23.0 mm × 23.0 mm Device Overview Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 1.4 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Functional Block Diagram Figure 1-1 is functional block diagram for the device. DRA75x / DRA74x (2x ARM Cortex–A15) Co-Processor DSP1 C66x Co-Processors GPU (Dual-Core SGX544 3D) VIP2 2x MMU sDMA LCD1 1xGFX / 3xVID Blend / Scale VIP3 VPE HD ATL 2x VCP Display Subsystem IPU1 (Dual Cortex–M4) (GC 320 2D) VIP1 EDMA DSP2 C66x Co-Processors BB2D Radio Accelerators 2x EVE Analytic Processors IVA HD 1080p Video MPU IPU2 (Dual Cortex–M4) LCD2 LCD3 HDMI 1.4a High-Speed Interconnect Connectivity System Spinlock Timers x16 1x USB 3.0 Mailbox x13 WDT FS/HS/SS Dual Mode w/PHY GPIO x8 RTC SS PWM SS x3 HDQ KBD 3x USB 2.0 Dual Mode FS/HS 1x w/ PHY 2x w/ ULPI QSPI McSPI x4 McASP x8 DCAN x2 I2C x5 MediaLB / MOST150 GMAC AVB Program/Data Storage Serial Interfaces UART x10 PCIe SS x2 MMC / SD x4 256KiB ROM up to 2.5MiB RAM w/ ECC GPMC / ELM SATA OCMC DMM EMIF x2 2x 32b (NAND/NOR/ DDR2/3 w/ECC(1) Async) intro_001 Figure 1-1. DRA75x, DRA74x Block Diagram (1) ECC is only available on EMIF1. Device Overview Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 3 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table of Contents 1 Device Overview ......................................... 1 7.12 Inter-Integrated Circuit Interface (I2C) ............. 260 1.1 Features .............................................. 1 1.2 Applications ........................................... 2 7.13 7.14 1.3 Description ............................................ 2 HDQ / 1-Wire Interface (HDQ1W) ................. 263 Universal Asynchronous Receiver Transmitter (UART) ............................................. 265 7.15 Multichannel Serial Peripheral Interface (MCSPI) 266 7.16 Quad Serial Peripheral Interface (QSPI) .......... Multichannel Audio Serial Port (McASP) .......... Universal Serial Bus (USB) ........................ Serial Advanced Technology Attachment (SATA) . 272 ........................... 3 Revision History ......................................... 5 Device Comparison ..................................... 6 3.1 Device Comparison Table ............................ 6 3.2 Related Products ..................................... 9 Terminal Configuration and Functions ............ 10 4.1 Terminal Assignment ................................ 10 4.2 Ball Characteristics .................................. 11 4.3 Multiplexing Characteristics ......................... 80 4.4 Signal Descriptions .................................. 98 Specifications ......................................... 140 5.1 Absolute Maximum Ratings........................ 140 5.2 ESD Ratings ....................................... 141 5.3 Power on Hour (POH) Limits ...................... 141 5.4 Recommended Operating Conditions ............. 143 5.5 Operating Performance Points ..................... 146 5.6 Power Consumption Summary .................... 167 5.7 Electrical Characteristics ........................... 168 5.8 Thermal Resistance Characteristics ............... 177 5.9 Power Supply Sequences ......................... 178 Clock Specifications ................................. 190 6.1 Input Clock Specifications ......................... 191 6.2 DPLLs, DLLs Specifications ....................... 199 1.4 2 3 4 5 6 7 Functional Block Diagram Timing Requirements and Switching Characteristics ........................................ 203 7.1 Timing Test Conditions ............................ 203 7.2 Interface Clock Specifications ..................... Timing Parameters and Information ............... 7.3 7.4 4 203 203 Recommended Clock and Control Signal Transition Behavior............................................ 205 7.17 7.18 7.19 7.20 8 298 300 Peripheral Component Interconnect Express (PCIe) .............................................. 300 7.21 Controller Area Network Interface (DCAN) ........ 301 7.22 Ethernet Interface (GMAC_SW) ................... 302 7.23 Media Local Bus (MLB) interface .................. 312 7.24 eMMC/SD/SDIO 7.25 General-Purpose Interface (GPIO) ................ 342 7.26 Audio Tracking Logic (ATL) ........................ 342 7.27 System and Miscellaneous interfaces ............. 343 7.28 Test Interfaces ..................................... 343 ................................... 315 Applications, Implementation, and Layout ...... 348 ........................................ 8.1 Introduction 8.2 Power Optimizations ............................... 349 8.3 Core Power Domains .............................. 363 8.4 Single-Ended Interfaces 8.5 Differential Interfaces 8.6 8.7 9 278 ........................... .............................. Clock Routing Guidelines .......................... 348 374 376 397 DDR2/DDR3 Board Design and Layout Guidelines .......................................... 399 Device and Documentation Support .............. 434 9.1 Device Nomenclature .............................. 434 9.2 Tools and Software ................................ 436 9.3 Documentation Support ............................ 436 9.4 Receiving Notification of Documentation Updates. 437 9.5 Related Links 9.6 Community Resources............................. 438 ...................................... 437 7.5 Virtual and Manual I/O Timing Modes ............. 205 7.6 Video Input Ports (VIP) ............................ 208 9.7 Trademarks ........................................ 438 7.7 7.8 Display Subsystem – Video Output Ports ......... 226 Display Subsystem – High-Definition Multimedia Interface (HDMI) ................................... 237 9.8 Electrostatic Discharge Caution 9.9 Export Control Notice .............................. 438 9.10 Glossary............................................ 438 7.9 External Memory Interface (EMIF)................. 237 7.10 General-Purpose Memory Controller (GPMC) ..... 237 7.11 Timers .............................................. 259 Table of Contents ................... 438 10 Mechanical Packaging and Orderable Information ............................................. 439 10.1 Mechanical Data ................................... 439 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 2 Revision History Changes from December 18, 2015 to April 14, 2016 (from * Revision (December 2015) to A Revision) • • • • • • • • • • • • • • • • • • • • • • • • • • Page Device security features are added in Device Overview section ............................................................... 1 Added ”Related Products” section .................................................................................................. 9 Added footnotes to the vout3_* signals which are muxed on vddshv6 power balls in Table 4-2 Ball Characteristics . 13 Added footnotes to the vout3_* signals which are muxed on vddshv6 power balls in Table 4-5 DSS Signal Descriptions ........................................................................................................................ 103 Signal Descriptions updated to remove redundancy .......................................................................... 106 Text in ESD Ratings table clarified .............................................................................................. 141 Note (5) in Table 5-7 is updated ................................................................................................. 148 Added “Power Consumption Summary” section ............................................................................... 167 Notes 9, 12 and 13 in Figure 5-1 are updated ................................................................................. 180 Notes 9, 12 and 13 in Figure 5-4 are updated ................................................................................. 187 Fixed some of the descriptions on GPMC and QSPI Manual Modes names in Table 7-2 “Modes Summary” ....... 205 Added new Manual Modes for: VOUT1, VOUT2 IOSET1, VOUT2 IOSET2 and VOUT3. Removed DSS_VIRTUAL1 ................................................................................................................... 205 New Timing information available for: Video Input Ports (VIP), Display Subsystem – Video Output Ports, Multichannel Serial Peripheral Interface (MCSPI), Quad Serial Peripheral Interface (QSPI) and eMMC/SD/SDIO. . 205 Corrected references for McASP Virtual modes in Table 7-2 “Modes Summary” ........................................ 205 Removed all vin4b_* signals from Table 7-9 Manual Functions Mapping for VIP2 ....................................... 216 A caution and two notes are added in “Display Subsystem – Video Output Ports“ section stating that VOUT signals are recommended to use the default SLEWCONTROL settings. Slow SLEWCONTROL should be used instead. .............................................................................................................................. 226 Flipped the "Parameter" entries for D5 and D6 in Table 7-16 ............................................................... 226 Added footnotes to the vout3_* signals which muxed on vddshv6 power balls in Table 7-18 VOUT3 IOSETs. ..... 229 A new caution is added in “Quad Serial Peripheral Interface” subsection ................................................. 272 QSPI time value Q7 direction on Figure 7-37 through Figure 7-40 is updated to start prior CS ....................... 274 Added Table 7-53 through Table 7-60 to clarify the MCASP Virtual Timing Mode usage ............................... 284 An update is performed in the “Peripheral Component Interconnect Express (PCIe)” section. ......................... 300 Updated information for TPS65917 as supported PMIC ..................................................................... 367 Aligning "Device and Documentation Support" section with new flow ...................................................... 434 Аdded SR 2.0 in Table 9-1 ....................................................................................................... 435 Added ”Related Links” section ................................................................................................... 437 Revision History Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 5 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 3 Device Comparison 3.1 Device Comparison Table Table 3-1 shows a comparison between devices, highlighting the differences. Table 3-1. Device Comparison Device Features Jacinto 6 EX Jacinto 6 EP Jacinto 6 DRA756 DRA755 DRA754 DRA752 DRA751 DRA750 DRA746 DRA745 DRA744 P L J P L J P L J Processors/ Accelerators Speed Grades MPU core 0 Yes Yes Yes MPU core 1 Yes Yes Yes DSP1 Yes Yes Yes DSP2 Yes Yes No BB2D Yes Yes Yes VOUT1 Yes Yes Yes VOUT2 Yes Yes Yes VOUT3 Yes Yes Yes HDMI Yes Yes Yes EVE1 Yes No No EVE2 Yes No No ARM Dual Cortex-M4 Image Processing Unit (IPU) IPU1 Yes Yes Yes IPU2 Yes Yes Yes Image Video Accelarator (IVA) IVA Yes Yes Yes SGX544 Dual-Core 3D Graphics Processing Unit (GPU) GPU Yes Yes Yes ARM Dual Cortex-A15 Microprocessor Subsystem (MPU) C66x VLIW DSP BitBLT 2D Hardware Acceleration Engine (BB2D) Display Subsystem Embedded Vision Engine (EVE) 6 Device Comparison Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 3-1. Device Comparison (continued) Device Features Jacinto 6 EX DRA756 DRA755 Jacinto 6 EP DRA754 DRA752 DRA751 Jacinto 6 DRA750 DRA746 DRA745 DRA744 vin1a Yes Yes vin1b Yes Yes No vin2a Yes Yes Yes vin2b Yes Yes Yes vin3a Yes Yes Yes vin3b Yes Yes Yes vin4a Yes Yes Yes vin4b Yes Yes Yes vin5a Yes Yes No vin6a Yes Yes No VPE Yes Yes Yes OCMC_RAM1 512KB 512KB 512KB OCMC_RAM2 1MB No No OCMC_RAM3 1MB No No GPMC Yes Yes Yes EMIF1 up to 2GB (with optional SECDED) up to 2GB (with optional SECDED) up to 2GB EMIF2 up to 2GB up to 2GB up to 2GB DMM Yes Yes Yes ATL Yes Yes Yes VCP1 Yes Yes Yes VCP2 Yes Yes Yes DCAN1 Yes Yes Yes DCAN2 Yes Yes Yes Enhanced DMA (EDMA) EDMA Yes Yes Yes System DMA (DMA_SYSTEM) DMA_SYSTEM Yes Yes Yes GMAC_SW[0] MII, RMII, or RGMII MII, RMII, or RGMII MII, RMII, or RGMII GMAC_SW[1] MII, RMII, or RGMII MII, RMII, or RGMII MII, RMII, or RGMII up to 247 up to 247 up to 247 VIP1 Video Input Port (VIP) VIP2 VIP3 Video Processing Engine (VPE) No Program/Data Storage On-Chip Shared Memory (RAM) General-Purpose Memory Controller (GPMC) DDR2/DDR3 Memory Controller (2) Dynamic Memory Manager (DMM) Radio Support Audio Tracking Logic (ATL) Viterbi Coprocessor (VCP) Peripherals Dual Controller Area Network Interface (DCAN) Ethernet Subsystem (Ethernet SS) General-Purpose I/O (GPIO) GPIO Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Device Comparison 7 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 3-1. Device Comparison (continued) Device Features Jacinto 6 EX DRA756 Inter-Integrated Circuit Interface (I2C) I2C System Mailbox Module MAILBOX Media Local Bus Subsystem (MLBSS) MLB Multichannel Audio Serial Port (McASP) MultiMedia Card/Secure Digital/Secure Digital Input Output Interface (MMC/SD/SDIO) PCI-Express 2.0 Port with Integrated PHY DRA755 5 Jacinto 6 EP DRA754 DRA752 DRA751 Jacinto 6 DRA750 5 DRA746 DRA745 13 13 13 Yes Yes Yes McASP1 16 serializers 16 serializers 16 serializers McASP2 16 serializers 16 serializers 16 serializers McASP3 4 serializers 4 serializers 4 serializers McASP4 4 serializers 4 serializers 4 serializers McASP5 4 serializers 4 serializers 4 serializers McASP6 4 serializers 4 serializers 4 serializers McASP7 4 serializers 4 serializers 4 serializers McASP8 4 serializers 4 serializers 4 serializers MMC1 1x UHSI 4b 1x UHSI 4b 1x UHSI 4b MMC2 1x eMMC 8b 1x eMMC 8b 1x eMMC 8b MMC3 1x SDIO 8b 1x SDIO 8b 1x SDIO 8b MMC4 1x SDIO 4b 1x SDIO 4b 1x SDIO 4b PCIe_SS1 Yes Yes Yes (Single-lane mode) PCIe_SS2 Yes Yes No SATA SATA Yes Yes Yes Real-Time Clock Subsystem (RTCSS) RTCSS Yes Yes Yes 4 4 4 Multichannel Serial Peripheral Interface (McSPI) McSPI HDQ1W HDQ1W Yes Yes Yes Quad SPI (QSPI) QSPI Yes Yes Yes Spinlock Module SPINLOCK Yes Yes Yes Keyboard Controller (KBD) KBD Yes Yes Yes Timers, General-Purpose TIMER 16 16 16 Timer, Watchdog WATCHDOG TIMER Yes Yes Yes PWMSS1 Yes Yes Yes PWMSS2 Yes Yes Yes PWMSS3 Yes Yes Yes 10 10 10 Pulse-Width Modulation Subsystem (PWMSS) Universal Asynchronous Receiver/Transmitter (UART) 8 Device Comparison DRA744 5 UART Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 3-1. Device Comparison (continued) Device Features Jacinto 6 EX DRA756 Universal Serial Bus (USB3.0) Universal Serial Bus (USB2.0) DRA755 Jacinto 6 EP DRA754 DRA752 DRA751 Jacinto 6 DRA750 DRA746 DRA745 USB1 (SuperSpeed, Dual-Role-Device [DRD]) Yes Yes Yes USB2 (HighSpeed, Dual-Role-Device [DRD], with embedded HS PHY) Yes Yes Yes USB3 (HighSpeed, OTG2.0, with ULPI) Yes Yes Yes USB4 (HighSpeed, OTG2.0, with ULPI) Yes Yes Yes(1) DRA744 (1) USB4 will not be supported on some pin-compatible roadmap devices. USB3 will be mapped to these balls instead. Pin compatibility can be maintained in the future by either not using USB4, or via software change to use USB4 on this device, but USB3 on these balls in the future. (2) In the Unified L3 memory map, there is maximum of 2GB of SDRAM space which is available to all L3 initiators including MPU (MPU, GPU, DSP, IVA, DMA, etc). Typically this space is interleaved across both EMIFs to optimize memory performance. If a system populates > 2GB of physical memory, that additional addressable space can be accessed only by the MPU via the ARM V7 Large Physical Address Extensions (LPAE). 3.2 Related Products Automotive Processors DRAx Infotainment SoCs The "Jacinto 6" family of infotainment processors (DRA7xx), paired with robust software and ecosystem offering bring unprecedented feature-rich, in-vehicle infotainment, instrument cluster and telematics features to the next generation automobiles. Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Device Comparison 9 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 4 Terminal Configuration and Functions 4.1 Terminal Assignment Figure 4-1 shows the ball locations for the 760 plastic ball grid array (PBGA) package and are used in conjunction with Table 4-2 through Table 4-34 to locate signal names and ball grid numbers. Figure 4-1. ABC S-PBGA-N760 Package (Bottom View) NOTE The following bottom balls are not connected: AF7 / AF10 / AF13 / AF16 / AF19 / AE4 / AE25 / AB26 / W3 / W26 / T3 / T26 / N3 / N26 / K3 / K26 / G3 / D4 / D25 / C10 / C13 / C16 / C19 / C22. These balls do not exist on the package. 4.1.1 Unused Balls Connection Requirements This section describes the Unused/Reserved balls connection requirements. NOTE The following balls are reserved: A27 / K14 / Y5 / Y10 / B28 These balls must be left unconnected. NOTE All unused power supply balls must be supplied with the voltages specified in the Section 5.4, Recommended Operating Conditions, unless alternative tie-off options are included in Section 4.4, Signal Descriptions. Table 4-1. Unused Balls Specific Connection Requirements 10 Balls Connection Requirements AE15 / AC15 / AE14 / D20 / AD17 / AC17 / AC16 / AB16 / V27 These balls must be connected to GND through an external pull resistor if unused E20 / D21 / E23 / C20 / C21 / AF14 / V28 / F18 These balls must be connect to the corresponding power supply through an external pull resistor if unused Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-1. Unused Balls Specific Connection Requirements (continued) Balls Connection Requirements AB17 These balls must be connected to F22 (porz) if unused NOTE All other unused signal balls with a Pad Configuration Register can be left unconnected with their internal pullup or pulldown resistor enabled. NOTE All other unused signal balls without Pad Configuration Register can be left unconnected. 4.2 Ball Characteristics Table 4-2 describes the terminal characteristics and the signals multiplexed on each ball. The following list describes the table column headers: 1. BALL NUMBER: Ball number(s) on the bottom side associated with each signal on the bottom. 2. BALL NAME: Mechanical name from package device (name is taken from muxmode 0). 3. SIGNAL NAME: Names of signals multiplexed on each ball (also notice that the name of the ball is the signal name in muxmode 0). NOTE Table 4-2 does not take into account the subsystem multiplexing signals. Subsystem multiplexing signals are described in Section 4.4, Signal Descriptions. NOTE In the Driver off mode, the buffer is configured in high-impedance. 4. 74x: This column shows if the functionality is applicable for DRA74x devices. Note that the ball characteristics table presents the functionality of DRA75x device. An empty box means "Yes". 5. MUXMODE: Multiplexing mode number: (a) MUXMODE 0 is the primary mode; this means that when MUXMODE=0 is set, the function mapped on the pin corresponds to the name of the pin. The primary muxmode is not necessarily the default muxmode. NOTE The default mode is the mode at the release of the reset; also see the RESET REL. MUXMODE column. (b) MUXMODE 1 through 15 are possible muxmodes for alternate functions. On each pin, some muxmodes are effectively used for alternate functions, while some muxmodes are not used. Only MUXMODE values which correspond to defined functions should be used. 6. TYPE: Signal type and direction: – I = Input – O = Output – IO = Input or Output – D = Open drain – DS = Differential Signaling – A = Analog – PWR = Power Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 11 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com – GND = Ground – CAP = LDO Capacitor 7. BALL RESET STATE: The state of the terminal at power-on reset: – drive 0 (OFF): The buffer drives VOL (pulldown or pullup resistor not activated) – drive 1 (OFF): The buffer drives VOH (pulldown or pullup resistor not activated) – OFF: High-impedance – PD: High-impedance with an active pulldown resistor – PU: High-impedance with an active pullup resistor 8. BALL RESET REL. STATE: The state of the terminal at the deactivation of the rstoutn signal (also mapped to the PRCM SYS_WARM_OUT_RST signal) – drive 0 (OFF): The buffer drives VOL (pulldown or pullup resistor not activated) – drive clk (OFF): The buffer drives a toggling clock (pulldown or pullup resistor not activated) – drive 1 (OFF): The buffer drives VOH (pulldown or pullup resistor not activated) – OFF: High-impedance – PD: High-impedance with an active pulldown resistor – PU: High-impedance with an active pullup resistor NOTE For more information on the CORE_PWRON_RET_RST reset signal and its reset sources, see the Power Reset and Clock Management / PRCM Reset Management Functional Description section of the Device TRM. 9. BALL RESET REL. MUXMODE: This muxmode is automatically configured at the release of the rstoutn signal (also mapped to the PRCM SYS_WARM_OUT_RST signal). 10. IO VOLTAGE VALUE: This column describes the IO voltage value (VDDS supply). 11. POWER: The voltage supply that powers the terminal IO buffers. 12. HYS: Indicates if the input buffer is with hysteresis: – Yes: With hysteresis – No: Without hysteresis An empty box means "Yes". NOTE For more information, see the hysteresis values in Section 5.7, Electrical Characteristics. 13. BUFFER TYPE: Drive strength of the associated output buffer. NOTE For programmable buffer strength: – The default value is given in Table 4-2. – A note describes all possible values according to the selected muxmode. 14. PULLUP / PULLDOWN TYPE: Denotes the presence of an internal pullup or pulldown resistor. Pullup and pulldown resistors can be enabled or disabled via software. 15. DSIS: The deselected input state (DSIS) indicates the state driven on the peripheral input (logic "0" or logic "1") when the peripheral pin function is not selected by any of the PINCNTLx registers. – 0: Logic 0 driven on the peripheral's input signal port. – 1: Logic 1 driven on the peripheral's input signal port. – blank: Not Applicable. 12 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE Configuring two pins to the same input signal is not supported as it can yield unexpected results. This can be easily prevented with the proper software configuration. (Hi-Z mode is not an input signal.) NOTE When a pad is set into a multiplexing mode which is not defined by pin multiplexing, that pad’s behavior is undefined. This should be avoided. CAUTION Peripherals exposed in Ball Characteristics Table and Multiplexing Characteristics Table represent functionality of a DRA75x device. Not all exposed peripherals are supported on DRA7xx devices. For peripherals supported on DRA7xx family of products please refer to Table 3-1, Device Comparison. NOTE Some of the DDR1 and DDR2 signals have an additional state change at the release of porz. The state that the signals change to at the release of porz is as follows: drive 0 (OFF) for: ddr1_csn0, ddr1_ck, ddr1_nck, ddr1_nck, ddr1_casn, ddr1_rasn, ddr1_wen, ddr1_ba[2:0], ddr1_a[15:0], ddr2_csn0, ddr2_ck, ddr2_nck, ddr2_casn, ddr2_rasn, ddr2_wen, ddr2_ba[2:0], ddr2_a[15:0]. OFF for: ddr1_ecc_d[7:0], ddr1_dqm[3:0], ddr1_dqm_ecc, ddr1_dqs[3:0], ddr1_dqsn[3:0], ddr1_dqs_ecc, ddr1_dqsn_ecc, ddr1_d[31:0], ddr2_dqm[3:0], ddr2_dqs[3:0], ddr2_dqsn[3:0], ddr2_d[31:0]. Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 13 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] K9 cap_vbbldo_dspeve cap_vbbldo_dspeve CAP Y14 cap_vbbldo_gpu cap_vbbldo_gpu CAP R20 cap_vbbldo_iva cap_vbbldo_iva CAP J16 cap_vbbldo_mpu cap_vbbldo_mpu CAP L9 cap_vddram_core1 cap_vddram_core1 CAP J19 cap_vddram_core2 cap_vddram_core2 CAP Y15 cap_vddram_core3 cap_vddram_core3 CAP P19 cap_vddram_core4 cap_vddram_core4 CAP Y16 cap_vddram_core5 cap_vddram_core5 CAP J10 cap_vddram_dspeve1 cap_vddram_dspeve1 CAP J9 cap_vddram_dspeve2 cap_vddram_dspeve2 CAP Y13 cap_vddram_gpu cap_vddram_gpu CAP T20 cap_vddram_iva cap_vddram_iva CAP K16 cap_vddram_mpu1 cap_vddram_mpu1 CAP K19 cap_vddram_mpu2 cap_vddram_mpu2 G19 dcan1_rx dcan1_rx 0 IO uart8_txd 2 O mmc2_sdwp 3 I sata1_led 4 O hdmi1_cec 6 IO gpio1_15 14 IO Driver off 15 I dcan1_tx 0 IO uart8_rxd 2 I mmc2_sdcd 3 I hdmi1_hpd 6 I gpio1_14 14 IO Driver off 15 I G20 dcan1_tx BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] CAP PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1 1 1 ddr1_a0 ddr1_a0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC19 ddr1_a1 ddr1_a1 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AD21 ddr1_a10 ddr1_a10 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AD22 ddr1_a11 ddr1_a11 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC21 ddr1_a12 ddr1_a12 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Terminal Configuration and Functions 1 0 AD20 14 DSIS [15] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] AF18 ddr1_a13 ddr1_a13 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE17 ddr1_a14 ddr1_a14 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AD18 ddr1_a15 ddr1_a15 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC20 ddr1_a2 ddr1_a2 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AB19 ddr1_a3 ddr1_a3 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF21 ddr1_a4 ddr1_a4 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AH22 ddr1_a5 ddr1_a5 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG23 ddr1_a6 ddr1_a6 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE21 ddr1_a7 ddr1_a7 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF22 ddr1_a8 ddr1_a8 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE22 ddr1_a9 ddr1_a9 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF17 ddr1_ba0 ddr1_ba0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE18 ddr1_ba1 ddr1_ba1 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AB18 ddr1_ba2 ddr1_ba2 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC18 ddr1_casn ddr1_casn 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG24 ddr1_ck ddr1_ck 0 O PD drive clk (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG22 ddr1_cke ddr1_cke 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AH23 ddr1_csn0 ddr1_csn0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF25 ddr1_d0 ddr1_d0 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF26 ddr1_d1 ddr1_d1 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG27 ddr1_d10 ddr1_d10 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF28 ddr1_d11 ddr1_d11 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE26 ddr1_d12 ddr1_d12 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy DSIS [15] Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 15 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] AC25 ddr1_d13 ddr1_d13 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC24 ddr1_d14 ddr1_d14 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AD25 ddr1_d15 ddr1_d15 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy V20 ddr1_d16 ddr1_d16 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy W20 ddr1_d17 ddr1_d17 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AB28 ddr1_d18 ddr1_d18 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC28 ddr1_d19 ddr1_d19 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG26 ddr1_d2 ddr1_d2 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC27 ddr1_d20 ddr1_d20 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y19 ddr1_d21 ddr1_d21 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AB27 ddr1_d22 ddr1_d22 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y20 ddr1_d23 ddr1_d23 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA23 ddr1_d24 ddr1_d24 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y22 ddr1_d25 ddr1_d25 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y23 ddr1_d26 ddr1_d26 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA24 ddr1_d27 ddr1_d27 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y24 ddr1_d28 ddr1_d28 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA26 ddr1_d29 ddr1_d29 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AH26 ddr1_d3 ddr1_d3 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA25 ddr1_d30 ddr1_d30 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA28 ddr1_d31 ddr1_d31 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF24 ddr1_d4 ddr1_d4 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE24 ddr1_d5 ddr1_d5 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy 16 Terminal Configuration and Functions DSIS [15] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] AF23 ddr1_d6 ddr1_d6 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE23 ddr1_d7 ddr1_d7 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC23 ddr1_d8 ddr1_d8 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF27 ddr1_d9 ddr1_d9 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AD23 ddr1_dqm0 ddr1_dqm0 0 O PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AB23 ddr1_dqm1 ddr1_dqm1 0 O PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AC26 ddr1_dqm2 ddr1_dqm2 0 O PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AA27 ddr1_dqm3 ddr1_dqm3 0 O PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy V26 ddr1_dqm_ecc ddr1_dqm_ecc 0 O PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AH25 ddr1_dqs0 ddr1_dqs0 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy AE27 ddr1_dqs1 ddr1_dqs1 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy AD27 ddr1_dqs2 ddr1_dqs2 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy Y28 ddr1_dqs3 ddr1_dqs3 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy AG25 ddr1_dqsn0 ddr1_dqsn0 0 IO PU PU 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy AE28 ddr1_dqsn1 ddr1_dqsn1 0 IO PU PU 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy AD28 ddr1_dqsn2 ddr1_dqsn2 0 IO PU PU 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy Y27 ddr1_dqsn3 ddr1_dqsn3 0 IO PU PU 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy V28 ddr1_dqsn_ecc ddr1_dqsn_ecc No 0 IO PU PU 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy V27 ddr1_dqs_ecc ddr1_dqs_ecc No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 NA LVCMOS DDR Pux/PDy W22 ddr1_ecc_d0 ddr1_ecc_d0 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy V23 ddr1_ecc_d1 ddr1_ecc_d1 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy W19 ddr1_ecc_d2 ddr1_ecc_d2 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy W23 ddr1_ecc_d3 ddr1_ecc_d3 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy No DSIS [15] Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 17 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] Y25 ddr1_ecc_d4 ddr1_ecc_d4 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy V24 ddr1_ecc_d5 ddr1_ecc_d5 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy V25 ddr1_ecc_d6 ddr1_ecc_d6 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y26 ddr1_ecc_d7 ddr1_ecc_d7 No 0 IO PD PD 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AH24 ddr1_nck ddr1_nck 0 O PD drive clk (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AE20 ddr1_odt0 ddr1_odt0 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AF20 ddr1_rasn ddr1_rasn 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy AG21 ddr1_rst ddr1_rst 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy Y18 ddr1_vref0 ddr1_vref0 0 PWR OFF OFF 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR NA AH21 ddr1_wen ddr1_wen 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr1 No LVCMOS DDR Pux/PDy R25 ddr2_a0 ddr2_a0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R26 ddr2_a1 ddr2_a1 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy N23 ddr2_a10 ddr2_a10 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P26 ddr2_a11 ddr2_a11 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy N28 ddr2_a12 ddr2_a12 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy T22 ddr2_a13 ddr2_a13 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R22 ddr2_a14 ddr2_a14 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U22 ddr2_a15 ddr2_a15 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R28 ddr2_a2 ddr2_a2 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R27 ddr2_a3 ddr2_a3 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P23 ddr2_a4 ddr2_a4 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P22 ddr2_a5 ddr2_a5 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P25 ddr2_a6 ddr2_a6 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy 18 Terminal Configuration and Functions DSIS [15] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] N20 ddr2_a7 ddr2_a7 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P27 ddr2_a8 ddr2_a8 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy N27 ddr2_a9 ddr2_a9 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U23 ddr2_ba0 ddr2_ba0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U27 ddr2_ba1 ddr2_ba1 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U26 ddr2_ba2 ddr2_ba2 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U28 ddr2_casn ddr2_casn 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy T28 ddr2_ck ddr2_ck 0 O PD drive clk (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy U24 ddr2_cke ddr2_cke 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy P24 ddr2_csn0 ddr2_csn0 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy E26 ddr2_d0 ddr2_d0 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy G25 ddr2_d1 ddr2_d1 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy H24 ddr2_d10 ddr2_d10 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy H26 ddr2_d11 ddr2_d11 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy G26 ddr2_d12 ddr2_d12 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy J25 ddr2_d13 ddr2_d13 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy J26 ddr2_d14 ddr2_d14 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy J24 ddr2_d15 ddr2_d15 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L22 ddr2_d16 ddr2_d16 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy K20 ddr2_d17 ddr2_d17 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy K21 ddr2_d18 ddr2_d18 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L23 ddr2_d19 ddr2_d19 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy F25 ddr2_d2 ddr2_d2 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy DSIS [15] Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 19 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] L24 ddr2_d20 ddr2_d20 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy J23 ddr2_d21 ddr2_d21 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy K22 ddr2_d22 ddr2_d22 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy J20 ddr2_d23 ddr2_d23 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L27 ddr2_d24 ddr2_d24 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L26 ddr2_d25 ddr2_d25 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L25 ddr2_d26 ddr2_d26 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy L28 ddr2_d27 ddr2_d27 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy M23 ddr2_d28 ddr2_d28 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy M24 ddr2_d29 ddr2_d29 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy F24 ddr2_d3 ddr2_d3 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy M25 ddr2_d30 ddr2_d30 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy M26 ddr2_d31 ddr2_d31 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy F26 ddr2_d4 ddr2_d4 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy F27 ddr2_d5 ddr2_d5 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy E27 ddr2_d6 ddr2_d6 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy E28 ddr2_d7 ddr2_d7 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy H23 ddr2_d8 ddr2_d8 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy H25 ddr2_d9 ddr2_d9 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy F28 ddr2_dqm0 ddr2_dqm0 0 O PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy G24 ddr2_dqm1 ddr2_dqm1 0 O PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy K23 ddr2_dqm2 ddr2_dqm2 0 O PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy M22 ddr2_dqm3 ddr2_dqm3 0 O PU PU 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy 20 Terminal Configuration and Functions DSIS [15] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] G28 ddr2_dqs0 ddr2_dqs0 0 IO PD PD 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy H27 ddr2_dqs1 ddr2_dqs1 0 IO PD PD 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy K27 ddr2_dqs2 ddr2_dqs2 0 IO PD PD 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy M28 ddr2_dqs3 ddr2_dqs3 0 IO PD PD 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy G27 ddr2_dqsn0 ddr2_dqsn0 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy H28 ddr2_dqsn1 ddr2_dqsn1 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy K28 ddr2_dqsn2 ddr2_dqsn2 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy M27 ddr2_dqsn3 ddr2_dqsn3 0 IO PU PU 1.35/1.5/1.8 vdds_ddr2 NA LVCMOS DDR Pux/PDy T27 ddr2_nck ddr2_nck 0 O PD drive clk (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R23 ddr2_odt0 ddr2_odt0 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy T23 ddr2_rasn ddr2_rasn 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy R24 ddr2_rst ddr2_rst 0 O PD drive 0 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy N22 ddr2_vref0 ddr2_vref0 0 PWR OFF OFF 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR NA U25 ddr2_wen ddr2_wen 0 O PD drive 1 (OFF) 1.35/1.5/1.8 vdds_ddr2 No LVCMOS DDR Pux/PDy G21 emu0 emu0 0 IO PU PU 0 1.8/3.3 vddshv3 Yes 14 IO Dual Voltage LVCMOS PU/PD gpio8_30 emu1 0 IO PU PU 0 1.8/3.3 vddshv3 Yes 14 IO Dual Voltage LVCMOS PU/PD gpio8_31 gpio6_10 0 IO PU PU 15 1.8/3.3 vddshv7 Yes 1 O Dual Voltage LVCMOS PU/PD mdio_mclk i2c3_sda 2 IO 1 usb3_ulpi_d7 3 IO 0 vin2b_hsync1 4 I D24 AC5 emu1 gpio6_10 vin5a_clk0 9 I ehrpwm2A No 10 O gpio6_10 14 IO Driver off 15 I 1 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 21 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AB4 BALL NAME [2] gpio6_11 SIGNAL NAME [3] F20 F21 22 gpio6_14 gpio6_15 gpio6_16 MUXMODE [5] TYPE [6] BALL RESET STATE [7] PU 15 1.8/3.3 POWER [11] vddshv7 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] 0 IO mdio_d 1 IO i2c3_scl 2 IO 1 usb3_ulpi_d6 3 IO 0 vin2b_vsync1 4 I PU/PD 1 9 I ehrpwm2B 10 O gpio6_11 14 IO Driver off 15 I gpio6_14 0 IO mcasp1_axr8 1 IO dcan2_tx 2 IO 1 uart10_rxd 3 I 1 vout2_hsync 6 O vin4a_hsync0 8 I 0 i2c3_sda 9 IO 1 timer1 10 IO gpio6_14 14 IO Driver off 15 I gpio6_15 0 IO mcasp1_axr9 1 IO dcan2_rx 2 IO uart10_txd 3 O vout2_vsync 6 O vin4a_vsync0 8 I 0 i2c3_scl 9 IO 1 timer2 10 IO gpio6_15 14 IO Driver off 15 I gpio6_16 0 IO mcasp1_axr10 1 IO vout2_fld 6 O vin4a_fld0 8 I clkout1 9 O timer3 10 IO gpio6_16 14 IO Driver off 15 I Terminal Configuration and Functions No PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] gpio6_11 vin5a_de0 E21 74x [4] 0 PU PU PU PU 15 15 1.8/3.3 1.8/3.3 vddshv3 vddshv3 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 PU/PD 0 1 PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] R6 T9 N9 P9 BALL NAME [2] gpmc_a0 gpmc_a1 gpmc_a10 gpmc_a11 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O I vout3_d16 3 O vin4a_d0 4 I 0 vin4b_d0 6 I 0 i2c4_scl 7 IO 1 uart5_rxd 8 I 1 gpio7_3 14 IO Driver off 15 I gpmc_a1 0 O vin3a_d17 2 I vout3_d17 3 O vin4a_d1 4 I 0 vin4b_d1 6 I 0 i2c4_sda 7 IO 1 uart5_txd 8 O gpio7_4 14 IO Driver off 15 I gpmc_a10 0 O vin3a_de0 2 I vout3_de 3 O vin4b_clk1 6 I timer10 7 IO spi4_d0 8 IO gpio2_0 14 IO Driver off 15 I gpmc_a11 0 O vin3a_fld0 2 I vout3_fld 3 O vin4a_fld0 4 I 0 vin4b_de1 6 I 0 timer9 7 IO spi4_cs0 8 IO gpio2_1 14 IO Driver off 15 I PD PD 15 1.8/3.3 vddshv10 vddshv10 Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 2 1.8/3.3 vddshv10 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] vin3a_d16 PD 15 HYS [12] gpmc_a0 PD PD POWER [11] Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 PU/PD 0 PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 23 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] P4 R3 T2 U2 U1 24 BALL NAME [2] gpmc_a12 gpmc_a13 gpmc_a14 gpmc_a15 gpmc_a16 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD 15 1.8/3.3 POWER [11] vddshv10 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] gpmc_a12 0 O vin4a_clk0 4 I gpmc_a0 5 O vin4b_fld1 6 I timer8 7 IO spi4_cs1 8 IO 1 dma_evt1 9 I 0 gpio2_2 14 IO Driver off 15 I gpmc_a13 0 O qspi1_rtclk 1 I vin4a_hsync0 4 I timer7 7 IO spi4_cs2 8 IO 1 dma_evt2 9 I 0 gpio2_3 14 IO Driver off 15 I gpmc_a14 0 O qspi1_d3 1 I vin4a_vsync0 4 I timer6 7 IO spi4_cs3 8 IO gpio2_4 14 IO Driver off 15 I gpmc_a15 0 O qspi1_d2 1 I vin4a_d8 4 I timer5 7 IO gpio2_5 14 IO Driver off 15 I gpmc_a16 0 O qspi1_d0 1 IO vin4a_d9 4 I gpio2_6 14 IO Driver off 15 I Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PU/PD 0 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 0 1 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] P3 R2 K7 T6 M7 BALL NAME [2] gpmc_a17 gpmc_a18 gpmc_a19 gpmc_a2 gpmc_a20 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv10 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] gpmc_a17 0 O qspi1_d1 1 I PU/PD vin4a_d10 4 I gpio2_7 14 IO Driver off 15 I gpmc_a18 0 O qspi1_sclk 1 O vin4a_d11 4 I gpio2_8 14 IO Driver off 15 I gpmc_a19 0 O mmc2_dat4 1 IO gpmc_a13 2 O vin4a_d12 4 I 0 vin3b_d0 6 I 0 gpio2_9 14 IO Driver off 15 I gpmc_a2 0 O vin3a_d18 2 I vout3_d18 3 O vin4a_d2 4 I 0 vin4b_d2 6 I 0 uart7_rxd 7 I 1 uart5_ctsn 8 I 1 gpio7_5 14 IO Driver off 15 I gpmc_a20 0 O mmc2_dat5 1 IO gpmc_a14 2 O vin4a_d13 4 I 0 vin3b_d1 6 I 0 gpio2_10 14 IO Driver off 15 I 0 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 0 PD PD PD PD PD PD 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv11 vddshv10 vddshv11 Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 PU/PD 0 PU/PD 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 25 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] J5 K6 J7 J4 J6 26 BALL NAME [2] gpmc_a21 gpmc_a22 gpmc_a23 gpmc_a24 gpmc_a25 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] IO gpmc_a15 2 O vin4a_d14 4 I 0 vin3b_d2 6 I 0 gpio2_11 14 IO Driver off 15 I gpmc_a22 0 O mmc2_dat7 1 IO gpmc_a16 2 O vin4a_d15 4 I 0 vin3b_d3 6 I 0 gpio2_12 14 IO Driver off 15 I gpmc_a23 0 O mmc2_clk 1 IO gpmc_a17 2 O vin4a_fld0 4 I 0 vin3b_d4 6 I 0 gpio2_13 14 IO Driver off 15 I gpmc_a24 0 O mmc2_dat0 1 IO gpmc_a18 2 O vin4a_d8 4 I 0 vin3b_d5 6 I 0 gpio2_14 14 IO Driver off 15 I gpmc_a25 0 O mmc2_dat1 1 IO gpmc_a19 2 O vin4a_d9 4 I 0 vin3b_d6 6 I 0 gpio2_15 14 IO Driver off 15 I PD PD PD PD PD PD 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv11 vddshv11 vddshv11 vddshv11 Yes Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] O 1.8/3.3 vddshv11 PULL UP/DOWN TYPE [14] 1 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] mmc2_dat6 PD PD POWER [11] gpmc_a21 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 PU/PD 1 PU/PD 1 PU/PD 1 PU/PD 1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] H4 H5 T7 P6 BALL NAME [2] gpmc_a26 gpmc_a27 gpmc_a3 gpmc_a4 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O IO gpmc_a20 2 O vin4a_d10 4 I 0 vin3b_d7 6 I 0 gpio2_16 14 IO Driver off 15 I gpmc_a27 0 O mmc2_dat3 1 IO gpmc_a21 2 O vin4a_d11 4 I 0 vin3b_hsync1 6 I 0 gpio2_17 14 IO Driver off 15 I gpmc_a3 0 O qspi1_cs2 1 O vin3a_d19 2 I vout3_d19 3 O vin4a_d3 4 I 0 vin4b_d3 6 I 0 uart7_txd 7 O uart5_rtsn 8 O gpio7_6 14 IO Driver off 15 I gpmc_a4 0 O qspi1_cs3 1 O vin3a_d20 2 I vout3_d20 3 O vin4a_d4 4 I 0 vin4b_d4 6 I 0 i2c5_scl 7 IO 1 uart6_rxd 8 I 1 gpio1_26 14 IO Driver off 15 I PD PD 15 1.8/3.3 vddshv11 vddshv10 Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 1 1.8/3.3 vddshv11 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] mmc2_dat2 PD 15 HYS [12] gpmc_a26 PD PD POWER [11] Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 PU/PD 1 PU/PD 1 0 PD PD 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 1 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 27 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] R9 R5 P5 N7 28 BALL NAME [2] gpmc_a5 gpmc_a6 gpmc_a7 gpmc_a8 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] I vout3_d21 3 O vin4a_d5 4 I 0 vin4b_d5 6 I 0 i2c5_sda 7 IO 1 uart6_txd 8 O gpio1_27 14 IO Driver off 15 I gpmc_a6 0 O vin3a_d22 2 I vout3_d22 3 O vin4a_d6 4 I 0 vin4b_d6 6 I 0 uart8_rxd 7 I 1 uart6_ctsn 8 I 1 gpio1_28 14 IO Driver off 15 I gpmc_a7 0 O vin3a_d23 2 I vout3_d23 3 O vin4a_d7 4 I 0 vin4b_d7 6 I 0 uart8_txd 7 O uart6_rtsn 8 O gpio1_29 14 IO Driver off 15 I gpmc_a8 0 O vin3a_hsync0 2 I vout3_hsync 3 O vin4b_hsync1 6 I timer12 7 IO spi4_sclk 8 IO gpio1_30 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv10 vddshv10 vddshv10 Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] O 1.8/3.3 vddshv10 PULL UP/DOWN TYPE [14] 2 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] vin3a_d21 PD PD POWER [11] gpmc_a5 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 PU/PD 0 PU/PD 0 PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] R4 M6 M2 J1 J2 H1 BALL NAME [2] gpmc_a9 gpmc_ad0 gpmc_ad1 gpmc_ad10 gpmc_ad11 gpmc_ad12 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] gpmc_a9 0 O vin3a_vsync0 2 I vout3_vsync 3 O vin4b_vsync1 6 I timer11 7 IO spi4_d1 8 IO gpio1_31 14 IO Driver off 15 I gpmc_ad0 0 IO vin3a_d0 2 I vout3_d0 3 O gpio1_6 14 IO sysboot0 15 I gpmc_ad1 0 IO vin3a_d1 2 I vout3_d1 3 O gpio1_7 14 IO sysboot1 15 I gpmc_ad10 0 IO vin3a_d10 2 I vout3_d10 3 O gpio7_28 14 IO sysboot10 15 I gpmc_ad11 0 IO vin3a_d11 2 I vout3_d11 3 O gpio7_29 14 IO sysboot11 15 I gpmc_ad12 0 IO vin3a_d12 2 I vout3_d12 3 O gpio1_18 14 IO sysboot12 15 I BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv10 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] PU/PD 0 0 0 OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF 15 15 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 vddshv10 vddshv10 vddshv10 vddshv10 vddshv10 Yes Yes Yes Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 0 0 0 0 0 0 0 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 29 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] J3 H2 H3 L5 M1 L6 L4 30 BALL NAME [2] gpmc_ad13 gpmc_ad14 gpmc_ad15 gpmc_ad2 gpmc_ad3 gpmc_ad4 gpmc_ad5 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] gpmc_ad13 0 IO vin3a_d13 2 I vout3_d13 3 O gpio1_19 14 IO sysboot13 15 I gpmc_ad14 0 IO vin3a_d14 2 I vout3_d14 3 O gpio1_20 14 IO sysboot14 15 I gpmc_ad15 0 IO vin3a_d15 2 I vout3_d15 3 O gpio1_21 14 IO sysboot15 15 I gpmc_ad2 0 IO vin3a_d2 2 I vout3_d2 3 O gpio1_8 14 IO sysboot2 15 I gpmc_ad3 0 IO vin3a_d3 2 I vout3_d3 3 O gpio1_9 14 IO sysboot3 15 I gpmc_ad4 0 IO vin3a_d4 2 I vout3_d4 3 O gpio1_10 14 IO sysboot4 15 I gpmc_ad5 0 IO vin3a_d5 2 I vout3_d5 3 O gpio1_11 14 IO sysboot5 15 I Terminal Configuration and Functions BALL RESET STATE [7] OFF OFF OFF OFF OFF OFF OFF BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] OFF OFF OFF OFF OFF OFF OFF 15 15 15 15 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 POWER [11] vddshv10 vddshv10 vddshv10 vddshv10 vddshv10 vddshv10 vddshv10 HYS [12] Yes Yes Yes Yes Yes Yes Yes BUFFER TYPE [13] PULL UP/DOWN TYPE [14] Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD DSIS [15] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] L3 L2 L1 K2 N1 BALL NAME [2] gpmc_ad6 gpmc_ad7 gpmc_ad8 gpmc_ad9 gpmc_advn_ale SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] OFF BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] IO I vout3_d6 3 O gpio1_12 14 IO sysboot6 15 I gpmc_ad7 0 IO vin3a_d7 2 I vout3_d7 3 O gpio1_13 14 IO sysboot7 15 I gpmc_ad8 0 IO vin3a_d8 2 I vout3_d8 3 O gpio7_18 14 IO sysboot8 15 I gpmc_ad9 0 IO vin3a_d9 2 I vout3_d9 3 O gpio7_19 14 IO sysboot9 15 I gpmc_advn_ale 0 O gpmc_cs6 1 O clkout2 2 O gpmc_wait1 3 I 1 vin4a_vsync0 4 I 0 gpmc_a2 5 O gpmc_a23 6 O timer3 7 IO i2c3_sda 8 IO 1 dma_evt2 9 I 0 gpio2_23 14 IO Driver off 15 I OFF OFF PU OFF OFF PU 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv10 vddshv10 vddshv10 vddshv10 Yes Yes Yes Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD DSIS [15] 2 1.8/3.3 vddshv10 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] vin3a_d6 OFF 15 HYS [12] gpmc_ad6 OFF OFF POWER [11] 0 0 0 0 0 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 31 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] N6 BALL NAME [2] gpmc_ben0 SIGNAL NAME [3] gpmc_ben1 T1 32 gpmc_clk gpmc_cs0 TYPE [6] 0 O gpmc_cs4 1 O No BALL RESET STATE [7] PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PU 15 1.8/3.3 POWER [11] vddshv10 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] PU/PD 3 I 0 vin3b_de1 6 I 0 timer2 7 IO dma_evt3 9 I gpio2_26 14 IO Driver off 15 I gpmc_ben1 0 O gpmc_cs5 1 O vin1b_de1 P7 MUXMODE [5] gpmc_ben0 vin1b_hsync1 M4 74x [4] PU PU 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD 3 I 0 vin3b_clk1 4 I 0 gpmc_a3 5 O vin3b_fld1 6 I timer1 7 IO dma_evt4 9 I gpio2_27 14 IO Driver off 15 I gpmc_clk 0 IO gpmc_cs7 1 O clkout1 2 O gpmc_wait1 3 I 1 vin4a_hsync0 4 I 0 vin4a_de0 5 I 0 vin3b_clk1 6 I 0 timer4 7 IO i2c3_scl 8 IO 1 dma_evt1 9 I 0 gpio2_22 14 IO Driver off 15 I gpmc_cs0 0 O gpio2_19 14 IO Driver off 15 I Terminal Configuration and Functions No 0 0 0 PU PU PU PU 15 15 1.8/3.3 1.8/3.3 vddshv10 vddshv10 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] H6 P2 P1 M5 N2 M3 BALL NAME [2] gpmc_cs1 gpmc_cs2 gpmc_cs3 gpmc_oen_ren gpmc_wait0 gpmc_wen SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O IO gpmc_a22 2 O vin4a_de0 4 I 0 vin3b_vsync1 6 I 0 gpio2_18 14 IO Driver off 15 I gpmc_cs2 0 O qspi1_cs0 1 O gpio2_20 14 IO Driver off 15 I gpmc_cs3 0 O qspi1_cs1 1 O vin3a_clk0 2 I vout3_clk 3 O gpmc_a1 5 O gpio2_21 14 IO Driver off 15 I gpmc_oen_ren 0 O gpio2_24 14 IO Driver off 15 I gpmc_wait0 0 I gpio2_28 14 IO Driver off 15 I gpmc_wen 0 O gpio2_25 14 IO PU PU 15 1.8/3.3 vddshv10 vddshv10 Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 1 1.8/3.3 vddshv11 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] mmc2_cmd PU 15 HYS [12] gpmc_cs1 PU PU POWER [11] PU/PD 1 Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 1 1 0 PU PU 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD PU PU 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD PU PU 15 1.8/3.3 vddshv10 Yes Dual Voltage LVCMOS PU/PD Driver off 15 I AG16 hdmi1_clockx hdmi1_clockx 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AH16 hdmi1_clocky hdmi1_clocky 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AG17 hdmi1_data0x hdmi1_data0x 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AH17 hdmi1_data0y hdmi1_data0y 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AG18 hdmi1_data1x hdmi1_data1x 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AH18 hdmi1_data1y hdmi1_data1y 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AG19 hdmi1_data2x hdmi1_data2x 0 O 1.8 vdda_hdmi NA HDMIPHY PDy AH19 hdmi1_data2y hdmi1_data2y 0 O 1.8 vdda_hdmi NA HDMIPHY PDy 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 33 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] C20 i2c1_scl i2c1_scl 0 IO OFF OFF 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS I2C PU/PD C21 i2c1_sda i2c1_sda 0 IO OFF OFF 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS I2C PU/PD F17 i2c2_scl i2c2_scl 0 IO OFF OFF 15 1.8/3.3 vddshv3 Yes 1 1 IO Driver off 15 I Dual Voltage LVCMOS I2C PU/PD hdmi1_ddc_sda i2c2_sda 0 IO OFF OFF 15 1.8/3.3 vddshv3 Yes 1 1 IO Dual Voltage LVCMOS I2C PU/PD hdmi1_ddc_scl C25 i2c2_sda Driver off 15 I AH15 ljcb_clkn ljcb_clkn 0 IO 1.8 vdda_pcie NA LJCB NA AG15 ljcb_clkp ljcb_clkp 0 IO 1.8 vdda_pcie NA LJCB NA B14 mcasp1_aclkr mcasp1_aclkr 0 IO 1.8/3.3 vddshv3 Yes PU/PD mcasp7_axr2 1 IO Dual Voltage LVCMOS vout2_d0 6 O vin4a_d0 8 I 0 i2c4_sda 10 IO 1 gpio5_0 14 IO Driver off 15 I mcasp1_aclkx 0 IO 7 I i2c3_sda 10 IO gpio7_31 14 IO Driver off 15 I mcasp1_axr0 0 IO uart6_rxd 3 I 7 I 0 i2c5_sda 10 IO 1 gpio5_2 14 IO Driver off 15 I C14 mcasp1_aclkx vin6a_fld0 G12 mcasp1_axr0 vin6a_vsync0 34 Terminal Configuration and Functions No No PD PD PD PD 15 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS 0 0 PU/PD 0 0 1 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] F12 BALL NAME [2] mcasp1_axr1 SIGNAL NAME [3] mcasp1_axr10 0 IO 3 O No mcasp1_axr13 15 1.8/3.3 vddshv3 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 I 0 IO 1 gpio5_3 14 IO Driver off 15 I mcasp1_axr10 0 IO mcasp6_aclkx 1 IO mcasp6_aclkr 2 IO 3 IO 0 7 I 0 timer7 10 IO gpio5_12 14 IO Driver off 15 I mcasp1_axr11 0 IO mcasp6_fsx 1 IO mcasp6_fsr 2 IO 3 IO 1 7 I 0 timer8 10 IO gpio4_17 14 IO Driver off 15 I mcasp1_axr12 0 IO mcasp7_axr0 1 IO spi3_cs1 3 IO 1 7 I 0 timer9 10 IO gpio4_18 14 IO Driver off 15 I mcasp1_axr13 0 IO mcasp7_axr1 1 IO 7 I timer10 10 IO gpio6_4 14 IO Driver off 15 I vin6a_d11 A13 PD POWER [11] 10 vin6a_d12 mcasp1_axr12 PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 7 No spi3_cs0 E14 BALL RESET STATE [7] i2c5_scl vin6a_d13 mcasp1_axr11 TYPE [6] uart6_txd spi3_d0 A12 MUXMODE [5] mcasp1_axr1 vin6a_hsync0 B13 74x [4] vin6a_d10 No No No PD PD PD PD PD PD PD PD 15 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 vddshv3 vddshv3 vddshv3 vddshv3 Yes Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 0 PU/PD 0 0 PU/PD 0 0 PU/PD 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 35 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] G14 BALL NAME [2] mcasp1_axr14 SIGNAL NAME [3] mcasp1_axr15 J11 E12 36 mcasp1_axr2 mcasp1_axr3 mcasp1_axr4 TYPE [6] 0 IO mcasp7_aclkx 1 IO mcasp7_aclkr 2 IO 7 I timer11 10 IO gpio6_5 14 IO Driver off 15 I mcasp1_axr15 0 IO mcasp7_fsx 1 IO mcasp7_fsr 2 IO vin6a_d8 G13 MUXMODE [5] mcasp1_axr14 vin6a_d9 F14 74x [4] No 7 I timer12 10 IO gpio6_6 14 IO Driver off 15 I mcasp1_axr2 0 IO mcasp6_axr2 1 IO uart6_ctsn 3 I vout2_d2 6 O vin4a_d2 8 I gpio5_4 14 IO Driver off 15 I mcasp1_axr3 0 IO mcasp6_axr3 1 IO uart6_rtsn 3 O vout2_d3 6 O vin4a_d3 8 I gpio5_5 14 IO Driver off 15 I mcasp1_axr4 0 IO mcasp4_axr2 1 IO vout2_d4 6 O vin4a_d4 8 I gpio5_6 14 IO Driver off 15 I Terminal Configuration and Functions No BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv3 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 1 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] F13 C12 D12 B12 BALL NAME [2] mcasp1_axr5 mcasp1_axr6 mcasp1_axr7 mcasp1_axr8 SIGNAL NAME [3] mcasp1_axr9 MUXMODE [5] TYPE [6] BALL RESET STATE [7] 1.8/3.3 vddshv3 Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] IO 1 IO vout2_d5 6 O vin4a_d5 8 I gpio5_7 14 IO Driver off 15 I mcasp1_axr6 0 IO mcasp5_axr2 1 IO vout2_d6 6 O vin4a_d6 8 I gpio5_8 14 IO Driver off 15 I mcasp1_axr7 0 IO mcasp5_axr3 1 IO vout2_d7 6 O vin4a_d7 8 I timer4 10 IO gpio5_9 14 IO Driver off 15 I mcasp1_axr8 0 IO mcasp6_axr0 1 IO spi3_sclk 3 IO 0 7 I 0 timer5 10 IO gpio5_10 14 IO Driver off 15 I mcasp1_axr9 0 IO mcasp6_axr1 1 IO spi3_d1 3 IO 0 7 I 0 timer6 10 IO gpio5_11 14 IO Driver off 15 I No 15 HYS [12] 0 vin6a_d14 PD POWER [11] mcasp4_axr3 No PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] mcasp1_axr5 vin6a_d15 A11 74x [4] 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv3 vddshv3 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 0 PU/PD 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 37 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] J14 D14 BALL NAME [2] mcasp1_fsr mcasp1_fsx SIGNAL NAME [3] A19 mcasp2_aclkr mcasp2_aclkx A15 C15 mcasp2_axr0 mcasp2_axr1 mcasp2_axr2 BALL RESET STATE [7] O vin4a_d1 8 I 0 i2c4_scl 10 IO 1 gpio5_1 14 IO Driver off 15 I mcasp1_fsx 0 IO 7 I i2c3_scl 10 IO gpio7_30 14 IO Driver off 15 I mcasp2_aclkr 0 IO mcasp8_axr2 1 IO vout2_d8 6 O vin4a_d8 8 I Driver off 15 I 0 IO 7 I Driver off 15 I mcasp2_axr0 0 IO vout2_d10 6 O vin4a_d10 8 I Driver off 15 I mcasp2_axr1 0 IO vout2_d11 6 O vin4a_d11 8 I Driver off 15 I mcasp2_axr2 0 IO mcasp3_axr2 1 IO 7 I gpio6_8 14 IO Driver off 15 I mcasp2_aclkx Terminal Configuration and Functions No No vddshv3 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 6 1.8/3.3 vddshv3 PULL UP/DOWN TYPE [14] vout2_d1 15 1.8/3.3 BUFFER TYPE [13] IO PD 15 HYS [12] IO PD PD POWER [11] 1 No PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 vin6a_d5 38 TYPE [6] mcasp7_axr3 vin6a_d7 B15 MUXMODE [5] mcasp1_fsr vin6a_de0 E15 74x [4] 0 0 PU/PD 0 0 1 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv3 vddshv3 Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] A16 BALL NAME [2] mcasp2_axr3 SIGNAL NAME [3] B16 B17 A17 A20 mcasp2_axr4 mcasp2_axr5 mcasp2_axr6 mcasp2_axr7 mcasp2_fsr MUXMODE [5] TYPE [6] mcasp2_axr3 0 IO mcasp3_axr3 1 IO 7 I gpio6_9 14 IO Driver off 15 I mcasp2_axr4 0 IO mcasp8_axr0 1 IO vout2_d12 6 O vin4a_d12 8 I gpio1_4 14 IO Driver off 15 I mcasp2_axr5 0 IO mcasp8_axr1 1 IO vout2_d13 6 O vin4a_d13 8 I gpio6_7 14 IO Driver off 15 I mcasp2_axr6 0 IO mcasp8_aclkx 1 IO mcasp8_aclkr 2 IO vout2_d14 6 O vin4a_d14 8 I gpio2_29 14 IO Driver off 15 I mcasp2_axr7 0 IO mcasp8_fsx 1 IO mcasp8_fsr 2 IO vout2_d15 6 O vin4a_d15 8 I gpio1_5 14 IO Driver off 15 I mcasp2_fsr 0 IO mcasp8_axr3 1 IO vout2_d9 6 O vin4a_d9 8 I Driver off 15 I vin6a_d4 D15 74x [4] No BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv3 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 39 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] A18 BALL NAME [2] mcasp2_fsx SIGNAL NAME [3] mcasp2_fsx mcasp3_aclkx mcasp3_axr0 mcasp3_axr1 0 IO 1 IO mcasp2_axr12 2 IO 0 uart7_rxd 3 I 1 7 I 0 gpio5_13 14 IO Driver off 15 I mcasp3_axr0 0 IO mcasp2_axr14 2 IO uart7_ctsn 3 I 1 uart5_rxd 4 I 1 7 I 0 Driver off 15 I mcasp3_axr1 0 IO mcasp2_axr15 2 IO uart7_rtsn 3 O No mcasp3_fsx PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv3 vddshv3 Yes Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS Dual Voltage LVCMOS 0 0 PU/PD 0 0 0 PU/PD 0 0 4 O vin6a_d0 No 7 I 0 vin5a_fld0 No 9 I 0 Driver off 15 I mcasp3_fsx 0 IO mcasp3_fsr 1 IO mcasp2_axr13 2 IO uart7_txd 3 O vin6a_d2 40 PD vddshv3 Yes DSIS [15] mcasp3_aclkr 1.8/3.3 vddshv3 PULL UP/DOWN TYPE [14] mcasp3_aclkx 15 1.8/3.3 BUFFER TYPE [13] I PD 15 HYS [12] 15 PD PD POWER [11] Driver off No PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] I No uart5_txd F15 BALL RESET STATE [7] IO vin6a_d1 C17 TYPE [6] 7 vin6a_d3 B19 MUXMODE [5] 0 vin6a_d6 B18 74x [4] 7 I gpio5_14 14 IO Driver off 15 I Terminal Configuration and Functions No PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] C18 BALL NAME [2] mcasp4_aclkx SIGNAL NAME [3] 74x [4] 2 IO 0 3 I 1 i2c4_sda 4 IO 1 vout2_d16 6 O 8 I 0 9 I 0 Driver off 15 I mcasp4_axr0 0 IO spi3_d0 2 IO uart8_ctsn 3 I 1 uart4_rxd 4 I 1 vout2_d18 6 O 8 I 0 9 I 0 Driver off 15 I mcasp4_axr1 0 IO spi3_cs0 2 IO uart8_rtsn 3 O uart4_txd 4 O vout2_d19 6 O vin4a_d19 8 I 0 9 I 0 Driver off 15 I mcasp4_fsx 0 IO mcasp4_fsr 1 IO spi3_d1 2 IO uart8_txd 3 O i2c4_scl 4 IO vout2_d17 6 O 8 I 0 9 I 0 15 I vin5a_d13 mcasp4_axr1 vin5a_d12 A21 mcasp4_fsx No No vin4a_d17 vin5a_d14 Driver off No PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv3 vddshv3 vddshv3 Yes Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] uart8_rxd 1.8/3.3 vddshv3 PULL UP/DOWN TYPE [14] spi3_sclk 15 1.8/3.3 BUFFER TYPE [13] IO PD 15 HYS [12] IO PD PD POWER [11] 1 No PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 vin4a_d18 D17 BALL RESET STATE [7] mcasp4_aclkr vin5a_d15 mcasp4_axr0 TYPE [6] mcasp4_aclkx vin4a_d16 G16 MUXMODE [5] PU/PD 0 0 0 PU/PD 0 1 PU/PD 0 0 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 41 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AA3 BALL NAME [2] mcasp5_aclkx SIGNAL NAME [3] 74x [4] 2 IO 0 3 I 1 i2c5_sda 4 IO 1 mlb_clk 5 I 1 vout2_d20 6 O 8 I 0 9 I 0 Driver off 15 I mcasp5_axr0 0 IO spi4_d0 2 IO uart9_ctsn 3 I 1 uart3_rxd 4 I 1 mlb_sig 5 IO 1 vout2_d22 6 O 8 I 0 9 I 0 Driver off 15 I mcasp5_axr1 0 IO spi4_cs0 2 IO uart9_rtsn 3 O uart3_txd 4 O mlb_dat 5 IO vout2_d23 6 O 8 I 0 9 I 0 Driver off 15 I mcasp5_fsx 0 IO mcasp5_fsr 1 IO spi4_d1 2 IO uart9_txd 3 O i2c5_scl 4 IO vout2_d21 6 O 8 I 0 9 I 0 15 I vin5a_d9 mcasp5_axr1 No vin4a_d23 vin5a_d8 AB9 mcasp5_fsx No vin4a_d21 vin5a_d10 Driver off 42 Terminal Configuration and Functions No PD PD 15 1.8/3.3 vddshv7 vddshv7 Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] uart9_rxd 1.8/3.3 vddshv7 PULL UP/DOWN TYPE [14] spi4_sclk 15 1.8/3.3 BUFFER TYPE [13] IO PD 15 HYS [12] IO PD PD POWER [11] 1 No PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 vin4a_d22 AA4 BALL RESET STATE [7] mcasp5_aclkr vin5a_d11 mcasp5_axr0 TYPE [6] mcasp5_aclkx vin4a_d20 AB3 MUXMODE [5] PU/PD 0 0 0 PU/PD 0 1 1 PD PD 15 1.8/3.3 vddshv7 Yes Dual Voltage LVCMOS PU/PD 0 0 1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] U4 V1 BALL NAME [2] mdio_d mdio_mclk SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] IO I mii0_txer 3 O 0 vin2a_d0 4 I 0 vin4b_d0 5 I 0 gpio5_16 14 IO Driver off 15 I mdio_mclk 0 O uart3_rtsn 1 O mii0_col 3 I vin2a_clk0 4 I vin4b_clk1 5 I gpio5_15 14 IO vddshv9 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 1 1.8/3.3 vddshv9 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] uart3_ctsn PU 15 HYS [12] mdio_d PU PU POWER [11] 1 1 PU/PD 1 0 0 Driver off 15 I AB2 mlbp_clk_n mlbp_clk_n 0 I 1.8 vdds_mlbp No ILVDS18 NA AB1 mlbp_clk_p mlbp_clk_p 0 I 1.8 vdds_mlbp No ILVDS18 NA AA2 mlbp_dat_n mlbp_dat_n 0 IO OFF OFF 1.8 vdds_mlbp No BMLB18 NA AA1 mlbp_dat_p mlbp_dat_p 0 IO OFF OFF 1.8 vdds_mlbp No BMLB18 NA AC2 mlbp_sig_n mlbp_sig_n 0 IO OFF OFF 1.8 vdds_mlbp No BMLB18 NA AC1 mlbp_sig_p mlbp_sig_p 0 IO OFF OFF 1.8 vdds_mlbp No BMLB18 NA W6 mmc1_clk mmc1_clk 0 IO PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 gpio6_21 14 IO Driver off 15 I mmc1_cmd 0 IO PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 gpio6_22 14 IO Driver off 15 I mmc1_dat0 0 IO PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 gpio6_23 14 IO Driver off 15 I mmc1_dat1 0 IO PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 gpio6_24 14 IO Driver off 15 I mmc1_dat2 0 IO PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 gpio6_25 14 IO Driver off 15 I Y6 AA6 Y4 AA5 mmc1_cmd mmc1_dat0 mmc1_dat1 mmc1_dat2 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 43 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] Y3 W7 Y9 AD4 BALL NAME [2] mmc1_dat3 mmc1_sdcd mmc1_sdwp mmc3_clk SIGNAL NAME [3] mmc3_cmd mmc3_dat0 BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] 0 IO 14 IO Driver off 15 I mmc1_sdcd 0 I uart6_rxd 3 I i2c4_sda 4 IO gpio6_27 14 IO Driver off 15 I mmc1_sdwp 0 I uart6_txd 3 O i2c4_scl 4 IO gpio6_28 14 IO Driver off 15 I mmc3_clk 0 IO usb3_ulpi_d5 3 IO vin2b_d7 4 I 0 9 I 0 ehrpwm2_tripzone_input 10 IO 0 gpio6_29 14 IO Driver off 15 I mmc3_cmd 0 IO spi3_sclk 1 IO usb3_ulpi_d4 3 IO 0 vin2b_d6 4 I 0 9 I 0 eCAP2_in_PWM2_out 10 IO 0 gpio6_30 14 IO Driver off 15 I mmc3_dat0 0 IO spi3_d1 1 IO uart5_rxd 2 I 1 usb3_ulpi_d3 3 IO 0 vin2b_d5 4 I 0 9 I 0 eQEP3A_in 10 I 0 gpio6_31 14 IO Driver off 15 I vin5a_d5 44 TYPE [6] gpio6_26 vin5a_d6 AC7 MUXMODE [5] mmc1_dat3 vin5a_d7 AC4 74x [4] Terminal Configuration and Functions No No No PU PU 15 1.8/3.3 vddshv8 Yes SDIO1833 PU/PD 1 PU PU 15 1.8/3.3 vddshv8 Yes Dual Voltage LVCMOS PU/PD 1 1 1 PD PD 15 1.8/3.3 vddshv8 Yes Dual Voltage LVCMOS PU/PD 0 1 PU PU PU PU PU PU 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv7 vddshv7 vddshv7 Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 0 PU/PD 1 0 PU/PD 1 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AC6 BALL NAME [2] mmc3_dat1 SIGNAL NAME [3] mmc3_dat2 mmc3_dat3 mmc3_dat4 BALL RESET STATE [7] O usb3_ulpi_d2 3 IO 0 vin2b_d4 4 I 0 9 I 0 eQEP3B_in 10 I 0 gpio7_0 14 IO Driver off 15 I mmc3_dat2 0 IO spi3_cs0 1 IO uart5_ctsn 2 I 1 usb3_ulpi_d1 3 IO 0 vin2b_d3 4 I 0 9 I 0 eQEP3_index 10 IO 0 gpio7_1 14 IO Driver off 15 I mmc3_dat3 0 IO spi3_cs1 1 IO uart5_rtsn 2 O usb3_ulpi_d0 3 IO 0 vin2b_d2 4 I 0 9 I 0 eQEP3_strobe 10 IO 0 gpio7_2 14 IO Driver off 15 I mmc3_dat4 0 IO spi4_sclk 1 IO uart10_rxd 2 I 1 usb3_ulpi_nxt 3 I 0 vin2b_d1 4 I 0 9 I 0 ehrpwm3A 10 O gpio1_22 14 IO Driver off 15 I vin5a_d1 No No No PU PU PU PU 15 15 1.8/3.3 1.8/3.3 vddshv7 vddshv7 vddshv7 Yes Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 2 1.8/3.3 vddshv7 PULL UP/DOWN TYPE [14] uart5_txd 15 1.8/3.3 BUFFER TYPE [13] IO PU 15 HYS [12] IO PU PU POWER [11] 1 No PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 vin5a_d2 AC8 TYPE [6] spi3_d0 vin5a_d3 AC3 MUXMODE [5] mmc3_dat1 vin5a_d4 AC9 74x [4] 1 0 PU/PD 1 1 PU/PD 1 1 PU/PD 1 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 45 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AD6 BALL NAME [2] mmc3_dat5 SIGNAL NAME [3] mmc3_dat6 BALL RESET STATE [7] O usb3_ulpi_dir 3 I 0 vin2b_d0 4 I 0 9 I 0 ehrpwm3B 10 O gpio1_23 14 IO Driver off 15 I mmc3_dat6 0 IO spi4_d0 1 IO uart10_ctsn 2 I usb3_ulpi_stp 3 O 4 I 9 I 0 ehrpwm3_tripzone_input 10 IO 0 gpio1_24 14 IO Driver off 15 I mmc3_dat7 0 IO spi4_cs0 1 IO uart10_rtsn 2 O usb3_ulpi_clk 3 I vin2b_clk1 4 I vin5a_vsync0 No No vddshv7 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 0 PU/PD 1 0 1 PU PU 15 1.8/3.3 vddshv7 Yes Dual Voltage LVCMOS PU/PD 1 1 0 9 I 0 eCAP3_in_PWM3_out 10 IO 0 gpio1_25 14 IO Driver off 15 I D21 nmin_dsp nmin_dsp 0 I PD PD 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS Y11 on_off on_off 0 O PU drive 1 (OFF) 1.8/3.3 vddshv5 Yes BC1833IHH PU/PD V AG13 pcie_rxn0 pcie_rxn0 0 I OFF OFF 1.8 vdda_pcie0 AG11 pcie_rxn1 pcie_rxn1 0 I OFF OFF 1.8 vdda_pcie1 AH13 pcie_rxp0 pcie_rxp0 0 I OFF OFF 1.8 vdda_pcie0 AH11 pcie_rxp1 pcie_rxp1 0 I OFF OFF 1.8 vdda_pcie1 AG14 pcie_txn0 pcie_txn0 0 O 1.8 vdda_pcie0 AG12 pcie_txn1 pcie_txn1 0 O 1.8 vdda_pcie1 46 DSIS [15] 2 1.8/3.3 vddshv7 PULL UP/DOWN TYPE [14] uart10_txd 15 1.8/3.3 BUFFER TYPE [13] IO PU 15 HYS [12] IO PU PU POWER [11] 1 No PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 vin5a_hsync0 mmc3_dat7 TYPE [6] spi4_d1 vin2b_de1 AB5 MUXMODE [5] mmc3_dat5 vin5a_d0 AB8 74x [4] Terminal Configuration and Functions No No No PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] AH14 pcie_txp0 pcie_txp0 AH12 pcie_txp1 pcie_txp1 F22 porz E23 U5 V5 W2 Y2 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] 0 O 1.8 vdda_pcie0 0 O 1.8 vdda_pcie1 porz 0 I 1.8/3.3 vddshv3 Yes IHHV1833 PU/PD resetn resetn 0 I PU PU 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD rgmii0_rxc rgmii0_rxc 0 I PD PD 1.8/3.3 vddshv9 Yes 2 O Dual Voltage LVCMOS PU/PD rmii1_txen mii0_txclk 3 I 0 vin2a_d5 4 I 0 vin4b_d5 5 I 0 usb4_ulpi_d2 6 IO 0 gpio5_26 14 IO Driver off 15 I rgmii0_rxctl 0 I rmii1_txd1 2 O mii0_txd3 3 O vin2a_d6 4 I 0 vin4b_d6 5 I 0 usb4_ulpi_d3 6 IO 0 gpio5_27 14 IO Driver off 15 I rgmii0_rxd0 0 I rmii0_txd0 1 O mii0_txd0 3 O vin2a_fld0 4 I vin4b_fld1 5 I 0 usb4_ulpi_d7 6 IO 0 gpio5_31 14 IO Driver off 15 I rgmii0_rxd1 0 I rmii0_txd1 1 O mii0_txd1 3 O vin2a_d9 4 I 0 usb4_ulpi_d6 6 IO 0 gpio5_30 14 IO Driver off 15 I rgmii0_rxctl rgmii0_rxd0 rgmii0_rxd1 No PD PD PD PD PD PD 15 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv9 vddshv9 vddshv9 Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD PU/PD 0 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 47 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] V3 V4 W9 V9 48 BALL NAME [2] rgmii0_rxd2 rgmii0_rxd3 rgmii0_txc rgmii0_txctl SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] O mii0_txen 3 O vin2a_d8 4 I 0 usb4_ulpi_d5 6 IO 0 gpio5_29 14 IO Driver off 15 I rgmii0_rxd3 0 I rmii1_txd0 2 O mii0_txd2 3 O vin2a_d7 4 I 0 vin4b_d7 5 I 0 usb4_ulpi_d4 6 IO 0 gpio5_28 14 IO Driver off 15 I rgmii0_txc 0 O uart3_ctsn 1 I rmii1_rxd1 2 I 0 mii0_rxd3 3 I 0 vin2a_d3 4 I 0 vin4b_d3 5 I 0 usb4_ulpi_clk 6 I 0 spi3_d0 7 IO 0 spi4_cs2 8 IO 1 gpio5_20 14 IO Driver off 15 I rgmii0_txctl 0 O uart3_rtsn 1 O rmii1_rxd0 2 I 0 mii0_rxd2 3 I 0 vin2a_d4 4 I 0 vin4b_d4 5 I 0 usb4_ulpi_stp 6 O spi3_cs0 7 IO 1 spi4_cs3 8 IO 1 gpio5_21 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv9 vddshv9 vddshv9 Yes Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] I 1.8/3.3 vddshv9 PULL UP/DOWN TYPE [14] 1 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] rmii0_txen PD PD POWER [11] rgmii0_rxd2 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PU/PD 0 0 PU/PD 1 PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] U6 V6 U7 BALL NAME [2] rgmii0_txd0 rgmii0_txd1 rgmii0_txd2 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O I mii0_rxd0 3 I 0 vin2a_d10 4 I 0 usb4_ulpi_d1 6 IO 0 spi4_cs0 7 IO 1 uart4_rtsn 8 O gpio5_25 14 IO Driver off 15 I rgmii0_txd1 0 O rmii0_rxd1 1 I mii0_rxd1 3 I vin2a_vsync0 4 I vin4b_vsync1 5 I 0 usb4_ulpi_d0 6 IO 0 spi4_d0 7 IO 0 uart4_ctsn 8 IO 1 gpio5_24 14 IO Driver off 15 I rgmii0_txd2 0 O rmii0_rxer 1 I mii0_rxer 3 I vin2a_hsync0 4 I vin4b_hsync1 5 I 0 usb4_ulpi_nxt 6 I 0 spi4_d1 7 IO 0 uart4_txd 8 O gpio5_23 14 IO Driver off 15 I vddshv9 Yes Yes Dual Voltage LVCMOS DSIS [15] 1 1.8/3.3 vddshv9 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] rmii0_rxd0 PD 15 HYS [12] rgmii0_txd0 PD PD POWER [11] Dual Voltage LVCMOS PU/PD 0 PU/PD 0 0 PD PD 15 1.8/3.3 vddshv9 Yes Dual Voltage LVCMOS PU/PD 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 49 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] V7 U3 BALL NAME [2] rgmii0_txd3 RMII_MHZ_50_CLK SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv9 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] rgmii0_txd3 0 O rmii0_crs 1 I mii0_crs 3 I vin2a_de0 4 I PU/PD vin4b_de1 5 I 0 usb4_ulpi_dir 6 I 0 spi4_sclk 7 IO 0 uart4_rxd 8 I 1 gpio5_22 14 IO Driver off 15 I RMII_MHZ_50_CLK 0 IO vin2a_d11 4 I gpio5_17 14 IO 0 0 PD PD Driver off 15 I F23 rstoutn rstoutn 0 O PD drive 1 (OFF) E18 rtck rtck 0 O PU gpio8_29 14 IO drive clk (OFF) 15 0 1.8/3.3 vddshv9 Yes Dual Voltage LVCMOS PU/PD 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD rtc_iso rtc_iso 0 I 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD AE14 rtc_osc_xi_clkin32 rtc_osc_xi_clkin32 0 I 1.8 vdda_rtc No LVCMOS OSC NA AD14 rtc_osc_xo rtc_osc_xo 0 O 1.8 vdda_rtc No LVCMOS OSC NA AB17 rtc_porz rtc_porz 0 I 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD AH9 sata1_rxn0 sata1_rxn0 0 I OFF OFF 1.8 vdda_sata NA SATAPHY NA AG9 sata1_rxp0 sata1_rxp0 0 I OFF OFF 1.8 vdda_sata NA SATAPHY NA AG10 sata1_txn0 sata1_txn0 0 O 1.8 vdda_sata NA SATAPHY NA AH10 sata1_txp0 sata1_txp0 0 O 1.8 vdda_sata NA SATAPHY NA A24 spi1_cs0 spi1_cs0 0 IO gpio7_10 14 IO Driver off 15 I spi1_cs1 0 IO sata1_led 2 O spi2_cs1 3 IO gpio7_11 14 IO Driver off 15 I 50 spi1_cs1 Terminal Configuration and Functions 0 0 AF14 A22 DSIS [15] PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1 PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1 1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] B21 B20 B25 F16 A25 B24 G17 BALL NAME [2] spi1_cs2 spi1_cs3 spi1_d0 spi1_d1 spi1_sclk spi2_cs0 spi2_d0 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] IO I mmc3_sdcd 2 I 1 spi2_cs2 3 IO 1 dcan2_tx 4 IO 1 mdio_mclk 5 O 1 hdmi1_hpd 6 I gpio7_12 14 IO Driver off 15 I spi1_cs3 0 IO uart4_txd 1 O mmc3_sdwp 2 I 0 spi2_cs3 3 IO 1 dcan2_rx 4 IO 1 mdio_d 5 IO 1 hdmi1_cec 6 IO gpio7_13 14 IO Driver off 15 I spi1_d0 0 IO gpio7_9 14 IO Driver off 15 I spi1_d1 0 IO gpio7_8 14 IO Driver off 15 I spi1_sclk 0 IO gpio7_7 14 IO Driver off 15 I spi2_cs0 0 IO uart3_rtsn 1 O uart5_txd 2 O gpio7_17 14 IO Driver off 15 I spi2_d0 0 IO uart3_ctsn 1 I uart5_rxd 2 I gpio7_16 14 IO Driver off 15 I vddshv3 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 1 1.8/3.3 vddshv3 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] uart4_rxd PU 15 HYS [12] spi1_cs2 PU PU POWER [11] 1 1 PU/PD 1 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 PU PU 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 1 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 51 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] B22 A26 BALL NAME [2] spi2_d1 spi2_sclk SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] spi2_d1 0 IO uart3_txd 1 O gpio7_15 14 IO Driver off 15 I spi2_sclk 0 IO uart3_rxd 1 I gpio7_14 14 IO BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 1 Driver off 15 I E20 tclk tclk 0 I PU PU 0 1.8/3.3 vddshv3 Yes IQ1833 PU/PD D23 tdi tdi 0 I PU PU 0 1.8/3.3 vddshv3 Yes PU/PD gpio8_27 14 I Dual Voltage LVCMOS tdo 0 O PU PU 0 1.8/3.3 vddshv3 Yes 14 IO Dual Voltage LVCMOS PU/PD gpio8_28 0 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 1.8/3.3 vddshv4 Yes Dual Voltage LVCMOS PU/PD F19 tdo F18 tms tms 0 IO OFF OFF D20 trstn trstn 0 I PD PD E25 uart1_ctsn uart1_ctsn 0 I PU PU uart9_rxd 2 I mmc4_clk 3 IO gpio7_24 14 IO Driver off 15 I uart1_rtsn 0 O uart9_txd 2 O mmc4_cmd 3 IO gpio7_25 14 IO Driver off 15 I uart1_rxd 0 I mmc4_sdcd 3 I gpio7_22 14 IO Driver off 15 I uart1_txd 0 O mmc4_sdwp 3 I gpio7_23 14 IO Driver off 15 I C27 B27 C26 52 uart1_rtsn uart1_rxd uart1_txd Terminal Configuration and Functions DSIS [15] 15 1 1 1 PU PU 15 1.8/3.3 vddshv4 Yes Dual Voltage LVCMOS PU/PD 1 PU PU PU PU 15 15 1.8/3.3 1.8/3.3 vddshv4 vddshv4 Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 1 1 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] D27 C28 D28 D26 BALL NAME [2] uart2_ctsn uart2_rtsn uart2_rxd uart2_txd SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PU BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] I I mmc4_dat2 3 IO 1 uart10_rxd 4 I 1 uart1_dtrn 5 O gpio1_16 14 IO Driver off 15 I uart2_rtsn 0 O uart3_txd 1 O uart3_irtx 2 O mmc4_dat3 3 IO uart10_txd 4 O uart1_rin 5 I gpio1_17 14 IO Driver off 15 I uart3_ctsn 1 I uart3_rctx 2 O mmc4_dat0 3 IO 1 uart2_rxd 4 I 1 uart1_dcdn 5 I 1 gpio7_26 14 IO Driver off 15 I uart2_txd 0 O uart3_rtsn 1 O uart3_sd 2 O mmc4_dat1 3 IO uart2_txd 4 O uart1_dsrn 5 I gpio7_27 14 IO Driver off 15 I vddshv4 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 2 1.8/3.3 vddshv4 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] uart3_rxd PU 15 HYS [12] uart2_ctsn PU PU POWER [11] 1 1 PU/PD 1 1 PU PU PU PU 15 15 1.8/3.3 1.8/3.3 vddshv4 vddshv4 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 PU/PD 1 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 53 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] V2 Y1 BALL NAME [2] uart3_rxd uart3_txd SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] I I mii0_rxdv 3 I 0 vin2a_d1 4 I 0 vin4b_d1 5 I 0 spi3_sclk 7 IO 0 gpio5_18 14 IO Driver off 15 I uart3_txd 0 O rmii1_rxer 2 I mii0_rxclk 3 I 0 vin2a_d2 4 I 0 vin4b_d2 5 I 0 spi3_d1 7 IO 0 spi4_cs1 8 IO 1 gpio5_19 14 IO vddshv9 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD 0 Driver off 15 I usb1_dm usb1_dm 0 IO OFF OFF 3.3 vdda33v_us NA b1 USB3PHY NA AD12 usb1_dp usb1_dp 0 IO OFF OFF 3.3 vdda33v_us NA b1 USB3PHY NA AB10 usb1_drvvbus usb1_drvvbus 0 O PD PD 1.8/3.3 vddshv6 7 IO Dual Voltage LVCMOS PU/PD timer16 gpio6_12 14 IO Driver off 15 I 15 Yes AF11 usb2_dm usb2_dm 0 IO 3.3 vdda33v_us No b2 USB2PHY NA AE11 usb2_dp usb2_dp 0 IO 3.3 vdda33v_us No b2 USB2PHY NA AC10 usb2_drvvbus usb2_drvvbus 0 O 1.8/3.3 vddshv6 7 IO Dual Voltage LVCMOS PU/PD timer15 gpio6_13 14 IO Driver off 15 I PD PD 15 AF12 usb_rxn0 usb_rxn0 0 I OFF OFF 1.8 vdda_usb1 AE12 usb_rxp0 usb_rxp0 0 I OFF OFF 1.8 vdda_usb1 AC11 usb_txn0 usb_txn0 0 O 1.8 vdda_usb1 AD11 usb_txp0 usb_txp0 0 O 1.8 vdda_usb1 Terminal Configuration and Functions Yes 1 0 AC12 54 DSIS [15] 2 1.8/3.3 vddshv9 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] rmii1_crs PD 15 HYS [12] uart3_rxd PD PD POWER [11] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] H13, H14, J17, J18, vdd L7, L8, N10, N13, P11, P12, P13, R11, R16, R19, T13, T16, T19, U13, U16, U8, U9, V16, V8 vdd PWR AA12 vdda33v_usb1 vdda33v_usb1 PWR Y12 vdda33v_usb2 vdda33v_usb2 PWR M14 vdda_abe_per vdda_abe_per PWR P16 vdda_ddr vdda_ddr PWR N11 vdda_debug vdda_debug PWR N12 vdda_dsp_eve vdda_dsp_eve PWR P15 vdda_gmac_core vdda_gmac_core PWR R14 vdda_gpu vdda_gpu PWR Y17 vdda_hdmi vdda_hdmi PWR R17 vdda_iva vdda_iva PWR N16 vdda_mpu vdda_mpu PWR AD16, AE16 vdda_osc vdda_osc PWR W14 vdda_pcie vdda_pcie PWR AA17 vdda_pcie0 vdda_pcie0 PWR AA16 vdda_pcie1 vdda_pcie1 PWR AB13 vdda_rtc vdda_rtc PWR V13 vdda_sata vdda_sata PWR AA13 vdda_usb1 vdda_usb1 PWR AB12 vdda_usb2 vdda_usb2 PWR W12 vdda_usb3 vdda_usb3 PWR P14 vdda_video vdda_video PWR G18, H17, M8, M9, vdds18v N8, P8, R8, T8, V21, V22, W17, W18 vdds18v PWR AA18, AA19, W21, Y21 vdds18v_ddr1 vdds18v_ddr1 PWR J21, J22, N21, P20, vdds18v_ddr2 P21 vdds18v_ddr2 PWR E3, E5, G4, G5, H8, vddshv1 H9 vddshv1 PWR N4, N5, P10, R10, R7, T4, T5 vddshv10 vddshv10 PWR J8, K8 vddshv11 vddshv11 PWR BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 55 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] BALL NAME [2] SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] B6, D10, E10, H10, vddshv2 H11 vddshv2 PWR B23, D16, D22, E16, E22, G15, H15, H16, H18, H19 vddshv3 vddshv3 PWR C24 vddshv4 vddshv4 PWR V12 vddshv5 vddshv5 PWR AD5, AD7, AE7, AF5 vddshv6 vddshv6 PWR AB6, AB7 vddshv7 vddshv7 PWR W8, Y8 vddshv8 vddshv8 PWR U10, W4, W5 vddshv9 vddshv9 PWR AA21, AA22, AB21, vdds_ddr1 AB22, AB24, AB25, AC22, AD26, AG20, AG28, AH27, W16, W27 vdds_ddr1 PWR E24, G22, G23, vdds_ddr2 H20, H21, H22, J27, L20, L21, M20, M21, T24, T25 vdds_ddr2 PWR AA7, Y7 vdds_mlbp PWR J13, K10, K11, K12, vdd_dspeve K13, L10, L11, L12, M10, M11, M12, M13 vdds_mlbp vdd_dspeve PWR U11, U12, V10, V11, V14, W10, W11, W13 vdd_gpu PWR U18, U19, V18, V19 vdd_iva vdd_iva PWR K17, K18, L15, L16, vdd_mpu L17, L18, L19, M15, M16, M17, M18, N17, N18, P17, P18, R18 vdd_mpu PWR AB15 vdd_rtc vdd_rtc AG8 vin1a_clk0 vin1a_clk0 vdd_gpu 0 I No 3 O vout3_fld (9) No 4 O gpio2_30 Yes (7) 14 IO 15 I Driver off 56 Terminal Configuration and Functions BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] DSIS [15] PWR No vout3_d16 BALL RESET STATE [7] (9) PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AE8 BALL NAME [2] vin1a_d0 SIGNAL NAME [3] 74x [4] vin1a_d1 No 0 I vout3_d7 (9) No 3 O vout3_d23 (9) No 4 O uart8_rxd No 5 I ehrpwm1A No 10 O gpio3_4 Yes (7) 14 IO 15 I vin1a_d1 No 0 I vout3_d6 (9) No 3 O vout3_d22 (9) No 4 O uart8_txd No 5 O ehrpwm1B No 10 O gpio3_5 Yes (7) 14 IO 15 I Driver off AG3 vin1a_d10 vin1a_d10 No 0 I vin1b_d5 No 1 I vout3_d13 (9) No 4 O kbd_row4 No 9 I gpio3_14 Yes (7) 14 IO Driver off AG5 vin1a_d11 15 I vin1a_d11 No 0 I vin1b_d4 No 1 I vout3_d12 (9) No 4 O gpmc_a23 No 5 O kbd_row5 No 9 I 14 IO gpio3_15 Yes (7) Driver off AF2 vin1a_d12 TYPE [6] vin1a_d0 Driver off AD8 MUXMODE [5] 15 I vin1a_d12 No 0 I vin1b_d3 No 1 I usb3_ulpi_d7 No 2 IO vout3_d11 (9) No 4 O gpmc_a24 No 5 O kbd_row6 No 9 I gpio3_16 Yes (7) 14 IO 15 I Driver off BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 1 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 57 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AF6 BALL NAME [2] vin1a_d13 SIGNAL NAME [3] 74x [4] No 0 I vin1b_d2 No 1 I usb3_ulpi_d6 No 2 IO (9) No 4 O gpmc_a25 No 5 O kbd_row7 No 9 I 14 IO gpio3_17 Yes (7) Driver off vin1a_d14 15 I vin1a_d14 No 0 I vin1b_d1 No 1 I usb3_ulpi_d5 No 2 IO vout3_d9 (9) No 4 O gpmc_a26 No 5 O kbd_row8 No 9 I gpio3_18 Yes (7) 14 IO Driver off AF4 vin1a_d15 15 I vin1a_d15 No 0 I vin1b_d0 No 1 I usb3_ulpi_d4 No 2 IO vout3_d8 (9) No 4 O gpmc_a27 No 5 O kbd_col0 No 9 O gpio3_19 Yes (7) 14 IO 15 I Driver off AF1 vin1a_d16 vin1a_d16 No 0 I vin1b_d7 No 1 I usb3_ulpi_d3 No 2 IO vout3_d7 (9) No 4 O vin3a_d0 No 6 I kbd_col1 No 9 O gpio3_20 Yes (7) 14 IO 15 I Driver off 58 TYPE [6] vin1a_d13 vout3_d10 AF3 MUXMODE [5] Terminal Configuration and Functions BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AE3 BALL NAME [2] vin1a_d17 SIGNAL NAME [3] 74x [4] No 0 I vin1b_d6 No 1 I usb3_ulpi_d2 No 2 IO No 4 O vin3a_d1 No 6 I kbd_col2 No 9 O gpio3_21 Yes (7) 14 IO 15 I (9) Driver off vin1a_d18 vin1a_d18 No 0 I vin1b_d5 No 1 I usb3_ulpi_d1 No 2 IO vout3_d5 (9) No 4 O vin3a_d2 No 6 I kbd_col3 No 9 O gpio3_22 Yes (7) 14 IO Driver off AE1 vin1a_d19 15 I vin1a_d19 No 0 I vin1b_d4 No 1 I usb3_ulpi_d0 No 2 IO vout3_d4 (9) No 4 O vin3a_d3 No 6 I kbd_col4 No 9 O gpio3_23 Yes (7) 14 IO 15 I Driver off AG7 vin1a_d2 TYPE [6] vin1a_d17 vout3_d6 AE5 MUXMODE [5] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 vin1a_d2 No 0 I vout3_d5 (9) No 3 O vout3_d21 (9) No 4 O uart8_ctsn No 5 I 1 ehrpwm1_tripzone_input No 10 IO 0 gpio3_6 Yes (7) 14 IO 15 I Driver off PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 59 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AE2 BALL NAME [2] vin1a_d20 SIGNAL NAME [3] 74x [4] No 0 I vin1b_d3 No 1 I usb3_ulpi_nxt No 2 I No 4 O vin3a_d4 No 6 I kbd_col5 No 9 O gpio3_24 Yes (7) 14 IO 15 I (9) Driver off vin1a_d21 vin1a_d21 No 0 I vin1b_d2 No 1 I usb3_ulpi_dir No 2 I vout3_d2 (9) No 4 O vin3a_d5 No 6 I kbd_col6 No 9 O gpio3_25 Yes (7) 14 IO Driver off AD2 vin1a_d22 15 I vin1a_d22 No 0 I vin1b_d1 No 1 I usb3_ulpi_stp No 2 O vout3_d1 (9) No 4 O vin3a_d6 No 6 I kbd_col7 No 9 O gpio3_26 Yes (7) 14 IO 15 I Driver off AD3 vin1a_d23 vin1a_d23 No 0 I vin1b_d0 No 1 I usb3_ulpi_clk No 2 I vout3_d0 (9) No 4 O vin3a_d7 No 6 I kbd_col8 No 9 O gpio3_27 Yes (7) 14 IO 15 I Driver off 60 TYPE [6] vin1a_d20 vout3_d3 AE6 MUXMODE [5] Terminal Configuration and Functions BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AH6 BALL NAME [2] vin1a_d3 SIGNAL NAME [3] 74x [4] vin1a_d4 No 0 I vout3_d4 (9) No 3 O vout3_d20 (9) No 4 O uart8_rtsn No 5 O eCAP1_in_PWM1_out No 10 IO gpio3_7 Yes (7) 14 IO 15 I vin1a_d4 No 0 I vout3_d3 (9) No 3 O vout3_d19 (9) No 4 O ehrpwm1_synci No 10 I 14 IO gpio3_8 Yes (7) Driver off AH5 vin1a_d5 15 I vin1a_d5 No 0 I vout3_d2 (9) No 3 O vout3_d18 (9) No 4 O ehrpwm1_synco No 10 O gpio3_9 Yes (7) 14 IO Driver off AG6 vin1a_d6 15 I No 0 I No 3 O vout3_d17 (9) No 4 O eQEP2A_in No 10 I gpio3_10 Yes (7) 14 IO vin1a_d6 vout3_d1 (9) Driver off AH4 vin1a_d7 TYPE [6] vin1a_d3 Driver off AH3 MUXMODE [5] 15 I vin1a_d7 No 0 I vout3_d0 (9) No 3 O vout3_d16 (9) No 4 O eQEP2B_in No 10 I gpio3_11 Yes (7) 14 IO 15 I Driver off BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 61 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AG4 BALL NAME [2] vin1a_d8 SIGNAL NAME [3] 74x [4] vin1a_de0 Yes Dual Voltage LVCMOS PU/PD DSIS [15] I vout3_d15 (9) No 4 O kbd_row2 No 9 I 0 eQEP2_index No 10 IO 0 14 IO 0 0 15 I vin1a_d9 No 0 I vin1b_d6 No 1 I vout3_d14 (9) No 4 O kbd_row3 No 9 I 0 eQEP2_strobe No 10 IO 0 gpio3_13 Yes (7) 14 IO PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 15 I vin1a_de0 No 0 I vin1b_hsync1 No 1 I vout3_d17 (9) No 3 O vout3_de (9) No 4 O uart7_rxd No 5 I timer16 No 7 IO spi3_sclk No 8 IO 0 kbd_row0 No 9 I 0 eQEP1A_in No 10 I 0 14 IO Yes (7) PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 1 15 I vin1a_fld0 No 0 I vin1b_vsync1 No 1 I vout3_clk (9) No 4 O uart7_txd No 5 O timer15 No 7 IO spi3_d1 No 8 IO 0 kbd_row1 No 9 I 0 eQEP1B_in No 10 I 0 14 IO 15 I gpio3_1 Driver off 62 vddshv6 PULL UP/DOWN TYPE [14] I Driver off vin1a_fld0 1.8/3.3 BUFFER TYPE [13] 1 gpio3_0 AF9 15 HYS [12] 0 Yes PD POWER [11] No (7) PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] No Driver off AD9 BALL RESET STATE [7] vin1b_d7 Driver off vin1a_d9 TYPE [6] vin1a_d8 gpio3_12 AG2 MUXMODE [5] Terminal Configuration and Functions Yes (7) PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AE9 BALL NAME [2] vin1a_hsync0 SIGNAL NAME [3] 74x [4] vin1a_vsync0 E1 vin2a_clk0 PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv6 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] No 0 I No 1 I vout3_hsync (9) No 4 O uart7_ctsn No 5 I timer14 No 7 IO spi3_d0 No 8 IO 0 eQEP1_index No 10 IO 0 gpio3_2 Yes (7) 14 IO 0 0 1 15 I vin1a_vsync0 No 0 I vin1b_de1 No 1 I vout3_vsync (9) No 4 O uart7_rtsn No 5 O timer13 No 7 IO spi3_cs0 No 8 IO 1 eQEP1_strobe No 10 IO 0 14 IO Yes (7) Driver off vin1b_clk1 BALL RESET STATE [7] vin1b_fld1 gpio3_3 AH7 TYPE [6] vin1a_hsync0 Driver off AF8 MUXMODE [5] PD PD 15 1.8/3.3 vddshv6 Yes Dual Voltage LVCMOS PU/PD 0 0 15 I vin1b_clk1 No 0 I vin3a_clk0 No 6 I gpio2_31 Yes (7) 14 IO Driver off 15 I vin2a_clk0 0 I vout2_fld 4 O emu5 5 O kbd_row0 9 I 0 eQEP1A_in 10 I 0 gpio3_28 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv6 vddshv1 Yes Yes Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 63 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] F2 F3 D3 F6 64 BALL NAME [2] vin2a_d0 vin2a_d1 vin2a_d10 vin2a_d11 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] O emu10 5 O uart9_ctsn 7 I 1 spi4_d0 8 IO 0 kbd_row4 9 I 0 ehrpwm1B 10 O gpio4_1 14 IO Driver off 15 I vin2a_d1 0 I vout2_d22 4 O emu11 5 O uart9_rtsn 7 O spi4_cs0 8 IO 1 kbd_row5 9 I 0 ehrpwm1_tripzone_input 10 IO 0 gpio4_2 14 IO Driver off 15 I vin2a_d10 0 I mdio_mclk 3 O vout2_d13 4 O kbd_col7 9 O ehrpwm2B 10 O gpio4_11 14 IO Driver off 15 I vin2a_d11 0 I mdio_d 3 IO vout2_d12 4 O kbd_row7 9 I 0 ehrpwm2_tripzone_input 10 IO 0 gpio4_12 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv1 vddshv1 vddshv1 Yes Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] I 1.8/3.3 vddshv1 PULL UP/DOWN TYPE [14] 4 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] vout2_d23 PD PD POWER [11] vin2a_d0 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PU/PD Dual Voltage LVCMOS PU/PD Dual Voltage LVCMOS PU/PD 0 0 0 1 0 1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] D5 C2 C3 C4 BALL NAME [2] vin2a_d12 vin2a_d13 vin2a_d14 vin2a_d15 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv1 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] vin2a_d12 0 I rgmii1_txc 3 O 0 vout2_d11 4 O mii1_rxclk 8 I kbd_col8 9 O eCAP2_in_PWM2_out 10 IO gpio4_13 14 IO Driver off 15 I vin2a_d13 0 I rgmii1_txctl 3 O vout2_d10 4 O mii1_rxdv 8 I 0 kbd_row8 9 I 0 eQEP3A_in 10 I 0 gpio4_14 14 IO Driver off 15 I vin2a_d14 0 I rgmii1_txd3 3 O vout2_d9 4 O mii1_txclk 8 I 0 eQEP3B_in 10 I 0 gpio4_15 14 IO Driver off 15 I vin2a_d15 0 I rgmii1_txd2 3 O vout2_d8 4 O mii1_txd0 8 O eQEP3_index 10 IO gpio4_16 14 IO Driver off 15 I 0 0 PD PD PD PD PD PD 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv1 vddshv1 vddshv1 Yes Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD PU/PD 0 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 65 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] B2 D6 C5 A3 66 BALL NAME [2] vin2a_d16 vin2a_d17 vin2a_d18 vin2a_d19 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD 15 1.8/3.3 POWER [11] vddshv1 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] vin2a_d16 0 I vin2b_d7 2 I rgmii1_txd1 3 O vout2_d7 4 O vin3a_d8 6 I mii1_txd1 8 O eQEP3_strobe 10 IO gpio4_24 14 IO Driver off 15 I vin2a_d17 0 I vin2b_d6 2 I rgmii1_txd0 3 O vout2_d6 4 O vin3a_d9 6 I mii1_txd2 8 O ehrpwm3A 10 O gpio4_25 14 IO Driver off 15 I vin2a_d18 0 I vin2b_d5 2 I rgmii1_rxc 3 I vout2_d5 4 O vin3a_d10 6 I mii1_txd3 8 O ehrpwm3B 10 O gpio4_26 14 IO Driver off 15 I vin2a_d19 0 I vin2b_d4 2 I rgmii1_rxctl 3 I vout2_d4 4 O vin3a_d11 6 I 0 mii1_txer 8 O 0 ehrpwm3_tripzone_input 10 IO 0 gpio4_27 14 IO Driver off 15 I Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] D1 B3 B4 B5 BALL NAME [2] vin2a_d2 vin2a_d20 vin2a_d21 vin2a_d22 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] I O emu12 5 O uart10_rxd 8 I 1 kbd_row6 9 I 0 eCAP1_in_PWM1_out 10 IO 0 gpio4_3 14 IO Driver off 15 I vin2a_d20 0 I vin2b_d3 2 I rgmii1_rxd3 3 I vout2_d3 4 O vin3a_de0 5 I 0 vin3a_d12 6 I 0 mii1_rxer 8 I 0 eCAP3_in_PWM3_out 10 IO 0 gpio4_28 14 IO Driver off 15 I vin2a_d21 0 I vin2b_d2 2 I rgmii1_rxd2 3 I vout2_d2 4 O vin3a_fld0 5 I 0 vin3a_d13 6 I 0 mii1_col 8 I 0 gpio4_29 14 IO Driver off 15 I vin2a_d22 0 I vin2b_d1 2 I rgmii1_rxd1 3 I vout2_d1 4 O vin3a_hsync0 5 I 0 vin3a_d14 6 I 0 mii1_crs 8 I 0 gpio4_30 14 IO Driver off 15 I vddshv1 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD DSIS [15] 4 1.8/3.3 vddshv1 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] vout2_d21 PD 15 HYS [12] vin2a_d2 PD PD POWER [11] PU/PD 0 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 67 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] A4 E2 D2 F4 68 BALL NAME [2] vin2a_d23 vin2a_d3 vin2a_d4 vin2a_d5 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD 15 1.8/3.3 POWER [11] vddshv1 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] vin2a_d23 0 I vin2b_d0 2 I rgmii1_rxd0 3 I vout2_d0 4 O vin3a_vsync0 5 I 0 vin3a_d15 6 I 0 mii1_txen 8 O gpio4_31 14 IO Driver off 15 I vin2a_d3 0 I vout2_d20 4 O emu13 5 O uart10_txd 8 O kbd_col0 9 O ehrpwm1_synci 10 I gpio4_4 14 IO Driver off 15 I vin2a_d4 0 I vout2_d19 4 O emu14 5 O uart10_ctsn 8 I kbd_col1 9 O ehrpwm1_synco 10 O gpio4_5 14 IO Driver off 15 I vin2a_d5 0 I vout2_d18 4 O emu15 5 O uart10_rtsn 8 O kbd_col2 9 O eQEP2A_in 10 I gpio4_6 14 IO Driver off 15 I Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 1 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] C1 E4 F5 E6 BALL NAME [2] vin2a_d6 vin2a_d7 vin2a_d8 vin2a_d9 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] vin2a_d6 0 I vout2_d17 4 O emu16 5 O mii1_rxd1 8 I kbd_col3 9 O eQEP2B_in 10 I gpio4_7 14 IO Driver off 15 I vin2a_d7 0 I vout2_d16 4 O emu17 5 O mii1_rxd2 8 I kbd_col4 9 O eQEP2_index 10 IO gpio4_8 14 IO Driver off 15 I vin2a_d8 0 I vout2_d15 4 O emu18 5 O mii1_rxd3 8 I kbd_col5 9 O eQEP2_strobe 10 IO gpio4_9 14 IO Driver off 15 I vin2a_d9 0 I vout2_d14 4 O emu19 5 O mii1_rxd0 8 I kbd_col6 9 O ehrpwm2A 10 O gpio4_10 14 IO Driver off 15 I BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv1 HYS [12] Yes BUFFER TYPE [13] Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] PU/PD DSIS [15] 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 0 PD PD 15 1.8/3.3 vddshv1 Yes Dual Voltage LVCMOS PU/PD 0 0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 69 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] G2 H7 G1 G6 70 BALL NAME [2] vin2a_de0 vin2a_fld0 vin2a_hsync0 vin2a_vsync0 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] I vin2b_fld1 2 I vin2b_de1 3 I vout2_de 4 O emu6 5 O kbd_row1 9 I 0 eQEP1B_in 10 I 0 gpio3_29 14 IO Driver off 15 I vin2a_fld0 0 I vin2b_clk1 2 I vout2_clk 4 O emu7 5 O eQEP1_index 10 IO gpio3_30 14 IO Driver off 15 I vin2a_hsync0 0 I vin2b_hsync1 3 I vout2_hsync 4 O emu8 5 O uart9_rxd 7 I 1 spi4_sclk 8 IO 0 kbd_row2 9 I 0 eQEP1_strobe 10 IO 0 gpio3_31 14 IO Driver off 15 I vin2a_vsync0 0 I vin2b_vsync1 3 I vout2_vsync 4 O emu9 5 O uart9_txd 7 O spi4_d1 8 IO 0 kbd_row3 9 I 0 ehrpwm1A 10 O gpio4_0 14 IO Driver off 15 I vddshv1 Yes Yes Dual Voltage LVCMOS DSIS [15] I 1.8/3.3 vddshv1 PULL UP/DOWN TYPE [14] 1 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] vin2a_fld0 PD PD POWER [11] vin2a_de0 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS PU/PD PU/PD 0 PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv1 vddshv1 Yes Yes Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] D11 F11 G10 D7 D8 BALL NAME [2] vout1_clk vout1_d0 vout1_d1 vout1_d10 vout1_d11 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O I vin3a_fld0 4 I 0 spi3_cs0 8 IO 1 gpio4_19 14 IO Driver off 15 I vout1_d0 0 O uart5_rxd 2 I vin4a_d16 3 I 0 vin3a_d16 4 I 0 spi3_cs2 8 IO 1 gpio8_0 14 IO Driver off 15 I vout1_d1 0 O uart5_txd 2 O vin4a_d17 3 I 0 vin3a_d17 4 I 0 gpio8_1 14 IO Driver off 15 I vout1_d10 0 O emu3 2 O vin4a_d10 3 I 0 vin3a_d10 4 I 0 obs5 5 O obs21 6 O obs_irq2 7 O gpio8_10 14 IO Driver off 15 I vout1_d11 0 O emu10 2 O vin4a_d11 3 I 0 vin3a_d11 4 I 0 obs6 5 O obs22 6 O obs_dmarq2 7 O gpio8_11 14 IO Driver off 15 I PD PD PD PD PD PD 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 3 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] vin4a_fld0 PD 15 HYS [12] vout1_clk PD PD POWER [11] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 0 PU/PD 1 PU/PD PU/PD PU/PD Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 71 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] A5 C6 C8 C7 72 BALL NAME [2] vout1_d12 vout1_d13 vout1_d14 vout1_d15 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] O vin4a_d12 3 I 0 vin3a_d12 4 I 0 obs7 5 O obs23 6 O gpio8_12 14 IO Driver off 15 I vout1_d13 0 O emu12 2 O vin4a_d13 3 I 0 vin3a_d13 4 I 0 obs8 5 O obs24 6 O gpio8_13 14 IO Driver off 15 I vout1_d14 0 O emu13 2 O vin4a_d14 3 I 0 vin3a_d14 4 I 0 obs9 5 O obs25 6 O gpio8_14 14 IO Driver off 15 I vout1_d15 0 O emu14 2 O vin4a_d15 3 I 0 vin3a_d15 4 I 0 obs10 5 O obs26 6 O gpio8_15 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] O 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 2 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] emu11 PD PD POWER [11] vout1_d12 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD PU/PD PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] B7 B8 A7 A8 F10 BALL NAME [2] vout1_d16 vout1_d17 vout1_d18 vout1_d19 vout1_d2 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O I vin4a_d0 3 I 0 vin3a_d0 4 I 0 gpio8_16 14 IO Driver off 15 I vout1_d17 0 O uart7_txd 2 O vin4a_d1 3 I 0 vin3a_d1 4 I 0 gpio8_17 14 IO Driver off 15 I vout1_d18 0 O emu4 2 O vin4a_d2 3 I 0 vin3a_d2 4 I 0 obs11 5 O obs27 6 O gpio8_18 14 IO Driver off 15 I vout1_d19 0 O emu15 2 O vin4a_d3 3 I 0 vin3a_d3 4 I 0 obs12 5 O obs28 6 O gpio8_19 14 IO Driver off 15 I vout1_d2 0 O emu2 2 O vin4a_d18 3 I 0 vin3a_d18 4 I 0 obs0 5 O obs16 6 O obs_irq1 7 O gpio8_2 14 IO Driver off 15 I PD PD PD PD PD PD 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 2 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] uart7_rxd PD 15 HYS [12] vout1_d16 PD PD POWER [11] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD 1 PU/PD PU/PD PU/PD PU/PD Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 73 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] C9 A9 B9 A10 74 BALL NAME [2] vout1_d20 vout1_d21 vout1_d22 vout1_d23 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] O vin4a_d4 3 I 0 vin3a_d4 4 I 0 obs13 5 O obs29 6 O gpio8_20 14 IO Driver off 15 I vout1_d21 0 O emu17 2 O vin4a_d5 3 I 0 vin3a_d5 4 I 0 obs14 5 O obs30 6 O gpio8_21 14 IO Driver off 15 I vout1_d22 0 O emu18 2 O vin4a_d6 3 I 0 vin3a_d6 4 I 0 obs15 5 O obs31 6 O gpio8_22 14 IO Driver off 15 I vout1_d23 0 O emu19 2 O vin4a_d7 3 I 0 vin3a_d7 4 I 0 spi3_cs3 8 IO 1 gpio8_23 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] O 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 2 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] emu16 PD PD POWER [11] vout1_d20 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD PU/PD PU/PD Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] G11 E9 F9 F8 BALL NAME [2] vout1_d3 vout1_d4 vout1_d5 vout1_d6 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] O O vin4a_d19 3 I 0 vin3a_d19 4 I 0 obs1 5 O obs17 6 O obs_dmarq1 7 O gpio8_3 14 IO Driver off 15 I vout1_d4 0 O emu6 2 O vin4a_d20 3 I 0 vin3a_d20 4 I 0 obs2 5 O obs18 6 O gpio8_4 14 IO Driver off 15 I vout1_d5 0 O emu7 2 O vin4a_d21 3 I 0 vin3a_d21 4 I 0 obs3 5 O obs19 6 O gpio8_5 14 IO Driver off 15 I vout1_d6 0 O emu8 2 O vin4a_d22 3 I 0 vin3a_d22 4 I 0 obs4 5 O obs20 6 O gpio8_6 14 IO Driver off 15 I PD PD PD PD 15 15 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] 2 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 0 15 1.8/3.3 BUFFER TYPE [13] emu5 PD 15 HYS [12] vout1_d3 PD PD POWER [11] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD PU/PD PU/PD Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 75 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] E7 E8 D9 B10 B11 C11 76 BALL NAME [2] vout1_d7 vout1_d8 vout1_d9 vout1_de vout1_fld vout1_hsync SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] O vin4a_d23 3 I 0 vin3a_d23 4 I 0 gpio8_7 14 IO Driver off 15 I vout1_d8 0 O uart6_rxd 2 I vin4a_d8 3 I 0 vin3a_d8 4 I 0 gpio8_8 14 IO Driver off 15 I vout1_d9 0 O uart6_txd 2 O vin4a_d9 3 I 0 vin3a_d9 4 I 0 gpio8_9 14 IO Driver off 15 I vout1_de 0 O vin4a_de0 3 I vin3a_de0 4 I 0 spi3_d1 8 IO 0 gpio4_20 14 IO Driver off 15 I vout1_fld 0 O vin4a_clk0 3 I vin3a_clk0 4 I 0 spi3_cs1 8 IO 1 gpio4_21 14 IO Driver off 15 I vout1_hsync 0 O vin4a_hsync0 3 I vin3a_hsync0 4 I 0 spi3_d0 8 IO 0 gpio4_22 14 IO Driver off 15 I PD PD PD PD PD PD PD PD 15 15 15 15 1.8/3.3 1.8/3.3 1.8/3.3 1.8/3.3 vddshv2 vddshv2 vddshv2 vddshv2 vddshv2 Yes Yes Yes Yes Yes Yes Dual Voltage LVCMOS DSIS [15] O 1.8/3.3 vddshv2 PULL UP/DOWN TYPE [14] 2 15 1.8/3.3 BUFFER TYPE [13] 0 PD 15 HYS [12] emu9 PD PD POWER [11] vout1_d7 Terminal Configuration and Functions PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS Dual Voltage LVCMOS PU/PD PU/PD 1 PU/PD PU/PD 0 PU/PD 0 PU/PD 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] E11 BALL NAME [2] vout1_vsync SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] vin3a_vsync0 4 I 0 spi3_sclk 8 IO 0 gpio4_23 14 IO Driver off 15 I vssa_hdmi GND vssa_osc0 vssa_osc0 GND AC14 vssa_osc1 vssa_osc1 GND AD13, AE13 vssa_pcie vssa_pcie GND AE10 vssa_sata vssa_sata GND AA11, AB11 vssa_usb vssa_usb GND AD10 vssa_usb3 vssa_usb3 GND U14 vssa_video vssa_video AD17 Wakeup0 Wakeup0 0 I dcan1_rx 1 I gpio1_0 14 I Driver off 15 I Wakeup1 0 I dcan2_rx 1 I gpio1_1 14 I Driver off 15 I Wakeup1 Yes Dual Voltage LVCMOS DSIS [15] I vssa_hdmi vddshv2 PULL UP/DOWN TYPE [14] O AF15 1.8/3.3 BUFFER TYPE [13] 3 AD19, AE19 15 HYS [12] 0 GND PD POWER [11] vin4a_vsync0 vss PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] vout1_vsync A1, A14, A2, A23, vss A28, A6, AA10, AA14, AA15, AA20, AA8, AA9, AB14, AB20, AD1, AD24, AG1, AH1, AH2, AH20, AH28, AH8, B1, D13, D19, E13, E19, F1, F7, G7, G8, G9, H12, J12, J15, J28, K1, K15, K24, K25, K4, K5, L13, L14, M19, N14, N15, N19, N24, N25, P28, R1, R12, R13, R15, R21, T10, T11, T12, T14, T15, T17, T18, T21, U15, U17, U20, U21, V15, V17, W1, W15, W24, W25, W28 AC17 BALL RESET STATE [7] PU/PD 0 GND OFF OFF 15 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD 1 OFF OFF 15 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD 1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 77 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] AB16 AC16 BALL NAME [2] Wakeup2 Wakeup3 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] Wakeup2 0 I sys_nirq2 1 I gpio1_2 14 I Driver off 15 I Wakeup3 0 I sys_nirq1 1 I gpio1_3 14 I Driver off 15 I BALL RESET STATE [7] BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] POWER [11] HYS [12] BUFFER TYPE [13] PULL UP/DOWN TYPE [14] OFF OFF 15 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD OFF OFF 15 1.8/3.3 vddshv5 Yes IHHV1833 PU/PD DSIS [15] AE15 xi_osc0 xi_osc0 0 I 1.8 vdda_osc No LVCMOS Analog NA AC15 xi_osc1 xi_osc1 0 I 1.8 vdda_osc No LVCMOS Analog NA AD15 xo_osc0 xo_osc0 0 O 1.8 vdda_osc No LVCMOS Analog NA AC13 xo_osc1 xo_osc1 0 A 1.8 vdda_osc No LVCMOS Analog NA D18 xref_clk0 xref_clk0 0 I 1.8/3.3 vddshv3 Yes 1 IO Dual Voltage LVCMOS PU/PD mcasp2_axr8 mcasp1_axr4 2 IO mcasp1_ahclkx 3 O mcasp5_ahclkx 4 O atl_clk0 5 O 7 I 0 hdq0 8 IO 1 clkout2 9 O timer13 10 IO gpio6_17 14 IO Driver off 15 I xref_clk1 0 I mcasp2_axr9 1 IO mcasp1_axr5 2 IO mcasp2_ahclkx 3 O mcasp6_ahclkx 4 O atl_clk1 5 O 7 I timer14 10 IO gpio6_18 14 IO Driver off 15 I vin6a_d0 E17 xref_clk1 vin6a_clk0 78 Terminal Configuration and Functions No No PD PD 15 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 0 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-2. Ball Characteristics(1) (continued) BALL NUMBER [1] B26 C23 BALL NAME [2] xref_clk2 xref_clk3 SIGNAL NAME [3] 74x [4] MUXMODE [5] TYPE [6] BALL RESET STATE [7] PD BALL BALL RESET I/O RESET REL. VOLTAGE REL. MUXMODE VALUE [10] STATE [8] [9] PD 15 1.8/3.3 POWER [11] vddshv3 BUFFER TYPE [13] HYS [12] Yes Dual Voltage LVCMOS PULL UP/DOWN TYPE [14] DSIS [15] xref_clk2 0 I mcasp2_axr10 1 IO PU/PD mcasp1_axr6 2 IO mcasp3_ahclkx 3 O mcasp7_ahclkx 4 O atl_clk2 5 O vout2_clk 6 O vin4a_clk0 8 I timer15 10 IO gpio6_19 14 IO Driver off 15 I xref_clk3 0 I mcasp2_axr11 1 IO mcasp1_axr7 2 IO mcasp4_ahclkx 3 O mcasp8_ahclkx 4 O atl_clk3 5 O vout2_de 6 O hdq0 7 IO 1 vin4a_de0 8 I 0 clkout3 9 O timer16 10 IO gpio6_20 14 IO Driver off 15 I 0 0 0 PD PD 15 1.8/3.3 vddshv3 Yes Dual Voltage LVCMOS PU/PD 0 0 (1) NA in this table stands for Not Applicable. (2) For more information on recommended operating conditions, see Table 5-4, Recommended Operating Conditions. (3) The pullup or pulldown block strength is equal to: minimum = 50 μA, typical = 100 μA, maximum = 250 μA. (4) The output impedance settings of this IO cell are programmable; by default, the value is DS[1:0] = 10, this means 40 Ω. For more information on DS[1:0] register configuration, see the Device TRM. (5) IO drive strength for usb1_dp, usb1_dm, usb2_dp and usb2_dm: minimum 18.3 mA, maximum 89 mA (for a power supply vdda33v_usb1 and vdda33v_usb2 = 3.46 V). (6) Minimum PU = 900 Ω, maximum PU = 3.090 kΩ and minimum PD = 14.25 kΩ, maximum PD = 24.8 kΩ. For more information, see chapter 7 of the USB2.0 specification, in particular section Signaling / Device Speed Identification. (7) This function will not be supported on some pin-compatibleroadmap devices. Pin compatibility can be maintained in the future by not using these GPIO signals. (8) In PUx / PDy, x and y = 60 to 200 μA. The output impedance settings (or drive strengths) of this IO are programmable (34 Ω, 40 Ω, 48 Ω, 60 Ω, 80 Ω) depending on the values of the I[2:0] registers. (9) The VOUT3 interface when multiplexed onto balls mapped to the VDDSHV6 supply rail is restricted to operating in 1.8V mode only (i.e., VDDSHV6 must be supplied with 1.8V). 3.3V mode is not supported. This must be considered in the pin mux programming and VDDSHVx supply connections. Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 79 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 4.3 www.ti.com Multiplexing Characteristics Table 4-3 describes the device multiplexing (no characteristics are available in this table). NOTE This table doesn't take into account subsystem multiplexing signals. Subsystem multiplexing signals are described in Section 4.4, Signal Descriptions. NOTE For more information, see the Control Module / Control Module Functional Description / PAD Functional Multiplexing and Configuration section of the Device TRM. NOTE Configuring two pins to the same input signal is not supported as it can yield unexpected results. This can be easily prevented with the proper software configuration. (Hi-Z mode is not an input signal.) NOTE When a pad is set into a multiplexing mode which is not defined by pin multiplexing, that pad’s behavior is undefined. This should be avoided. CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are valid only if signals within a single IOSET are used. The IOSETs are defined in the corresponding tables. Table 4-3. Multiplexing Characteristics ADDRESS 80 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 P25 ddr2_a6 Y23 ddr1_d26 Y19 ddr1_d21 AE15 xi_osc0 AH24 ddr1_nck Terminal Configuration and Functions 1 2 3 4 5 6 7 8 9 10 14 15 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 AG15 ljcb_clkp AF24 ddr1_d4 U25 ddr2_wen F27 ddr2_d5 V25 ddr1_ecc_d6 M27 ddr2_dqsn3 G26 ddr2_d12 AG19 hdmi1_data2x AF21 ddr1_a4 E27 ddr2_d6 F24 ddr2_d3 H26 ddr2_d11 W23 ddr1_ecc_d3 Y27 ddr1_dqsn3 AC24 ddr1_d14 J24 ddr2_d15 R26 ddr2_a1 G27 ddr2_dqsn0 AF28 ddr1_d11 AA23 ddr1_d24 AD18 ddr1_a15 H23 ddr2_d8 AH16 hdmi1_clocky AC20 ddr1_a2 AA24 ddr1_d27 W19 ddr1_ecc_d2 L24 ddr2_d20 AG11 pcie_rxn1 AG21 ddr1_rst AE28 ddr1_dqsn1 AC11 usb_txn0 L22 ddr2_d16 U28 ddr2_casn K22 ddr2_d22 AG25 ddr1_dqsn0 W20 ddr1_d17 AF14 rtc_iso AA27 ddr1_dqm3 AF25 ddr1_d0 1 2 3 4 5 6 7 8 9 10 14 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 15 81 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 82 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 AF23 ddr1_d6 AG18 hdmi1_data1x AG10 sata1_txn0 AF20 ddr1_rasn V26 ddr1_dqm_ec c V20 ddr1_d16 G25 ddr2_d1 AH13 pcie_rxp0 AC18 ddr1_casn AG9 sata1_rxp0 AH23 ddr1_csn0 AE11 usb2_dp R25 ddr2_a0 Y24 ddr1_d28 AH15 ljcb_clkn AD20 ddr1_a0 AA25 ddr1_d30 L23 ddr2_d19 AA1 mlbp_dat_p AD14 rtc_osc_xo J25 ddr2_d13 AC25 ddr1_d13 AB23 ddr1_dqm1 U22 ddr2_a15 T22 ddr2_a13 AH19 hdmi1_data2y M26 ddr2_d31 AB27 ddr1_d22 AG14 pcie_txn0 Y28 ddr1_dqs3 J20 ddr2_d23 AB19 ddr1_a3 AH10 sata1_txp0 G28 ddr2_dqs0 AG24 ddr1_ck AE24 ddr1_d5 AC15 xi_osc1 AC21 ddr1_a12 Terminal Configuration and Functions 1 2 3 4 5 6 7 8 9 10 14 15 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 K28 ddr2_dqsn2 AB1 mlbp_clk_p AF12 usb_rxn0 L28 ddr2_d27 M24 ddr2_d29 AH9 sata1_rxn0 AC26 ddr1_dqm2 AA28 ddr1_d31 H28 ddr2_dqsn1 AD23 ddr1_dqm0 E26 1 2 3 4 5 6 7 8 9 10 14 15 ddr2_d0 AE27 ddr1_dqs1 AF27 ddr1_d9 V24 ddr1_ecc_d5 K23 ddr2_dqm2 K20 ddr2_d17 T28 ddr2_ck H24 ddr2_d10 AG27 ddr1_d10 R23 ddr2_odt0 U27 ddr2_ba1 AF22 ddr1_a8 AA2 mlbp_dat_n U23 ddr2_ba0 AH21 ddr1_wen AE21 ddr1_a7 AC12 usb1_dm AH12 pcie_txp1 Y20 ddr1_d23 AC27 ddr1_d20 AE23 ddr1_d7 T27 ddr2_nck AG22 ddr1_cke AD27 ddr1_dqs2 AH14 pcie_txp0 AH26 ddr1_d3 AD21 ddr1_a10 N28 ddr2_a12 Y25 ddr1_ecc_d4 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 83 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME 0 AE17 ddr1_a14 AH18 hdmi1_data1y AH22 ddr1_a5 J26 ddr2_d14 W22 ddr1_ecc_d0 V23 ddr1_ecc_d1 AE12 usb_rxp0 AE14 rtc_osc_xi_clki n32 AH11 pcie_rxp1 AB2 mlbp_clk_n AG23 84 MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 1 2 3 4 5 6 7 8 9 10 14 15 ddr1_a6 H27 ddr2_dqs1 AB18 ddr1_ba2 AG17 hdmi1_data0x AF26 ddr1_d1 H25 ddr2_d9 M25 ddr2_d30 AD11 usb_txp0 AC1 mlbp_sig_p L27 ddr2_d24 V27 ddr1_dqs_ecc AF17 ddr1_ba0 AE26 ddr1_d12 G24 ddr2_dqm1 K27 ddr2_dqs2 AC19 ddr1_a1 AG13 pcie_rxn0 L26 ddr2_d25 AB28 ddr1_d18 N23 ddr2_a10 M22 ddr2_dqm3 U26 ddr2_ba2 Y26 ddr1_ecc_d7 P24 ddr2_csn0 R22 ddr2_a14 AD22 ddr1_a11 N20 ddr2_a7 M23 ddr2_d28 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER AD28 0 ddr2_cke P22 ddr2_a5 AE18 ddr1_ba1 F26 ddr2_d4 AE20 ddr1_odt0 N22 ddr2_vref0 E28 ddr2_d7 F25 ddr2_d2 AF11 usb2_dm R24 ddr2_rst AD15 xo_osc0 R27 ddr2_a3 AE22 ddr1_a9 AC13 3 4 5 6 7 8 9 10 14 15 ddr1_vref0 xo_osc1 F28 ddr2_dqm0 J23 ddr2_d21 P26 ddr2_a11 M28 ddr2_dqs3 AC2 mlbp_sig_n AD12 usb1_dp Y22 ddr1_d25 T23 ddr2_rasn AH17 2 ddr1_dqsn2 U24 Y18 1 hdmi1_data0y N27 ddr2_a9 P23 ddr2_a4 AG26 ddr1_d2 AH25 ddr1_dqs0 AG12 pcie_txn1 AF18 ddr1_a13 K21 ddr2_d18 AC28 ddr1_d19 V28 ddr1_dqsn_ec c P27 ddr2_a8 AC23 ddr1_d8 F22 porz L25 ddr2_d26 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 85 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 86 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 AG16 hdmi1_clockx R28 ddr2_a2 AA26 ddr1_d29 AD25 ddr1_d15 1 2 3 4 5 6 7 8 9 10 14 15 0x1400 CTRL_CORE_PAD_ GPMC_AD0 M6 gpmc_ad0 vin3a_d0 vout3_d0 gpio1_6 sysboot0 0x1404 CTRL_CORE_PAD_ GPMC_AD1 M2 gpmc_ad1 vin3a_d1 vout3_d1 gpio1_7 sysboot1 0x1408 CTRL_CORE_PAD_ GPMC_AD2 L5 gpmc_ad2 vin3a_d2 vout3_d2 gpio1_8 sysboot2 0x140C CTRL_CORE_PAD_ GPMC_AD3 M1 gpmc_ad3 vin3a_d3 vout3_d3 gpio1_9 sysboot3 0x1410 CTRL_CORE_PAD_ GPMC_AD4 L6 gpmc_ad4 vin3a_d4 vout3_d4 gpio1_10 sysboot4 0x1414 CTRL_CORE_PAD_ GPMC_AD5 L4 gpmc_ad5 vin3a_d5 vout3_d5 gpio1_11 sysboot5 0x1418 CTRL_CORE_PAD_ GPMC_AD6 L3 gpmc_ad6 vin3a_d6 vout3_d6 gpio1_12 sysboot6 0x141C CTRL_CORE_PAD_ GPMC_AD7 L2 gpmc_ad7 vin3a_d7 vout3_d7 gpio1_13 sysboot7 0x1420 CTRL_CORE_PAD_ GPMC_AD8 L1 gpmc_ad8 vin3a_d8 vout3_d8 gpio7_18 sysboot8 0x1424 CTRL_CORE_PAD_ GPMC_AD9 K2 gpmc_ad9 vin3a_d9 vout3_d9 gpio7_19 sysboot9 0x1428 CTRL_CORE_PAD_ GPMC_AD10 J1 gpmc_ad10 vin3a_d10 vout3_d10 gpio7_28 sysboot10 0x142C CTRL_CORE_PAD_ GPMC_AD11 J2 gpmc_ad11 vin3a_d11 vout3_d11 gpio7_29 sysboot11 0x1430 CTRL_CORE_PAD_ GPMC_AD12 H1 gpmc_ad12 vin3a_d12 vout3_d12 gpio1_18 sysboot12 0x1434 CTRL_CORE_PAD_ GPMC_AD13 J3 gpmc_ad13 vin3a_d13 vout3_d13 gpio1_19 sysboot13 0x1438 CTRL_CORE_PAD_ GPMC_AD14 H2 gpmc_ad14 vin3a_d14 vout3_d14 gpio1_20 sysboot14 0x143C CTRL_CORE_PAD_ GPMC_AD15 H3 gpmc_ad15 vin3a_d15 vout3_d15 gpio1_21 sysboot15 0x1440 CTRL_CORE_PAD_ GPMC_A0 R6 gpmc_a0 vin3a_d16 vout3_d16 vin4a_d0 vin4b_d0 i2c4_scl uart5_rxd gpio7_3 Driver off 0x1444 CTRL_CORE_PAD_ GPMC_A1 T9 gpmc_a1 vin3a_d17 vout3_d17 vin4a_d1 vin4b_d1 i2c4_sda uart5_txd gpio7_4 Driver off 0x1448 CTRL_CORE_PAD_ GPMC_A2 T6 gpmc_a2 vin3a_d18 vout3_d18 vin4a_d2 vin4b_d2 uart7_rxd uart5_ctsn gpio7_5 Driver off 0x144C CTRL_CORE_PAD_ GPMC_A3 T7 gpmc_a3 qspi1_cs2 vin3a_d19 vout3_d19 vin4a_d3 vin4b_d3 uart7_txd uart5_rtsn gpio7_6 Driver off 0x1450 CTRL_CORE_PAD_ GPMC_A4 P6 gpmc_a4 qspi1_cs3 vin3a_d20 vout3_d20 vin4a_d4 vin4b_d4 i2c5_scl uart6_rxd gpio1_26 Driver off Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 1 2 3 4 5 6 7 8 9 10 14 15 0x1454 CTRL_CORE_PAD_ GPMC_A5 R9 gpmc_a5 vin3a_d21 vout3_d21 vin4a_d5 vin4b_d5 i2c5_sda uart6_txd gpio1_27 Driver off 0x1458 CTRL_CORE_PAD_ GPMC_A6 R5 gpmc_a6 vin3a_d22 vout3_d22 vin4a_d6 vin4b_d6 uart8_rxd uart6_ctsn gpio1_28 Driver off 0x145C CTRL_CORE_PAD_ GPMC_A7 P5 gpmc_a7 vin3a_d23 vout3_d23 vin4a_d7 vin4b_d7 uart8_txd uart6_rtsn gpio1_29 Driver off 0x1460 CTRL_CORE_PAD_ GPMC_A8 N7 gpmc_a8 vin3a_hsync0 vout3_hsync vin4b_hsync1 timer12 spi4_sclk gpio1_30 Driver off 0x1464 CTRL_CORE_PAD_ GPMC_A9 R4 gpmc_a9 vin3a_vsync0 vout3_vsync vin4b_vsync1 timer11 spi4_d1 gpio1_31 Driver off 0x1468 CTRL_CORE_PAD_ GPMC_A10 N9 gpmc_a10 vin3a_de0 vout3_de vin4b_clk1 timer10 spi4_d0 gpio2_0 Driver off 0x146C CTRL_CORE_PAD_ GPMC_A11 P9 gpmc_a11 vin3a_fld0 vout3_fld vin4b_de1 timer9 spi4_cs0 gpio2_1 Driver off 0x1470 CTRL_CORE_PAD_ GPMC_A12 P4 gpmc_a12 vin4b_fld1 timer8 spi4_cs1 dma_evt1 gpio2_2 Driver off 0x1474 CTRL_CORE_PAD_ GPMC_A13 R3 gpmc_a13 qspi1_rtclk vin4a_hsync0 timer7 spi4_cs2 dma_evt2 gpio2_3 Driver off 0x1478 CTRL_CORE_PAD_ GPMC_A14 T2 gpmc_a14 qspi1_d3 vin4a_vsync0 timer6 spi4_cs3 gpio2_4 Driver off 0x147C CTRL_CORE_PAD_ GPMC_A15 U2 gpmc_a15 qspi1_d2 vin4a_d8 timer5 gpio2_5 Driver off 0x1480 CTRL_CORE_PAD_ GPMC_A16 U1 gpmc_a16 qspi1_d0 vin4a_d9 gpio2_6 Driver off 0x1484 CTRL_CORE_PAD_ GPMC_A17 P3 gpmc_a17 qspi1_d1 vin4a_d10 gpio2_7 Driver off 0x1488 CTRL_CORE_PAD_ GPMC_A18 R2 gpmc_a18 qspi1_sclk vin4a_d11 gpio2_8 Driver off 0x148C CTRL_CORE_PAD_ GPMC_A19 K7 gpmc_a19 mmc2_dat4 gpmc_a13 vin4a_d12 vin3b_d0 gpio2_9 Driver off 0x1490 CTRL_CORE_PAD_ GPMC_A20 M7 gpmc_a20 mmc2_dat5 gpmc_a14 vin4a_d13 vin3b_d1 gpio2_10 Driver off 0x1494 CTRL_CORE_PAD_ GPMC_A21 J5 gpmc_a21 mmc2_dat6 gpmc_a15 vin4a_d14 vin3b_d2 gpio2_11 Driver off 0x1498 CTRL_CORE_PAD_ GPMC_A22 K6 gpmc_a22 mmc2_dat7 gpmc_a16 vin4a_d15 vin3b_d3 gpio2_12 Driver off 0x149C CTRL_CORE_PAD_ GPMC_A23 J7 gpmc_a23 mmc2_clk gpmc_a17 vin4a_fld0 vin3b_d4 gpio2_13 Driver off 0x14A0 CTRL_CORE_PAD_ GPMC_A24 J4 gpmc_a24 mmc2_dat0 gpmc_a18 vin4a_d8 vin3b_d5 gpio2_14 Driver off 0x14A4 CTRL_CORE_PAD_ GPMC_A25 J6 gpmc_a25 mmc2_dat1 gpmc_a19 vin4a_d9 vin3b_d6 gpio2_15 Driver off 0x14A8 CTRL_CORE_PAD_ GPMC_A26 H4 gpmc_a26 mmc2_dat2 gpmc_a20 vin4a_d10 vin3b_d7 gpio2_16 Driver off 0x14AC CTRL_CORE_PAD_ GPMC_A27 H5 gpmc_a27 mmc2_dat3 gpmc_a21 vin4a_d11 vin3b_hsync1 gpio2_17 Driver off 0x14B0 CTRL_CORE_PAD_ GPMC_CS1 H6 gpmc_cs1 mmc2_cmd gpmc_a22 vin4a_de0 vin3b_vsync1 gpio2_18 Driver off vin4a_fld0 vin4a_clk0 gpmc_a0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 87 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 88 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 1 2 3 4 5 6 7 8 0x14B4 CTRL_CORE_PAD_ GPMC_CS0 T1 gpmc_cs0 0x14B8 CTRL_CORE_PAD_ GPMC_CS2 P2 gpmc_cs2 qspi1_cs0 0x14BC CTRL_CORE_PAD_ GPMC_CS3 P1 gpmc_cs3 qspi1_cs1 vin3a_clk0 vout3_clk 0x14C0 CTRL_CORE_PAD_ GPMC_CLK P7 gpmc_clk gpmc_cs7 clkout1 gpmc_wait1 vin4a_hsync0 vin4a_de0 vin3b_clk1 timer4 i2c3_scl 0x14C4 CTRL_CORE_PAD_ GPMC_ADVN_ALE N1 gpmc_advn_al gpmc_cs6 e clkout2 gpmc_wait1 vin4a_vsync0 gpmc_a2 gpmc_a23 timer3 i2c3_sda 0x14C8 CTRL_CORE_PAD_ GPMC_OEN_REN M5 0x14CC CTRL_CORE_PAD_ GPMC_WEN 0x14D0 9 10 14 15 gpio2_19 Driver off gpio2_20 Driver off gpio2_21 Driver off dma_evt1 gpio2_22 Driver off dma_evt2 gpio2_23 Driver off gpmc_oen_re n gpio2_24 Driver off M3 gpmc_wen gpio2_25 Driver off CTRL_CORE_PAD_ GPMC_BEN0 N6 gpmc_ben0 gpmc_cs4 vin1b_hsync1 0x14D4 CTRL_CORE_PAD_ GPMC_BEN1 M4 gpmc_ben1 gpmc_cs5 vin1b_de1 0x14D8 CTRL_CORE_PAD_ GPMC_WAIT0 N2 gpmc_wait0 0x14DC CTRL_CORE_PAD_V IN1A_CLK0 AG8 vin1a_clk0 0x14E0 CTRL_CORE_PAD_V IN1B_CLK1 AH7 vin1b_clk1 0x14E4 CTRL_CORE_PAD_V IN1A_DE0 AD9 vin1a_de0 vin1b_hsync1 0x14E8 CTRL_CORE_PAD_V IN1A_FLD0 AF9 vin1a_fld0 vin1b_vsync1 0x14EC CTRL_CORE_PAD_V IN1A_HSYNC0 AE9 0x14F0 CTRL_CORE_PAD_V IN1A_VSYNC0 0x14F4 vout3_d16 gpmc_a1 vin3b_clk1 gpmc_a3 vin3b_de1 timer2 dma_evt3 gpio2_26 Driver off vin3b_fld1 timer1 dma_evt4 gpio2_27 Driver off gpio2_28 Driver off gpio2_30 Driver off gpio2_31 Driver off vout3_fld vin3a_clk0 vout3_de uart7_rxd timer16 spi3_sclk kbd_row0 eQEP1A_in gpio3_0 Driver off vout3_clk uart7_txd timer15 spi3_d1 kbd_row1 eQEP1B_in gpio3_1 Driver off vin1a_hsync0 vin1b_fld1 vout3_hsync uart7_ctsn timer14 spi3_d0 eQEP1_index gpio3_2 Driver off AF8 vin1a_vsync0 vin1b_de1 vout3_vsync uart7_rtsn timer13 spi3_cs0 eQEP1_strob gpio3_3 e Driver off CTRL_CORE_PAD_V IN1A_D0 AE8 vin1a_d0 vout3_d7 vout3_d23 uart8_rxd ehrpwm1A gpio3_4 Driver off 0x14F8 CTRL_CORE_PAD_V IN1A_D1 AD8 vin1a_d1 vout3_d6 vout3_d22 uart8_txd ehrpwm1B gpio3_5 Driver off 0x14FC CTRL_CORE_PAD_V IN1A_D2 AG7 vin1a_d2 vout3_d5 vout3_d21 uart8_ctsn ehrpwm1_trip gpio3_6 zone_input Driver off 0x1500 CTRL_CORE_PAD_V IN1A_D3 AH6 vin1a_d3 vout3_d4 vout3_d20 uart8_rtsn eCAP1_in_P WM1_out gpio3_7 Driver off 0x1504 CTRL_CORE_PAD_V IN1A_D4 AH3 vin1a_d4 vout3_d3 vout3_d19 ehrpwm1_syn gpio3_8 ci Driver off 0x1508 CTRL_CORE_PAD_V IN1A_D5 AH5 vin1a_d5 vout3_d2 vout3_d18 ehrpwm1_syn gpio3_9 co Driver off 0x150C CTRL_CORE_PAD_V IN1A_D6 AG6 vin1a_d6 vout3_d1 vout3_d17 eQEP2A_in gpio3_10 Driver off 0x1510 CTRL_CORE_PAD_V IN1A_D7 AH4 vin1a_d7 vout3_d0 vout3_d16 eQEP2B_in gpio3_11 Driver off Terminal Configuration and Functions vout3_d17 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 1 2 3 4 5 6 7 8 9 10 14 15 0x1514 CTRL_CORE_PAD_V IN1A_D8 AG4 vin1a_d8 vin1b_d7 vout3_d15 kbd_row2 eQEP2_index gpio3_12 Driver off 0x1518 CTRL_CORE_PAD_V IN1A_D9 AG2 vin1a_d9 vin1b_d6 vout3_d14 kbd_row3 eQEP2_strob gpio3_13 e Driver off 0x151C CTRL_CORE_PAD_V IN1A_D10 AG3 vin1a_d10 vin1b_d5 vout3_d13 kbd_row4 gpio3_14 Driver off 0x1520 CTRL_CORE_PAD_V IN1A_D11 AG5 vin1a_d11 vin1b_d4 vout3_d12 gpmc_a23 kbd_row5 gpio3_15 Driver off 0x1524 CTRL_CORE_PAD_V IN1A_D12 AF2 vin1a_d12 vin1b_d3 usb3_ulpi_d7 vout3_d11 gpmc_a24 kbd_row6 gpio3_16 Driver off 0x1528 CTRL_CORE_PAD_V IN1A_D13 AF6 vin1a_d13 vin1b_d2 usb3_ulpi_d6 vout3_d10 gpmc_a25 kbd_row7 gpio3_17 Driver off 0x152C CTRL_CORE_PAD_V IN1A_D14 AF3 vin1a_d14 vin1b_d1 usb3_ulpi_d5 vout3_d9 gpmc_a26 kbd_row8 gpio3_18 Driver off 0x1530 CTRL_CORE_PAD_V IN1A_D15 AF4 vin1a_d15 vin1b_d0 usb3_ulpi_d4 vout3_d8 gpmc_a27 kbd_col0 gpio3_19 Driver off 0x1534 CTRL_CORE_PAD_V IN1A_D16 AF1 vin1a_d16 vin1b_d7 usb3_ulpi_d3 vout3_d7 vin3a_d0 kbd_col1 gpio3_20 Driver off 0x1538 CTRL_CORE_PAD_V IN1A_D17 AE3 vin1a_d17 vin1b_d6 usb3_ulpi_d2 vout3_d6 vin3a_d1 kbd_col2 gpio3_21 Driver off 0x153C CTRL_CORE_PAD_V IN1A_D18 AE5 vin1a_d18 vin1b_d5 usb3_ulpi_d1 vout3_d5 vin3a_d2 kbd_col3 gpio3_22 Driver off 0x1540 CTRL_CORE_PAD_V IN1A_D19 AE1 vin1a_d19 vin1b_d4 usb3_ulpi_d0 vout3_d4 vin3a_d3 kbd_col4 gpio3_23 Driver off 0x1544 CTRL_CORE_PAD_V IN1A_D20 AE2 vin1a_d20 vin1b_d3 usb3_ulpi_nxt vout3_d3 vin3a_d4 kbd_col5 gpio3_24 Driver off 0x1548 CTRL_CORE_PAD_V IN1A_D21 AE6 vin1a_d21 vin1b_d2 usb3_ulpi_dir vout3_d2 vin3a_d5 kbd_col6 gpio3_25 Driver off 0x154C CTRL_CORE_PAD_V IN1A_D22 AD2 vin1a_d22 vin1b_d1 usb3_ulpi_stp vout3_d1 vin3a_d6 kbd_col7 gpio3_26 Driver off 0x1550 CTRL_CORE_PAD_V IN1A_D23 AD3 vin1a_d23 vin1b_d0 usb3_ulpi_clk vout3_d0 vin3a_d7 kbd_col8 gpio3_27 Driver off 0x1554 CTRL_CORE_PAD_V IN2A_CLK0 E1 vin2a_clk0 0x1558 CTRL_CORE_PAD_V IN2A_DE0 G2 vin2a_de0 0x155C CTRL_CORE_PAD_V IN2A_FLD0 H7 vin2a_fld0 0x1560 CTRL_CORE_PAD_V IN2A_HSYNC0 G1 vin2a_hsync0 vin2b_hsync1 vout2_hsync emu8 uart9_rxd spi4_sclk 0x1564 CTRL_CORE_PAD_V IN2A_VSYNC0 G6 vin2a_vsync0 vin2b_vsync1 vout2_vsync emu9 uart9_txd 0x1568 CTRL_CORE_PAD_V IN2A_D0 F2 vin2a_d0 vout2_d23 emu10 0x156C CTRL_CORE_PAD_V IN2A_D1 F3 vin2a_d1 vout2_d22 emu11 0x1570 CTRL_CORE_PAD_V IN2A_D2 D1 vin2a_d2 vout2_d21 emu12 vin2a_fld0 vin2b_fld1 vin2b_clk1 vin2b_de1 vout2_fld emu5 kbd_row0 eQEP1A_in gpio3_28 Driver off vout2_de emu6 kbd_row1 eQEP1B_in gpio3_29 Driver off vout2_clk emu7 eQEP1_index gpio3_30 Driver off kbd_row2 eQEP1_strob gpio3_31 e Driver off spi4_d1 kbd_row3 ehrpwm1A gpio4_0 Driver off uart9_ctsn spi4_d0 kbd_row4 ehrpwm1B gpio4_1 Driver off uart9_rtsn spi4_cs0 kbd_row5 ehrpwm1_trip gpio4_2 zone_input Driver off uart10_rxd kbd_row6 eCAP1_in_P WM1_out Driver off gpio4_3 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 89 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 90 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 14 15 0x1574 CTRL_CORE_PAD_V IN2A_D3 E2 vin2a_d3 vout2_d20 emu13 uart10_txd kbd_col0 ehrpwm1_syn gpio4_4 ci Driver off 0x1578 CTRL_CORE_PAD_V IN2A_D4 D2 vin2a_d4 vout2_d19 emu14 uart10_ctsn kbd_col1 ehrpwm1_syn gpio4_5 co Driver off 0x157C CTRL_CORE_PAD_V IN2A_D5 F4 vin2a_d5 vout2_d18 emu15 uart10_rtsn kbd_col2 eQEP2A_in gpio4_6 Driver off 0x1580 CTRL_CORE_PAD_V IN2A_D6 C1 vin2a_d6 vout2_d17 emu16 mii1_rxd1 kbd_col3 eQEP2B_in gpio4_7 Driver off 0x1584 CTRL_CORE_PAD_V IN2A_D7 E4 vin2a_d7 vout2_d16 emu17 mii1_rxd2 kbd_col4 eQEP2_index gpio4_8 Driver off 0x1588 CTRL_CORE_PAD_V IN2A_D8 F5 vin2a_d8 vout2_d15 emu18 mii1_rxd3 kbd_col5 eQEP2_strob gpio4_9 e Driver off 0x158C CTRL_CORE_PAD_V IN2A_D9 E6 vin2a_d9 vout2_d14 emu19 mii1_rxd0 kbd_col6 ehrpwm2A gpio4_10 Driver off 0x1590 CTRL_CORE_PAD_V IN2A_D10 D3 vin2a_d10 mdio_mclk vout2_d13 kbd_col7 ehrpwm2B gpio4_11 Driver off 0x1594 CTRL_CORE_PAD_V IN2A_D11 F6 vin2a_d11 mdio_d vout2_d12 kbd_row7 ehrpwm2_trip gpio4_12 zone_input Driver off 0x1598 CTRL_CORE_PAD_V IN2A_D12 D5 vin2a_d12 rgmii1_txc vout2_d11 mii1_rxclk kbd_col8 eCAP2_in_P WM2_out gpio4_13 Driver off 0x159C CTRL_CORE_PAD_V IN2A_D13 C2 vin2a_d13 rgmii1_txctl vout2_d10 mii1_rxdv kbd_row8 eQEP3A_in gpio4_14 Driver off 0x15A0 CTRL_CORE_PAD_V IN2A_D14 C3 vin2a_d14 rgmii1_txd3 vout2_d9 mii1_txclk eQEP3B_in gpio4_15 Driver off 0x15A4 CTRL_CORE_PAD_V IN2A_D15 C4 vin2a_d15 rgmii1_txd2 vout2_d8 mii1_txd0 eQEP3_index gpio4_16 Driver off 0x15A8 CTRL_CORE_PAD_V IN2A_D16 B2 vin2a_d16 vin2b_d7 rgmii1_txd1 vout2_d7 vin3a_d8 mii1_txd1 eQEP3_strob gpio4_24 e Driver off 0x15AC CTRL_CORE_PAD_V IN2A_D17 D6 vin2a_d17 vin2b_d6 rgmii1_txd0 vout2_d6 vin3a_d9 mii1_txd2 ehrpwm3A gpio4_25 Driver off 0x15B0 CTRL_CORE_PAD_V IN2A_D18 C5 vin2a_d18 vin2b_d5 rgmii1_rxc vout2_d5 vin3a_d10 mii1_txd3 ehrpwm3B gpio4_26 Driver off 0x15B4 CTRL_CORE_PAD_V IN2A_D19 A3 vin2a_d19 vin2b_d4 rgmii1_rxctl vout2_d4 vin3a_d11 mii1_txer ehrpwm3_trip gpio4_27 zone_input Driver off 0x15B8 CTRL_CORE_PAD_V IN2A_D20 B3 vin2a_d20 vin2b_d3 rgmii1_rxd3 vout2_d3 vin3a_de0 vin3a_d12 mii1_rxer eCAP3_in_P WM3_out gpio4_28 Driver off 0x15BC CTRL_CORE_PAD_V IN2A_D21 B4 vin2a_d21 vin2b_d2 rgmii1_rxd2 vout2_d2 vin3a_fld0 vin3a_d13 mii1_col gpio4_29 Driver off 0x15C0 CTRL_CORE_PAD_V IN2A_D22 B5 vin2a_d22 vin2b_d1 rgmii1_rxd1 vout2_d1 vin3a_hsync0 vin3a_d14 mii1_crs gpio4_30 Driver off 0x15C4 CTRL_CORE_PAD_V IN2A_D23 A4 vin2a_d23 vin2b_d0 rgmii1_rxd0 vout2_d0 vin3a_vsync0 vin3a_d15 mii1_txen gpio4_31 Driver off 0x15C8 CTRL_CORE_PAD_V OUT1_CLK D11 vout1_clk vin4a_fld0 vin3a_fld0 spi3_cs0 gpio4_19 Driver off 0x15CC CTRL_CORE_PAD_V OUT1_DE B10 vout1_de vin4a_de0 vin3a_de0 spi3_d1 gpio4_20 Driver off 0x15D0 CTRL_CORE_PAD_V OUT1_FLD B11 vout1_fld vin4a_clk0 vin3a_clk0 spi3_cs1 gpio4_21 Driver off Terminal Configuration and Functions 1 2 3 4 5 6 7 8 9 10 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 1 2 3 4 5 6 7 8 9 10 14 15 0x15D4 CTRL_CORE_PAD_V OUT1_HSYNC C11 vout1_hsync vin4a_hsync0 vin3a_hsync0 spi3_d0 gpio4_22 Driver off 0x15D8 CTRL_CORE_PAD_V OUT1_VSYNC E11 vout1_vsync vin4a_vsync0 vin3a_vsync0 spi3_sclk gpio4_23 Driver off 0x15DC CTRL_CORE_PAD_V OUT1_D0 F11 vout1_d0 uart5_rxd vin4a_d16 vin3a_d16 spi3_cs2 gpio8_0 Driver off 0x15E0 CTRL_CORE_PAD_V OUT1_D1 G10 vout1_d1 uart5_txd vin4a_d17 vin3a_d17 gpio8_1 Driver off 0x15E4 CTRL_CORE_PAD_V OUT1_D2 F10 vout1_d2 emu2 vin4a_d18 vin3a_d18 obs0 obs16 obs_irq1 gpio8_2 Driver off 0x15E8 CTRL_CORE_PAD_V OUT1_D3 G11 vout1_d3 emu5 vin4a_d19 vin3a_d19 obs1 obs17 obs_dmarq1 gpio8_3 Driver off 0x15EC CTRL_CORE_PAD_V OUT1_D4 E9 vout1_d4 emu6 vin4a_d20 vin3a_d20 obs2 obs18 gpio8_4 Driver off 0x15F0 CTRL_CORE_PAD_V OUT1_D5 F9 vout1_d5 emu7 vin4a_d21 vin3a_d21 obs3 obs19 gpio8_5 Driver off 0x15F4 CTRL_CORE_PAD_V OUT1_D6 F8 vout1_d6 emu8 vin4a_d22 vin3a_d22 obs4 obs20 gpio8_6 Driver off 0x15F8 CTRL_CORE_PAD_V OUT1_D7 E7 vout1_d7 emu9 vin4a_d23 vin3a_d23 gpio8_7 Driver off 0x15FC CTRL_CORE_PAD_V OUT1_D8 E8 vout1_d8 uart6_rxd vin4a_d8 vin3a_d8 gpio8_8 Driver off 0x1600 CTRL_CORE_PAD_V OUT1_D9 D9 vout1_d9 uart6_txd vin4a_d9 vin3a_d9 gpio8_9 Driver off 0x1604 CTRL_CORE_PAD_V OUT1_D10 D7 vout1_d10 emu3 vin4a_d10 vin3a_d10 obs5 obs21 obs_irq2 gpio8_10 Driver off 0x1608 CTRL_CORE_PAD_V OUT1_D11 D8 vout1_d11 emu10 vin4a_d11 vin3a_d11 obs6 obs22 obs_dmarq2 gpio8_11 Driver off 0x160C CTRL_CORE_PAD_V OUT1_D12 A5 vout1_d12 emu11 vin4a_d12 vin3a_d12 obs7 obs23 gpio8_12 Driver off 0x1610 CTRL_CORE_PAD_V OUT1_D13 C6 vout1_d13 emu12 vin4a_d13 vin3a_d13 obs8 obs24 gpio8_13 Driver off 0x1614 CTRL_CORE_PAD_V OUT1_D14 C8 vout1_d14 emu13 vin4a_d14 vin3a_d14 obs9 obs25 gpio8_14 Driver off 0x1618 CTRL_CORE_PAD_V OUT1_D15 C7 vout1_d15 emu14 vin4a_d15 vin3a_d15 obs10 obs26 gpio8_15 Driver off 0x161C CTRL_CORE_PAD_V OUT1_D16 B7 vout1_d16 uart7_rxd vin4a_d0 vin3a_d0 gpio8_16 Driver off 0x1620 CTRL_CORE_PAD_V OUT1_D17 B8 vout1_d17 uart7_txd vin4a_d1 vin3a_d1 gpio8_17 Driver off 0x1624 CTRL_CORE_PAD_V OUT1_D18 A7 vout1_d18 emu4 vin4a_d2 vin3a_d2 obs11 obs27 gpio8_18 Driver off 0x1628 CTRL_CORE_PAD_V OUT1_D19 A8 vout1_d19 emu15 vin4a_d3 vin3a_d3 obs12 obs28 gpio8_19 Driver off 0x162C CTRL_CORE_PAD_V OUT1_D20 C9 vout1_d20 emu16 vin4a_d4 vin3a_d4 obs13 obs29 gpio8_20 Driver off 0x1630 CTRL_CORE_PAD_V OUT1_D21 A9 vout1_d21 emu17 vin4a_d5 vin3a_d5 obs14 obs30 gpio8_21 Driver off Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 91 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 92 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 1 2 3 4 5 7 CTRL_CORE_PAD_V OUT1_D22 B9 vout1_d22 emu18 vin4a_d6 vin3a_d6 0x1638 CTRL_CORE_PAD_V OUT1_D23 A10 vout1_d23 emu19 vin4a_d7 vin3a_d7 0x163C CTRL_CORE_PAD_ MDIO_MCLK V1 mdio_mclk uart3_rtsn mii0_col vin2a_clk0 0x1640 CTRL_CORE_PAD_ MDIO_D U4 mdio_d uart3_ctsn mii0_txer vin2a_d0 0x1644 CTRL_CORE_PAD_R MII_MHZ_50_CLK U3 RMII_MHZ_50 _CLK 0x1648 CTRL_CORE_PAD_U ART3_RXD V2 uart3_rxd rmii1_crs mii0_rxdv vin2a_d1 vin4b_d1 spi3_sclk 0x164C CTRL_CORE_PAD_U ART3_TXD Y1 uart3_txd rmii1_rxer mii0_rxclk vin2a_d2 vin4b_d2 spi3_d1 0x1650 CTRL_CORE_PAD_R GMII0_TXC W9 rgmii0_txc uart3_ctsn rmii1_rxd1 mii0_rxd3 vin2a_d3 vin4b_d3 0x1654 CTRL_CORE_PAD_R GMII0_TXCTL V9 rgmii0_txctl uart3_rtsn rmii1_rxd0 mii0_rxd2 vin2a_d4 0x1658 CTRL_CORE_PAD_R GMII0_TXD3 V7 rgmii0_txd3 rmii0_crs mii0_crs vin2a_de0 0x165C CTRL_CORE_PAD_R GMII0_TXD2 U7 rgmii0_txd2 rmii0_rxer mii0_rxer 0x1660 CTRL_CORE_PAD_R GMII0_TXD1 V6 rgmii0_txd1 rmii0_rxd1 0x1664 CTRL_CORE_PAD_R GMII0_TXD0 U6 rgmii0_txd0 rmii0_rxd0 0x1668 CTRL_CORE_PAD_R GMII0_RXC U5 rgmii0_rxc 0x166C CTRL_CORE_PAD_R GMII0_RXCTL V5 0x1670 CTRL_CORE_PAD_R GMII0_RXD3 0x1674 8 9 10 obs31 14 15 gpio8_22 Driver off gpio8_23 Driver off vin4b_clk1 gpio5_15 Driver off vin4b_d0 gpio5_16 Driver off gpio5_17 Driver off gpio5_18 Driver off spi4_cs1 gpio5_19 Driver off usb4_ulpi_clk spi3_d0 spi4_cs2 gpio5_20 Driver off vin4b_d4 usb4_ulpi_stp spi3_cs0 spi4_cs3 gpio5_21 Driver off vin4b_de1 usb4_ulpi_dir spi4_sclk uart4_rxd gpio5_22 Driver off vin2a_hsync0 vin4b_hsync1 usb4_ulpi_nxt spi4_d1 uart4_txd gpio5_23 Driver off mii0_rxd1 vin2a_vsync0 vin4b_vsync1 usb4_ulpi_d0 spi4_d0 uart4_ctsn gpio5_24 Driver off mii0_rxd0 vin2a_d10 uart4_rtsn gpio5_25 Driver off rmii1_txen mii0_txclk vin2a_d5 vin4b_d5 usb4_ulpi_d2 gpio5_26 Driver off rgmii0_rxctl rmii1_txd1 mii0_txd3 vin2a_d6 vin4b_d6 usb4_ulpi_d3 gpio5_27 Driver off V4 rgmii0_rxd3 rmii1_txd0 mii0_txd2 vin2a_d7 vin4b_d7 usb4_ulpi_d4 gpio5_28 Driver off CTRL_CORE_PAD_R GMII0_RXD2 V3 rgmii0_rxd2 rmii0_txen mii0_txen vin2a_d8 usb4_ulpi_d5 gpio5_29 Driver off 0x1678 CTRL_CORE_PAD_R GMII0_RXD1 Y2 rgmii0_rxd1 rmii0_txd1 mii0_txd1 vin2a_d9 usb4_ulpi_d6 gpio5_30 Driver off 0x167C CTRL_CORE_PAD_R GMII0_RXD0 W2 rgmii0_rxd0 rmii0_txd0 mii0_txd0 vin2a_fld0 usb4_ulpi_d7 gpio5_31 Driver off 0x1680 CTRL_CORE_PAD_U SB1_DRVVBUS AB10 usb1_drvvbus timer16 gpio6_12 Driver off 0x1684 CTRL_CORE_PAD_U SB2_DRVVBUS AC10 usb2_drvvbus timer15 gpio6_13 Driver off 0x1688 CTRL_CORE_PAD_ GPIO6_14 E21 gpio6_14 mcasp1_axr8 dcan2_tx uart10_rxd vout2_hsync vin4a_hsync0 i2c3_sda timer1 gpio6_14 Driver off 0x168C CTRL_CORE_PAD_ GPIO6_15 F20 gpio6_15 mcasp1_axr9 dcan2_rx uart10_txd vout2_vsync vin4a_vsync0 i2c3_scl timer2 gpio6_15 Driver off 0x1690 CTRL_CORE_PAD_ GPIO6_16 F21 gpio6_16 mcasp1_axr1 0 vout2_fld vin4a_fld0 timer3 gpio6_16 Driver off Terminal Configuration and Functions obs15 6 0x1634 spi3_cs3 vin2a_d11 usb4_ulpi_d1 spi4_cs0 vin4b_fld1 clkout1 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 1 2 3 4 5 6 7 0x1694 CTRL_CORE_PAD_X REF_CLK0 D18 xref_clk0 mcasp2_axr8 mcasp1_axr4 mcasp1_ahclk mcasp5_ahclk atl_clk0 x x vin6a_d0 0x1698 CTRL_CORE_PAD_X REF_CLK1 E17 xref_clk1 mcasp2_axr9 mcasp1_axr5 mcasp2_ahclk mcasp6_ahclk atl_clk1 x x vin6a_clk0 0x169C CTRL_CORE_PAD_X REF_CLK2 B26 xref_clk2 mcasp2_axr1 mcasp1_axr6 mcasp3_ahclk mcasp7_ahclk atl_clk2 0 x x vout2_clk 0x16A0 CTRL_CORE_PAD_X REF_CLK3 C23 xref_clk3 mcasp2_axr1 mcasp1_axr7 mcasp4_ahclk mcasp8_ahclk atl_clk3 1 x x vout2_de 0x16A4 CTRL_CORE_PAD_ MCASP1_ACLKX C14 mcasp1_aclkx 0x16A8 CTRL_CORE_PAD_ MCASP1_FSX D14 mcasp1_fsx 0x16AC CTRL_CORE_PAD_ MCASP1_ACLKR B14 mcasp1_aclkr mcasp7_axr2 vout2_d0 0x16B0 CTRL_CORE_PAD_ MCASP1_FSR J14 mcasp1_fsr vout2_d1 0x16B4 CTRL_CORE_PAD_ MCASP1_AXR0 G12 mcasp1_axr0 uart6_rxd 0x16B8 CTRL_CORE_PAD_ MCASP1_AXR1 F12 mcasp1_axr1 uart6_txd 0x16BC CTRL_CORE_PAD_ MCASP1_AXR2 G13 mcasp1_axr2 mcasp6_axr2 uart6_ctsn vout2_d2 0x16C0 CTRL_CORE_PAD_ MCASP1_AXR3 J11 mcasp1_axr3 mcasp6_axr3 uart6_rtsn 0x16C4 CTRL_CORE_PAD_ MCASP1_AXR4 E12 0x16C8 CTRL_CORE_PAD_ MCASP1_AXR5 0x16CC 8 9 14 15 gpio6_17 Driver off timer14 gpio6_18 Driver off timer15 gpio6_19 Driver off timer16 gpio6_20 Driver off vin6a_fld0 i2c3_sda gpio7_31 Driver off vin6a_de0 i2c3_scl gpio7_30 Driver off vin4a_d0 i2c4_sda gpio5_0 Driver off vin4a_d1 i2c4_scl gpio5_1 Driver off vin6a_vsync0 i2c5_sda gpio5_2 Driver off vin6a_hsync0 i2c5_scl gpio5_3 Driver off vin4a_d2 gpio5_4 Driver off vout2_d3 vin4a_d3 gpio5_5 Driver off mcasp1_axr4 mcasp4_axr2 vout2_d4 vin4a_d4 gpio5_6 Driver off F13 mcasp1_axr5 mcasp4_axr3 vout2_d5 vin4a_d5 gpio5_7 Driver off CTRL_CORE_PAD_ MCASP1_AXR6 C12 mcasp1_axr6 mcasp5_axr2 vout2_d6 vin4a_d6 gpio5_8 Driver off 0x16D0 CTRL_CORE_PAD_ MCASP1_AXR7 D12 mcasp1_axr7 mcasp5_axr3 vout2_d7 vin4a_d7 timer4 gpio5_9 Driver off 0x16D4 CTRL_CORE_PAD_ MCASP1_AXR8 B12 mcasp1_axr8 mcasp6_axr0 spi3_sclk vin6a_d15 timer5 gpio5_10 Driver off 0x16D8 CTRL_CORE_PAD_ MCASP1_AXR9 A11 mcasp1_axr9 mcasp6_axr1 spi3_d1 vin6a_d14 timer6 gpio5_11 Driver off 0x16DC CTRL_CORE_PAD_ MCASP1_AXR10 B13 mcasp1_axr1 mcasp6_aclkx mcasp6_aclkr spi3_d0 0 vin6a_d13 timer7 gpio5_12 Driver off 0x16E0 CTRL_CORE_PAD_ MCASP1_AXR11 A12 mcasp1_axr1 mcasp6_fsx 1 spi3_cs0 vin6a_d12 timer8 gpio4_17 Driver off 0x16E4 CTRL_CORE_PAD_ MCASP1_AXR12 E14 mcasp1_axr1 mcasp7_axr0 2 spi3_cs1 vin6a_d11 timer9 gpio4_18 Driver off 0x16E8 CTRL_CORE_PAD_ MCASP1_AXR13 A13 mcasp1_axr1 mcasp7_axr1 3 vin6a_d10 timer10 gpio6_4 Driver off 0x16EC CTRL_CORE_PAD_ MCASP1_AXR14 G14 mcasp1_axr1 mcasp7_aclkx mcasp7_aclkr 4 vin6a_d9 timer11 gpio6_5 Driver off 0x16F0 CTRL_CORE_PAD_ MCASP1_AXR15 F14 mcasp1_axr1 mcasp7_fsx 5 vin6a_d8 timer12 gpio6_6 Driver off mcasp6_fsr mcasp7_fsr clkout2 10 timer13 mcasp7_axr3 hdq0 vin4a_clk0 hdq0 vin4a_de0 clkout3 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 93 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 94 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 1 2 3 4 5 6 7 8 9 10 14 15 0x16F4 CTRL_CORE_PAD_ MCASP2_ACLKX A19 mcasp2_aclkx vin6a_d7 Driver off 0x16F8 CTRL_CORE_PAD_ MCASP2_FSX A18 mcasp2_fsx vin6a_d6 Driver off 0x16FC CTRL_CORE_PAD_ MCASP2_ACLKR E15 mcasp2_aclkr mcasp8_axr2 vout2_d8 vin4a_d8 Driver off 0x1700 CTRL_CORE_PAD_ MCASP2_FSR A20 mcasp2_fsr vout2_d9 vin4a_d9 Driver off 0x1704 CTRL_CORE_PAD_ MCASP2_AXR0 B15 mcasp2_axr0 vout2_d10 vin4a_d10 Driver off 0x1708 CTRL_CORE_PAD_ MCASP2_AXR1 A15 mcasp2_axr1 vout2_d11 vin4a_d11 Driver off 0x170C CTRL_CORE_PAD_ MCASP2_AXR2 C15 mcasp2_axr2 mcasp3_axr2 vin6a_d5 gpio6_8 Driver off 0x1710 CTRL_CORE_PAD_ MCASP2_AXR3 A16 mcasp2_axr3 mcasp3_axr3 vin6a_d4 gpio6_9 Driver off 0x1714 CTRL_CORE_PAD_ MCASP2_AXR4 D15 mcasp2_axr4 mcasp8_axr0 vout2_d12 vin4a_d12 gpio1_4 Driver off 0x1718 CTRL_CORE_PAD_ MCASP2_AXR5 B16 mcasp2_axr5 mcasp8_axr1 vout2_d13 vin4a_d13 gpio6_7 Driver off 0x171C CTRL_CORE_PAD_ MCASP2_AXR6 B17 mcasp2_axr6 mcasp8_aclkx mcasp8_aclkr vout2_d14 vin4a_d14 gpio2_29 Driver off 0x1720 CTRL_CORE_PAD_ MCASP2_AXR7 A17 mcasp2_axr7 mcasp8_fsx vout2_d15 vin4a_d15 gpio1_5 Driver off 0x1724 CTRL_CORE_PAD_ MCASP3_ACLKX B18 mcasp3_aclkx mcasp3_aclkr mcasp2_axr1 uart7_rxd 2 vin6a_d3 gpio5_13 Driver off 0x1728 CTRL_CORE_PAD_ MCASP3_FSX F15 mcasp3_fsx vin6a_d2 gpio5_14 Driver off 0x172C CTRL_CORE_PAD_ MCASP3_AXR0 B19 mcasp3_axr0 mcasp2_axr1 uart7_ctsn 4 uart5_rxd vin6a_d1 0x1730 CTRL_CORE_PAD_ MCASP3_AXR1 C17 mcasp3_axr1 mcasp2_axr1 uart7_rtsn 5 uart5_txd vin6a_d0 0x1734 CTRL_CORE_PAD_ MCASP4_ACLKX C18 mcasp4_aclkx mcasp4_aclkr spi3_sclk uart8_rxd i2c4_sda vout2_d16 0x1738 CTRL_CORE_PAD_ MCASP4_FSX A21 mcasp4_fsx spi3_d1 uart8_txd i2c4_scl 0x173C CTRL_CORE_PAD_ MCASP4_AXR0 G16 mcasp4_axr0 spi3_d0 uart8_ctsn 0x1740 CTRL_CORE_PAD_ MCASP4_AXR1 D17 mcasp4_axr1 spi3_cs0 0x1744 CTRL_CORE_PAD_ MCASP5_ACLKX AA3 0x1748 CTRL_CORE_PAD_ MCASP5_FSX 0x174C 0x1750 mcasp8_axr3 mcasp3_fsr mcasp8_fsr mcasp2_axr1 uart7_txd 3 Driver off vin5a_fld0 Driver off vin4a_d16 vin5a_d15 Driver off vout2_d17 vin4a_d17 vin5a_d14 Driver off uart4_rxd vout2_d18 vin4a_d18 vin5a_d13 Driver off uart8_rtsn uart4_txd vout2_d19 vin4a_d19 vin5a_d12 Driver off mcasp5_aclkx mcasp5_aclkr spi4_sclk uart9_rxd i2c5_sda vout2_d20 vin4a_d20 vin5a_d11 Driver off AB9 mcasp5_fsx spi4_d1 uart9_txd i2c5_scl vout2_d21 vin4a_d21 vin5a_d10 Driver off CTRL_CORE_PAD_ MCASP5_AXR0 AB3 mcasp5_axr0 spi4_d0 uart9_ctsn uart3_rxd mlb_sig vout2_d22 vin4a_d22 vin5a_d9 Driver off CTRL_CORE_PAD_ MCASP5_AXR1 AA4 mcasp5_axr1 spi4_cs0 uart9_rtsn uart3_txd mlb_dat vout2_d23 vin4a_d23 vin5a_d8 Driver off Terminal Configuration and Functions mcasp4_fsr mcasp5_fsr mlb_clk Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME BALL NUMBER MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) 0 1 2 3 4 5 6 7 8 9 10 14 15 0x1754 CTRL_CORE_PAD_ MMC1_CLK W6 mmc1_clk gpio6_21 Driver off 0x1758 CTRL_CORE_PAD_ MMC1_CMD Y6 mmc1_cmd gpio6_22 Driver off 0x175C CTRL_CORE_PAD_ MMC1_DAT0 AA6 mmc1_dat0 gpio6_23 Driver off 0x1760 CTRL_CORE_PAD_ MMC1_DAT1 Y4 mmc1_dat1 gpio6_24 Driver off 0x1764 CTRL_CORE_PAD_ MMC1_DAT2 AA5 mmc1_dat2 gpio6_25 Driver off 0x1768 CTRL_CORE_PAD_ MMC1_DAT3 Y3 mmc1_dat3 gpio6_26 Driver off 0x176C CTRL_CORE_PAD_ MMC1_SDCD W7 mmc1_sdcd uart6_rxd i2c4_sda gpio6_27 Driver off 0x1770 CTRL_CORE_PAD_ MMC1_SDWP Y9 mmc1_sdwp uart6_txd i2c4_scl gpio6_28 Driver off 0x1774 CTRL_CORE_PAD_ GPIO6_10 AC5 gpio6_10 mdio_mclk i2c3_sda usb3_ulpi_d7 vin2b_hsync1 vin5a_clk0 ehrpwm2A gpio6_10 Driver off 0x1778 CTRL_CORE_PAD_ GPIO6_11 AB4 gpio6_11 mdio_d i2c3_scl usb3_ulpi_d6 vin2b_vsync1 vin5a_de0 ehrpwm2B gpio6_11 Driver off 0x177C CTRL_CORE_PAD_ MMC3_CLK AD4 mmc3_clk usb3_ulpi_d5 vin2b_d7 vin5a_d7 ehrpwm2_trip gpio6_29 zone_input Driver off 0x1780 CTRL_CORE_PAD_ MMC3_CMD AC4 mmc3_cmd spi3_sclk usb3_ulpi_d4 vin2b_d6 vin5a_d6 eCAP2_in_P WM2_out gpio6_30 Driver off 0x1784 CTRL_CORE_PAD_ MMC3_DAT0 AC7 mmc3_dat0 spi3_d1 uart5_rxd usb3_ulpi_d3 vin2b_d5 vin5a_d5 eQEP3A_in gpio6_31 Driver off 0x1788 CTRL_CORE_PAD_ MMC3_DAT1 AC6 mmc3_dat1 spi3_d0 uart5_txd usb3_ulpi_d2 vin2b_d4 vin5a_d4 eQEP3B_in gpio7_0 Driver off 0x178C CTRL_CORE_PAD_ MMC3_DAT2 AC9 mmc3_dat2 spi3_cs0 uart5_ctsn usb3_ulpi_d1 vin2b_d3 vin5a_d3 eQEP3_index gpio7_1 Driver off 0x1790 CTRL_CORE_PAD_ MMC3_DAT3 AC3 mmc3_dat3 spi3_cs1 uart5_rtsn usb3_ulpi_d0 vin2b_d2 vin5a_d2 eQEP3_strob gpio7_2 e Driver off 0x1794 CTRL_CORE_PAD_ MMC3_DAT4 AC8 mmc3_dat4 spi4_sclk uart10_rxd usb3_ulpi_nxt vin2b_d1 vin5a_d1 ehrpwm3A gpio1_22 Driver off 0x1798 CTRL_CORE_PAD_ MMC3_DAT5 AD6 mmc3_dat5 spi4_d1 uart10_txd usb3_ulpi_dir vin2b_d0 vin5a_d0 ehrpwm3B gpio1_23 Driver off 0x179C CTRL_CORE_PAD_ MMC3_DAT6 AB8 mmc3_dat6 spi4_d0 uart10_ctsn usb3_ulpi_stp vin2b_de1 vin5a_hsync0 ehrpwm3_trip gpio1_24 zone_input Driver off 0x17A0 CTRL_CORE_PAD_ MMC3_DAT7 AB5 mmc3_dat7 spi4_cs0 uart10_rtsn usb3_ulpi_clk vin2b_clk1 vin5a_vsync0 eCAP3_in_P WM3_out gpio1_25 Driver off 0x17A4 CTRL_CORE_PAD_S PI1_SCLK A25 spi1_sclk gpio7_7 Driver off 0x17A8 CTRL_CORE_PAD_S PI1_D1 F16 spi1_d1 gpio7_8 Driver off 0x17AC CTRL_CORE_PAD_S PI1_D0 B25 spi1_d0 gpio7_9 Driver off 0x17B0 CTRL_CORE_PAD_S PI1_CS0 A24 spi1_cs0 gpio7_10 Driver off Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 95 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-3. Multiplexing Characteristics (continued) ADDRESS 96 REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 0x17B4 CTRL_CORE_PAD_S PI1_CS1 A22 spi1_cs1 0x17B8 CTRL_CORE_PAD_S PI1_CS2 B21 spi1_cs2 0x17BC CTRL_CORE_PAD_S PI1_CS3 B20 0x17C0 CTRL_CORE_PAD_S PI2_SCLK 0x17C4 1 2 3 4 5 sata1_led spi2_cs1 uart4_rxd mmc3_sdcd spi2_cs2 dcan2_tx mdio_mclk spi1_cs3 uart4_txd mmc3_sdwp spi2_cs3 dcan2_rx mdio_d A26 spi2_sclk CTRL_CORE_PAD_S PI2_D1 B22 0x17C8 CTRL_CORE_PAD_S PI2_D0 0x17CC 6 7 8 9 10 14 15 gpio7_11 Driver off hdmi1_hpd gpio7_12 Driver off hdmi1_cec gpio7_13 Driver off uart3_rxd gpio7_14 Driver off spi2_d1 uart3_txd gpio7_15 Driver off G17 spi2_d0 uart3_ctsn uart5_rxd gpio7_16 Driver off CTRL_CORE_PAD_S PI2_CS0 B24 spi2_cs0 uart3_rtsn uart5_txd gpio7_17 Driver off 0x17D0 CTRL_CORE_PAD_D CAN1_TX G20 dcan1_tx uart8_rxd mmc2_sdcd hdmi1_hpd gpio1_14 Driver off 0x17D4 CTRL_CORE_PAD_D CAN1_RX G19 dcan1_rx uart8_txd mmc2_sdwp hdmi1_cec gpio1_15 Driver off 0x17E0 CTRL_CORE_PAD_U ART1_RXD B27 uart1_rxd mmc4_sdcd gpio7_22 Driver off 0x17E4 CTRL_CORE_PAD_U ART1_TXD C26 uart1_txd mmc4_sdwp gpio7_23 Driver off 0x17E8 CTRL_CORE_PAD_U ART1_CTSN E25 uart1_ctsn uart9_rxd mmc4_clk gpio7_24 Driver off 0x17EC CTRL_CORE_PAD_U ART1_RTSN C27 uart1_rtsn uart9_txd mmc4_cmd gpio7_25 Driver off 0x17F0 CTRL_CORE_PAD_U ART2_RXD D28 uart3_ctsn uart3_rctx mmc4_dat0 uart2_rxd uart1_dcdn gpio7_26 Driver off 0x17F4 CTRL_CORE_PAD_U ART2_TXD D26 uart2_txd uart3_rtsn uart3_sd mmc4_dat1 uart2_txd uart1_dsrn gpio7_27 Driver off 0x17F8 CTRL_CORE_PAD_U ART2_CTSN D27 uart2_ctsn uart3_rxd mmc4_dat2 uart10_rxd uart1_dtrn gpio1_16 Driver off 0x17FC CTRL_CORE_PAD_U ART2_RTSN C28 uart2_rtsn uart3_irtx mmc4_dat3 uart10_txd uart1_rin gpio1_17 Driver off 0x1800 CTRL_CORE_PAD_I 2C1_SDA C21 i2c1_sda 0x1804 CTRL_CORE_PAD_I 2C1_SCL C20 i2c1_scl 0x1808 CTRL_CORE_PAD_I 2C2_SDA C25 i2c2_sda hdmi1_ddc_sc l Driver off 0x180C CTRL_CORE_PAD_I 2C2_SCL F17 i2c2_scl hdmi1_ddc_sd a Driver off 0x1818 CTRL_CORE_PAD_ WAKEUP0 AD17 Wakeup0 dcan1_rx gpio1_0 Driver off 0x181C CTRL_CORE_PAD_ WAKEUP1 AC17 Wakeup1 dcan2_rx gpio1_1 Driver off 0x1820 CTRL_CORE_PAD_ WAKEUP2 AB16 Wakeup2 sys_nirq2 gpio1_2 Driver off Terminal Configuration and Functions uart3_txd sata1_led Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-3. Multiplexing Characteristics (continued) ADDRESS REGISTER NAME MUXMODE FIELD SETTINGS (CTRL_CORE_PAD_*[3:0]) BALL NUMBER 0 Wakeup3 1 sys_nirq1 2 3 4 5 6 7 8 9 10 14 15 gpio1_3 Driver off 0x1824 CTRL_CORE_PAD_ WAKEUP3 AC16 0x1828 CTRL_CORE_PAD_ ON_OFF Y11 0x182C CTRL_CORE_PAD_R TC_PORZ AB17 0x1830 CTRL_CORE_PAD_T MS F18 tms 0x1834 CTRL_CORE_PAD_T DI D23 tdi gpio8_27 0x1838 CTRL_CORE_PAD_T DO F19 tdo gpio8_28 0x183C CTRL_CORE_PAD_T CLK E20 tclk 0x1840 CTRL_CORE_PAD_T RSTN D20 trstn 0x1844 CTRL_CORE_PAD_R TCK E18 rtck gpio8_29 0x1848 CTRL_CORE_PAD_E MU0 G21 emu0 gpio8_30 0x184C CTRL_CORE_PAD_E MU1 D24 emu1 gpio8_31 0x185C CTRL_CORE_PAD_R ESETN E23 resetn 0x1860 CTRL_CORE_PAD_N MIN_DSP D21 nmin_dsp 0x1864 CTRL_CORE_PAD_R STOUTN F23 rstoutn on_off rtc_porz 1. NA in table stands for Not Applicable. Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 97 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 4.4 www.ti.com Signal Descriptions Many signals are available on multiple pins, according to the software configuration of the pin multiplexing options. 1. SIGNAL NAME: The name of the signal passing through the pin. NOTE The subsystem multiplexing signals are not described in Table 4-2 and Table 4-3. 2. DESCRIPTION: Description of the signal 3. TYPE: Signal direction and type: – I = Input – O = Output – IO = Input or output – D = Open Drain – DS = Differential – A = Analog – PWR = Power – GND = Ground 4. BALL: Associated ball(s) bottom NOTE For more information, see the Control Module / Control Module Register Manual section of the device TRM. 4.4.1 Video Input Ports (VIP) NOTE For more information, see the Video Input Port (VIP) section of the device TRM. CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are applicable for all combinations of signals for vin1, vin5 and vin6. However, the timings are only valid for vin2, vin3, and vin4 if signals within a single IOSET are used. The IOSETs are defined in the Table 7-4, Table 7-5 and Table 7-6. Table 4-4. VIP Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL I AG8 I AD9 Video Input 1 98 vin1a_clk0 Video Input 1 Port A Clock input.Input clock for 8-bit 16-bit or 24-bit Port A video capture. Input data is sampled on the CLK0 edge. vin1a_de0 Video Input 1 Data Enable input vin1a_fld0 Video Input 1 Port A Field ID input (1) (1) vin1a_hsync0 Video Input 1 Port A Horizontal Sync input vin1a_vsync0 Video Input 1 Port A Vertical Sync input (1) (1) I AF9 I AE9 I AF8 I AE8 vin1a_d0 Video Input 1 Port A Data input (1) vin1a_d1 Video Input 1 Port A Data input (1) I AD8 vin1a_d2 Video Input 1 Port A Data input (1) I AG7 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-4. VIP Signal Descriptions (continued) SIGNAL NAME TYPE BALL Video Input 1 Port A Data input (1) I AH6 vin1a_d4 Video Input 1 Port A Data input (1) I AH3 vin1a_d5 Video Input 1 Port A Data input (1) I AH5 vin1a_d6 Video Input 1 Port A Data input (1) I AG6 vin1a_d7 Video Input 1 Port A Data input (1) I AH4 vin1a_d8 Video Input 1 Port A Data input (1) I AG4 vin1a_d9 Video Input 1 Port A Data input (1) I AG2 vin1a_d10 Video Input 1 Port A Data input (1) I AG3 vin1a_d11 Video Input 1 Port A Data input (1) I AG5 vin1a_d12 Video Input 1 Port A Data input (1) I AF2 vin1a_d13 Video Input 1 Port A Data input (1) I AF6 vin1a_d14 Video Input 1 Port A Data input (1) I AF3 vin1a_d15 Video Input 1 Port A Data input (1) I AF4 vin1a_d16 Video Input 1 Port A Data input (1) I AF1 vin1a_d17 Video Input 1 Port A Data input (1) I AE3 vin1a_d18 Video Input 1 Port A Data input (1) I AE5 vin1a_d19 Video Input 1 Port A Data input (1) I AE1 vin1a_d20 Video Input 1 Port A Data input (1) I AE2 vin1a_d21 Video Input 1 Port A Data input (1) I AE6 vin1a_d22 Video Input 1 Port A Data input (1) I AD2 vin1a_d23 Video Input 1 Port A Data input (1) I AD3 I N6 / AD9 vin1a_d3 DESCRIPTION vin1b_hsync1 Video Input 1 Port B Horizontal Sync input vin1b_vsync1 Video Input 1 Port B Vertical Sync input (1) (1) vin1b_fld1 Video Input 1 Port B Field ID input vin1b_de1 Video Input 1 Port B Data Enable input(1) vin1b_clk1 Video Input 1 Port B Clock input vin1b_d0 Video Input 1 Port B Data input vin1b_d1 (1) (1) I AF9 I AE9 I AF8 / M4 I AH7 (1) I AF4 / AD3 Video Input 1 Port B Data input (1) I AF3 / AD2 vin1b_d2 Video Input 1 Port B Data input (1) I AF6 / AE6 vin1b_d3 Video Input 1 Port B Data input (1) I AF2 / AE2 vin1b_d4 Video Input 1 Port B Data input (1) I AG5 / AE1 vin1b_d5 Video Input 1 Port B Data input (1) I AG3 / AE5 vin1b_d6 Video Input 1 Port B Data input (1) I AG2 / AE3 vin1b_d7 Video Input 1 Port B Data input (1) I AG4 / AF1 Video Input 2 vin2a_clk0 Video Input 2 Port A Clock input. I E1 / V1 vin2a_de0 Video Input 2 Port A Data Enable input I G2 / V7 vin2a_fld0 Video Input 2 Port A Field ID input I H7 / G2 / W2 vin2a_hsync0 Video Input 2 Port A Horizontal Sync input I G1 / U7 vin2a_vsync0 Video Input 2 Port A Vertical Sync input I G6 / V6 vin2a_d0 Video Input 2 Port A Data input I F2 / U4 vin2a_d1 Video Input 2 Port A Data input I F3 / V2 vin2a_d2 Video Input 2 Port A Data input I D1 / Y1 vin2a_d3 Video Input 2 Port A Data input I E2 / W9 vin2a_d4 Video Input 2 Port A Data input I D2 / V9 vin2a_d5 Video Input 2 Port A Data input I F4 / U5 vin2a_d6 Video Input 2 Port A Data input I C1 / V5 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 99 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-4. VIP Signal Descriptions (continued) SIGNAL NAME TYPE BALL vin2a_d7 DESCRIPTION Video Input 2 Port A Data input I E4 / V4 vin2a_d8 Video Input 2 Port A Data input I F5 / V3 vin2a_d9 Video Input 2 Port A Data input I E6 / Y2 vin2a_d10 Video Input 2 Port A Data input I D3 / U6 vin2a_d11 Video Input 2 Port A Data input I F6 / U3 vin2a_d12 Video Input 2 Port A Data input I D5 vin2a_d13 Video Input 2 Port A Data input I C2 vin2a_d14 Video Input 2 Port A Data input I C3 vin2a_d15 Video Input 2 Port A Data input I C4 vin2a_d16 Video Input 2 Port A Data input I B2 vin2a_d17 Video Input 2 Port A Data input I D6 vin2a_d18 Video Input 2 Port A Data input I C5 vin2a_d19 Video Input 2 Port A Data input I A3 vin2a_d20 Video Input 2 Port A Data input I B3 vin2a_d21 Video Input 2 Port A Data input I B4 vin2a_d22 Video Input 2 Port A Data input I B5 vin2a_d23 Video Input 2 Port A Data input I A4 vin2b_clk1 Video Input 2 Port B Clock input I AB5 / H7 vin2b_de1 Video Input 2 Port B Data Enable input I AB8 / G2 vin2b_fld1 Video Input 2 Port B Field ID input I G2 vin2b_hsync1 Video Input 2 Port B Horizontal Sync input I AC5 / G1 vin2b_vsync1 Video Input 2 Port B Vertical Sync input I AB4 / G6 vin2b_d0 Video Input 2 Port B Data input I AD6 / A4 vin2b_d1 Video Input 2 Port B Data input I AC8 / B5 vin2b_d2 Video Input 2 Port B Data input I AC3 / B4 vin2b_d3 Video Input 2 Port B Data input I AC9 / B3 vin2b_d4 Video Input 2 Port B Data input I AC6 / A3 vin2b_d5 Video Input 2 Port B Data input I AC7 / C5 vin2b_d6 Video Input 2 Port B Data input I AC4 / D6 vin2b_d7 Video Input 2 Port B Data input I AD4 / B2 vin3a_clk0 Video Input 3 Port A Clock input I B11 / AH7 / P1 vin3a_de0 Video Input 3 Port A Data Enable input I N9 / B3 / B10 vin3a_fld0 Video Input 3 Port A Field ID input I P9 / B4 / D11 vin3a_hsync0 Video Input 3 Port A Horizontal Sync input I N7 / B5 / C11 vin3a_vsync0 Video Input 3 Port A Vertical Sync input I R4 / A4 / E11 vin3a_d0 Video Input 3 Port A Data input I M6 / AF1 / B7 vin3a_d1 Video Input 3 Port A Data input I M2 / AE3 / B8 vin3a_d2 Video Input 3 Port A Data input I L5 / AE5 / A7 vin3a_d3 Video Input 3 Port A Data input I M1 / AE1 / A8 vin3a_d4 Video Input 3 Port A Data input I L6 / AE2 / C9 vin3a_d5 Video Input 3 Port A Data input I L4 / AE6 / A9 vin3a_d6 Video Input 3 Port A Data input I L3 / AD2 / B9 vin3a_d7 Video Input 3 Port A Data input I L2 / AD3 / A10 vin3a_d8 Video Input 3 Port A Data input I L1 / B2 / E8 vin3a_d9 Video Input 3 Port A Data input I K2 / D6 / D9 vin3a_d10 Video Input 3 Port A Data input I J1 / C5 / D7 Video Input 3 100 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-4. VIP Signal Descriptions (continued) SIGNAL NAME TYPE BALL vin3a_d11 DESCRIPTION Video Input 3 Port A Data input I J2 / A3 / D8 vin3a_d12 Video Input 3 Port A Data input I H1 / B3 / A5 vin3a_d13 Video Input 3 Port A Data input I J3 / B4 / C6 vin3a_d14 Video Input 3 Port A Data input I H2 / B5 / C8 vin3a_d15 Video Input 3 Port A Data input I H3 / A4 / C7 vin3a_d16 Video Input 3 Port A Data input I R6 / F11 vin3a_d17 Video Input 3 Port A Data input I T9 / G10 vin3a_d18 Video Input 3 Port A Data input I T6 / F10 vin3a_d19 Video Input 3 Port A Data input I T7 / G11 vin3a_d20 Video Input 3 Port A Data input I P6 / E9 vin3a_d21 Video Input 3 Port A Data input I R9 / F9 vin3a_d22 Video Input 3 Port A Data input I R5 / F8 vin3a_d23 Video Input 3 Port A Data input I P5 / E7 vin3b_clk1 Video Input 3 Port B Clock input I P7 / M4 vin3b_de1 Video Input 3 Port B Data Enable input I N6 vin3b_fld1 Video Input 3 Port A Field ID input I M4 vin3b_hsync1 Video Input 3 Port A Horizontal Sync input I H5 vin3b_vsync1 H6 Video Input 3 Port A Vertical Sync input I vin3b_d0 Video Input 3 Port B Data input I K7 vin3b_d1 Video Input 3 Port B Data input I M7 vin3b_d2 Video Input 3 Port B Data input I J5 vin3b_d3 Video Input 3 Port B Data input I K6 vin3b_d4 Video Input 3 Port B Data input I J7 vin3b_d5 Video Input 3 Port B Data input I J4 vin3b_d6 Video Input 3 Port B Data input I J6 vin3b_d7 Video Input 3 Port B Data input I H4 vin4a_clk0 Video Input 4 Port A Clock input I P4 / B26 / B11 vin4a_de0 Video Input 4 Port A Data Enable input I H6 / C23 / B10 / P7 vin4a_fld0 Video Input 4 Video Input 4 Port A Field ID input I J7 / F21 / P9 / D11 vin4a_hsync0 Video Input 4 Port A Horizontal Sync input I R3 / E21 / C11 / P7 vin4a_vsync0 Video Input 4 Port A Vertical Sync input I T2 / F20 / E11 / N1 vin4a_d0 Video Input 4 Port A Data input I R6 / B7 / B14 vin4a_d1 Video Input 4 Port A Data input I T9 / B8 / J14 vin4a_d2 Video Input 4 Port A Data input I T6 / A7 / G13 vin4a_d3 Video Input 4 Port A Data input I T7 / A8 / J11 vin4a_d4 Video Input 4 Port A Data input I P6 / C9 / E12 vin4a_d5 Video Input 4 Port A Data input I R9 / A9 / F13 vin4a_d6 Video Input 4 Port A Data input I R5 / B9 / C12 vin4a_d7 Video Input 4 Port A Data input I P5 / A10 / D12 vin4a_d8 Video Input 4 Port A Data input I E8 / U2 / E15 / J4 vin4a_d9 Video Input 4 Port A Data input I D9 / U1 / A20 / J6 vin4a_d10 Video Input 4 Port A Data input I D7 / P3 / B15 / H4 vin4a_d11 Video Input 4 Port A Data input I D8 / R2 / A15 / H5 vin4a_d12 Video Input 4 Port A Data input I A5 / K7 / D15 vin4a_d13 Video Input 4 Port A Data input I C6 / M7 / B16 vin4a_d14 Video Input 4 Port A Data input I C8 / J5 / B17 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 101 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-4. VIP Signal Descriptions (continued) SIGNAL NAME TYPE BALL vin4a_d15 DESCRIPTION Video Input 4 Port A Data input I C7 / K6 / A17 vin4a_d16 Video Input 4 Port A Data input I C18 / F11 vin4a_d17 Video Input 4 Port A Data input I A21 / G10 vin4a_d18 Video Input 4 Port A Data input I G16 / F10 vin4a_d19 Video Input 4 Port A Data input I D17 / G11 vin4a_d20 Video Input 4 Port A Data input I AA3 / E9 vin4a_d21 Video Input 4 Port A Data input I AB9 / F9 vin4a_d22 Video Input 4 Port A Data input I AB3 / F8 vin4a_d23 Video Input 4 Port A Data input I AA4 / E7 vin4b_clk1 Video Input 4 Port B Clock input I N9 / V1 vin4b_de1 Video Input 4 Port B Data Enable input I P9 / V7 vin4b_fld1 Video Input 4 Port B Field ID input I P4 / W2 vin4b_hsync1 Video Input 4 Port B Horizontal Sync input I N7 / U7 vin4b_vsync1 Video Input 4 Port B Vertical Sync input I R4 / V6 vin4b_d0 Video Input 4 Port B Data input I R6 / U4 vin4b_d1 Video Input 4 Port B Data input I T9 / V2 vin4b_d2 Video Input 4 Port B Data input I T6 / Y1 vin4b_d3 Video Input 4 Port B Data input I T7 / W9 vin4b_d4 Video Input 4 Port B Data input I P6 / V9 vin4b_d5 Video Input 4 Port B Data input I R9 / U5 vin4b_d6 Video Input 4 Port B Data input I R5 / V5 vin4b_d7 Video Input 4 Port B Data input I P5 / V4 I AC5 I AB4 Video Input 5 vin5a_clk0 Video Input 5 Port A Clock input (2) vin5a_de0 Video Input 5 Port A Data Enable input vin5a_fld0 Video Input 5 Port A Field ID input (2) (2) vin5a_hsync0 Video Input 5 Port A Horizontal Sync input vin5a_vsync0 Video Input 5 Port A Vertical Sync input (2) (2) I C17 I AB8 I AB5 I AD6 vin5a_d0 Video Input 5 Port A Data input (2) vin5a_d1 Video Input 5 Port A Data input (2) I AC8 vin5a_d2 Video Input 5 Port A Data input (2) I AC3 vin5a_d3 Video Input 5 Port A Data input (2) I AC9 vin5a_d4 Video Input 5 Port A Data input (2) I AC6 vin5a_d5 Video Input 5 Port A Data input (2) I AC7 vin5a_d6 Video Input 5 Port A Data input (2) I AC4 vin5a_d7 Video Input 5 Port A Data input (2) I AD4 vin5a_d8 Video Input 5 Port A Data input (2) I AA4 vin5a_d9 Video Input 5 Port A Data input (2) I AB3 vin5a_d10 Video Input 5 Port A Data input (2) I AB9 vin5a_d11 Video Input 5 Port A Data input (2) I AA3 vin5a_d12 Video Input 5 Port A Data input (2) I D17 vin5a_d13 Video Input 5 Port A Data input (2) I G16 vin5a_d14 Video Input 5 Port A Data input (2) I A21 vin5a_d15 Video Input 5 Port A Data input (2) I C18 Video Input 6 102 (2) vin6a_clk0 Video Input 6 Port A Clock input vin6a_de0 Video Input 6 Port B Data Enable input(2) Terminal Configuration and Functions I E17 I D14 Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-4. VIP Signal Descriptions (continued) SIGNAL NAME vin6a_fld0 DESCRIPTION Video Input 6 Port A Field ID input (2) vin6a_hsync0 Video Input 6 Port A Horizontal Sync input vin6a_vsync0 Video Input 6 Port A Vertical Sync input (2) (2) TYPE BALL I C14 I F12 I G12 Video Input 6 Port A Data input (2) I C17 / D18 vin6a_d1 Video Input 6 Port A Data input (2) I B19 vin6a_d2 Video Input 6 Port A Data input (2) I F15 vin6a_d3 Video Input 6 Port A Data input (2) I B18 vin6a_d4 Video Input 6 Port A Data input (2) I A16 vin6a_d5 Video Input 6 Port A Data input (2) I C15 vin6a_d6 Video Input 6 Port A Data input (2) I A18 vin6a_d7 Video Input 6 Port A Data input (2) I A19 vin6a_d8 Video Input 6 Port A Data input (2) I F14 vin6a_d9 Video Input 6 Port A Data input (2) I G14 vin6a_d10 Video Input 6 Port A Data input (2) I A13 vin6a_d11 Video Input 6 Port A Data input (2) I E14 vin6a_d12 Video Input 6 Port A Data input (2) I A12 vin6a_d13 Video Input 6 Port A Data input (2) I B13 vin6a_d14 Video Input 6 Port A Data input (2) I A11 vin6a_d15 Video Input 6 Port A Data input (2) I B12 vin6a_d0 (1) The VIP1 interface (Video Input 1a and Video Input 1b in Table 4-4 ) signal sets are NOT supported in the DRA74x device. For more details on the device differentiation, refer to the Table 3-1, Device Comparison. (2) The VIP3 interface (Video Input 5 and Video Input 6 in Table 4-4 ) signal sets are NOT supported in the DRA74x device. For more details on the device differentiation, refer to the Table 3-1, Device Comparison. 4.4.2 Display Subsystem – Video Output Ports CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are valid only if signals within a single IOSET are used. The IOSETs are defined in the Table 7-17 and Table 7-18. Table 4-5. DSS Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL DPI Video Output 1 vout1_clk Video Output 1 Clock output O D11 vout1_de Video Output 1 Data Enable output O B10 vout1_fld Video Output 1 Field ID output.This signal is not used for embedded sync modes. O B11 vout1_hsync Video Output 1 Horizontal Sync output.This signal is not used for embedded sync modes. O C11 vout1_vsync Video Output 1 Vertical Sync output.This signal is not used for embedded sync modes. O E11 vout1_d0 Video Output 1 Data output O F11 vout1_d1 Video Output 1 Data output O G10 vout1_d2 Video Output 1 Data output O F10 vout1_d3 Video Output 1 Data output O G11 vout1_d4 Video Output 1 Data output O E9 vout1_d5 Video Output 1 Data output O F9 vout1_d6 Video Output 1 Data output O F8 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 103 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-5. DSS Signal Descriptions (continued) SIGNAL NAME TYPE BALL vout1_d7 DESCRIPTION Video Output 1 Data output O E7 vout1_d8 Video Output 1 Data output O E8 vout1_d9 Video Output 1 Data output O D9 vout1_d10 Video Output 1 Data output O D7 vout1_d11 Video Output 1 Data output O D8 vout1_d12 Video Output 1 Data output O A5 vout1_d13 Video Output 1 Data output O C6 vout1_d14 Video Output 1 Data output O C8 vout1_d15 Video Output 1 Data output O C7 vout1_d16 Video Output 1 Data output O B7 vout1_d17 Video Output 1 Data output O B8 vout1_d18 Video Output 1 Data output O A7 vout1_d19 Video Output 1 Data output O A8 vout1_d20 Video Output 1 Data output O C9 vout1_d21 Video Output 1 Data output O A9 vout1_d22 Video Output 1 Data output O B9 vout1_d23 Video Output 1 Data output O A10 vout2_clk Video Output 2 Clock output O H7 / B26 vout2_de Video Output 2 Data Enable output O G2 / C23 vout2_fld Video Output 2 Field ID output.This signal is not used for embedded sync modes. O E1 / F21 vout2_hsync Video Output 2 Horizontal Sync output.This signal is not used for embedded sync modes. O G1 / E21 vout2_vsync Video Output 2 Vertical Sync output.This signal is not used for embedded sync modes. O G6 / F20 vout2_d0 Video Output 2 Data output O A4 / B14 vout2_d1 Video Output 2 Data output O B5 / J14 vout2_d2 Video Output 2 Data output O B4 / G13 vout2_d3 Video Output 2 Data output O B3 / J11 vout2_d4 Video Output 2 Data output O A3 / E12 vout2_d5 Video Output 2 Data output O C5 / F13 vout2_d6 Video Output 2 Data output O D6 / C12 vout2_d7 Video Output 2 Data output O B2 / D12 vout2_d8 Video Output 2 Data output O C4 / E15 vout2_d9 Video Output 2 Data output O C3 / A20 vout2_d10 Video Output 2 Data output O C2 / B15 vout2_d11 Video Output 2 Data output O D5 / A15 vout2_d12 Video Output 2 Data output O F6 / D15 vout2_d13 Video Output 2 Data output O D3 / B16 vout2_d14 Video Output 2 Data output O E6 / B17 vout2_d15 Video Output 2 Data output O F5 / A17 vout2_d16 Video Output 2 Data output O E4 / C18 vout2_d17 Video Output 2 Data output O C1 / A21 vout2_d18 Video Output 2 Data output O F4 / G16 vout2_d19 Video Output 2 Data output O D2 / D17 vout2_d20 Video Output 2 Data output O E2 / AA3 vout2_d21 Video Output 2 Data output O D1 / AB9 vout2_d22 Video Output 2 Data output O F3 / AB3 vout2_d23 Video Output 2 Data output O F2 / AA4 DPI Video Output 2 104 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-5. DSS Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL DPI Video Output 3 (1) vout3_clk Video Output 3 Clock output O P1 / AF9 vout3_de Video Output 3 Data Enable output O N9 / AD9 (1) vout3_fld Video Output 3 Field ID output.This signal is not used for embedded sync modes. O P9 / AG8 (1) vout3_hsync Video Output 3 Horizontal Sync output.This signal is not used for embedded sync modes. O N7 / AE9 (1) vout3_vsync Video Output 3 Vertical Sync output.This signal is not used for embedded sync modes. O R4 / AF8 (1) vout3_d0 Video Output 3 Data output O M6/ AH4 (1)/ AD3 vout3_d1 Video Output 3 Data output O M2/ AG6 (1)/ AD2 vout3_d2 Video Output 3 Data output O vout3_d3 Video Output 3 Data output O vout3_d4 Video Output 3 Data output O vout3_d5 Video Output 3 Data output O (1) (1) L5/ AH5 M1/ (1) / AE6 AH3 (1)/ (1) L6/ AH6 (1) L4/ AG7 (1) (1) AE2 / AE1 (1) / AE5 (1) vout3_d6 Video Output 3 Data output O L3/ AD8 (1) vout3_d7 Video Output 3 Data output O L2/ AE8 (1) / AE3 / AF1 (1) (1) (1) vout3_d8 Video Output 3 Data output O L1 / AF4 vout3_d9 Video Output 3 Data output O K2 / AF3 (1) vout3_d10 Video Output 3 Data output O J1 / AF6 (1) vout3_d11 Video Output 3 Data output O J2 / AF2 (1) vout3_d12 Video Output 3 Data output O H1 / AG5 (1) vout3_d13 Video Output 3 Data output O J3 / AG3 (1) vout3_d14 Video Output 3 Data output O H2 / AG2 (1) vout3_d15 Video Output 3 Data output O H3 / AG4 (1) vout3_d16 Video Output 3 Data output O R6/ AG8 (1)/ AH4 vout3_d17 Video Output 3 Data output O T9/ AD9 (1)/ AG6 vout3_d18 Video Output 3 Data output O T6 / AH5 (1) vout3_d19 Video Output 3 Data output O T7 / AH3 (1) vout3_d20 Video Output 3 Data output O P6 / AH6 vout3_d21 Video Output 3 Data output O R9 / AG7 (1) vout3_d22 Video Output 3 Data output O R5 / AD8 (1) vout3_d23 Video Output 3 Data output O P5 / AE8 (1) (1) (1) (1) (1) The VOUT3 interface when multiplexed onto balls mapped to the VDDSHV6 supply rail is restricted to operating in 1.8V mode only (i.e., VDDSHV6 must be supplied with 1.8V). 3.3V mode is not supported. This must be considered in the pin mux programming and VDDSHVx supply connections. 4.4.3 Display Subsystem – High-Definition Multimedia Interface (HDMI) NOTE For more information, see the Display Subsystem / Display Subsystem Overview of the device TRM. Table 4-6. HDMI Signal Descriptions SIGNAL NAME hdmi1_cec DESCRIPTION HDMI consumer electronic control TYPE BALL IOD B20/ G19 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 105 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-6. HDMI Signal Descriptions (continued) SIGNAL NAME hdmi1_hpd DESCRIPTION HDMI display hot plug detect TYPE BALL I B21/ G20 C25 hdmi1_ddc_scl HDMI display data channel clock IOD hdmi1_ddc_sda HDMI display data channel data IOD F17 hdmi1_clockx HDMI clock differential positive or negative ODS AG16 hdmi1_clocky HDMI clock differential positive or negative ODS AH16 hdmi1_data2x HDMI data 2 differential positive or negative ODS AG19 hdmi1_data2y HDMI data 2 differential positive or negative ODS AH19 hdmi1_data1x HDMI data 1 differential positive or negative ODS AG18 hdmi1_data1y HDMI data 1 differential positive or negative ODS AH18 hdmi1_data0x HDMI data 0 differential positive or negative ODS AG17 hdmi1_data0y HDMI data 0 differential positive or negative ODS AH17 4.4.4 External Memory Interface (EMIF) NOTE For more information, see the Memory Subsystem / EMIF Controller section of the device TRM. NOTE The index numbers 1 and 2 which are part of the EMIF1 and EMIF2 signal prefixes (ddr1_* and ddr2_*) listed in Table 4-7, EMIF Signal Descriptions, not to be confused with DDR1 and DDR2 types of SDRAM memories. Table 4-7. EMIF Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL EMIF Channel 1 106 ddr1_csn0 EMIF1 Chip Select 0 O AH23 ddr1_cke EMIF1 Clock Enable O AG22 ddr1_ck EMIF1 Clock O AG24 ddr1_nck EMIF1 Negative Clock O AH24 ddr1_odt0 EMIF1 On-Die Termination for Chip Select 0 O AE20 ddr1_casn EMIF1 Column Address Strobe O AC18 ddr1_rasn EMIF1 Row Address Strobe O AF20 ddr1_wen EMIF1 Write Enable O AH21 AG21 ddr1_rst EMIF1 Reset output (DDR3-SDRAM only) O ddr1_ba0 EMIF1 Bank Address O AF17 ddr1_ba1 EMIF1 Bank Address O AE18 ddr1_ba2 EMIF1 Bank Address O AB18 ddr1_a0 EMIF1 Address Bus O AD20 ddr1_a1 EMIF1 Address Bus O AC19 ddr1_a2 EMIF1 Address Bus O AC20 ddr1_a3 EMIF1 Address Bus O AB19 ddr1_a4 EMIF1 Address Bus O AF21 ddr1_a5 EMIF1 Address Bus O AH22 ddr1_a6 EMIF1 Address Bus O AG23 ddr1_a7 EMIF1 Address Bus O AE21 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-7. EMIF Signal Descriptions (continued) SIGNAL NAME TYPE BALL ddr1_a8 DESCRIPTION EMIF1 Address Bus O AF22 ddr1_a9 EMIF1 Address Bus O AE22 ddr1_a10 EMIF1 Address Bus O AD21 ddr1_a11 EMIF1 Address Bus O AD22 ddr1_a12 EMIF1 Address Bus O AC21 ddr1_a13 EMIF1 Address Bus O AF18 ddr1_a14 EMIF1 Address Bus O AE17 ddr1_a15 EMIF1 Address Bus O AD18 ddr1_d0 EMIF1 Data Bus IO AF25 ddr1_d1 EMIF1 Data Bus IO AF26 ddr1_d2 EMIF1 Data Bus IO AG26 ddr1_d3 EMIF1 Data Bus IO AH26 ddr1_d4 EMIF1 Data Bus IO AF24 ddr1_d5 EMIF1 Data Bus IO AE24 ddr1_d6 EMIF1 Data Bus IO AF23 ddr1_d7 EMIF1 Data Bus IO AE23 ddr1_d8 EMIF1 Data Bus IO AC23 ddr1_d9 EMIF1 Data Bus IO AF27 ddr1_d10 EMIF1 Data Bus IO AG27 ddr1_d11 EMIF1 Data Bus IO AF28 ddr1_d12 EMIF1 Data Bus IO AE26 ddr1_d13 EMIF1 Data Bus IO AC25 ddr1_d14 EMIF1 Data Bus IO AC24 ddr1_d15 EMIF1 Data Bus IO AD25 ddr1_d16 EMIF1 Data Bus IO V20 ddr1_d17 EMIF1 Data Bus IO W20 ddr1_d18 EMIF1 Data Bus IO AB28 ddr1_d19 EMIF1 Data Bus IO AC28 ddr1_d20 EMIF1 Data Bus IO AC27 ddr1_d21 EMIF1 Data Bus IO Y19 ddr1_d22 EMIF1 Data Bus IO AB27 ddr1_d23 EMIF1 Data Bus IO Y20 ddr1_d24 EMIF1 Data Bus IO AA23 ddr1_d25 EMIF1 Data Bus IO Y22 ddr1_d26 EMIF1 Data Bus IO Y23 ddr1_d27 EMIF1 Data Bus IO AA24 ddr1_d28 EMIF1 Data Bus IO Y24 ddr1_d29 EMIF1 Data Bus IO AA26 ddr1_d30 EMIF1 Data Bus IO AA25 ddr1_d31 EMIF1 Data Bus IO AA28 W22 EMIF1 ECC Data Bus (1) IO ddr1_ecc_d1 EMIF1 ECC Data Bus (1) IO V23 ddr1_ecc_d2 EMIF1 ECC Data Bus (1) IO W19 ddr1_ecc_d3 EMIF1 ECC Data Bus (1) IO W23 ddr1_ecc_d4 EMIF1 ECC Data Bus (1) IO Y25 ddr1_ecc_d5 EMIF1 ECC Data Bus (1) IO V24 ddr1_ecc_d6 EMIF1 ECC Data Bus (1) IO V25 ddr1_ecc_d0 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 107 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-7. EMIF Signal Descriptions (continued) SIGNAL NAME ddr1_ecc_d7 DESCRIPTION EMIF1 ECC Data Bus (1) TYPE BALL IO Y26 AD23 ddr1_dqm0 EMIF1 Data Mask O ddr1_dqm1 EMIF1 Data Mask O AB23 ddr1_dqm2 EMIF1 Data Mask O AC26 ddr1_dqm3 EMIF1 Data Mask O AA27 EMIF1 ECC Data Mask O V26 ddr1_dqs0 Data strobe 0 input/output for byte 0 of the 32-bit data bus. This signal is output to the EMIF1 memory when writing and input when reading. IO AH25 ddr1_dqsn0 Data strobe 0 invert IO AG25 ddr1_dqs1 Data strobe 1 input/output for byte 1 of the 32-bit data bus. This signal is output to the EMIF1 memory when writing and input when reading. IO AE27 ddr1_dqsn1 Data strobe 1 invert IO AE28 ddr1_dqs2 Data strobe 2 input/output for byte 2 of the 32-bit data bus. This signal is output to the EMIF1 memory when writing and input when reading. IO AD27 ddr1_dqsn2 Data strobe 2 invert IO AD28 ddr1_dqs3 Data strobe 3 input/output for byte 3 of the 32-bit data bus. This signal is output to the EMIF1 memory when writing and input when reading. IO Y28 ddr1_dqsn3 Data strobe 3 invert IO Y27 ddr1_dqs_ecc EMIF1 ECC Data strobe input/output. This signal is output to the EMIF1 memory when writing and input when reading. IO V27 ddr1_dqsn_ecc EMIF1 ECC Complementary Data strobe IO V28 Reference Power Supply EMIF1 A Y18 ddr2_csn0 EMIF2 Chip Select 0 O P24 ddr2_cke EMIF2 Clock Enable O U24 T28 ddr1_dqm_ecc ddr1_vref0 EMIF Channel 2 108 ddr2_ck EMIF2 Clock O ddr2_nck EMIF2 Negative Clock O T27 ddr2_odt0 EMIF2 On-Die Termination for Chip Select 0 O R23 ddr2_casn EMIF2 Column Address Strobe O U28 ddr2_rasn EMIF2 Row Address Strobe O T23 ddr2_wen EMIF2 Write Enable O U25 ddr2_rst EMIF2 Reset output (DDR3-SDRAM only) O R24 ddr2_ba0 EMIF2 Bank Address O U23 ddr2_ba1 EMIF2 Bank Address O U27 ddr2_ba2 EMIF2 Bank Address O U26 ddr2_a0 EMIF2 Address Bus O R25 ddr2_a1 EMIF2 Address Bus O R26 ddr2_a2 EMIF2 Address Bus O R28 ddr2_a3 EMIF2 Address Bus O R27 ddr2_a4 EMIF2 Address Bus O P23 ddr2_a5 EMIF2 Address Bus O P22 ddr2_a6 EMIF2 Address Bus O P25 ddr2_a7 EMIF2 Address Bus O N20 ddr2_a8 EMIF2 Address Bus O P27 ddr2_a9 EMIF2 Address Bus O N27 ddr2_a10 EMIF2 Address Bus O N23 ddr2_a11 EMIF2 Address Bus O P26 ddr2_a12 EMIF2 Address Bus O N28 ddr2_a13 EMIF2 Address Bus O T22 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-7. EMIF Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL O R22 EMIF2 Address Bus O U22 EMIF2 Data Bus IO E26 ddr2_d1 EMIF2 Data Bus IO G25 ddr2_d2 EMIF2 Data Bus IO F25 ddr2_d3 EMIF2 Data Bus IO F24 ddr2_d4 EMIF2 Data Bus IO F26 ddr2_d5 EMIF2 Data Bus IO F27 ddr2_d6 EMIF2 Data Bus IO E27 ddr2_d7 EMIF2 Data Bus IO E28 ddr2_d8 EMIF2 Data Bus IO H23 ddr2_a14 EMIF2 Address Bus ddr2_a15 ddr2_d0 ddr2_d9 EMIF2 Data Bus IO H25 ddr2_d10 EMIF2 Data Bus IO H24 ddr2_d11 EMIF2 Data Bus IO H26 ddr2_d12 EMIF2 Data Bus IO G26 ddr2_d13 EMIF2 Data Bus IO J25 ddr2_d14 EMIF2 Data Bus IO J26 ddr2_d15 EMIF2 Data Bus IO J24 ddr2_d16 EMIF2 Data Bus IO L22 ddr2_d17 EMIF2 Data Bus IO K20 ddr2_d18 EMIF2 Data Bus IO K21 ddr2_d19 EMIF2 Data Bus IO L23 ddr2_d20 EMIF2 Data Bus IO L24 ddr2_d21 EMIF2 Data Bus IO J23 ddr2_d22 EMIF2 Data Bus IO K22 ddr2_d23 EMIF2 Data Bus IO J20 ddr2_d24 EMIF2 Data Bus IO L27 ddr2_d25 EMIF2 Data Bus IO L26 ddr2_d26 EMIF2 Data Bus IO L25 ddr2_d27 EMIF2 Data Bus IO L28 ddr2_d28 EMIF2 Data Bus IO M23 ddr2_d29 EMIF2 Data Bus IO M24 ddr2_d30 EMIF2 Data Bus IO M25 ddr2_d31 EMIF2 Data Bus IO M26 ddr2_dqm0 EMIF2 Data Mask O F28 ddr2_dqm1 EMIF2 Data Mask O G24 ddr2_dqm2 EMIF2 Data Mask O K23 ddr2_dqm3 EMIF2 Data Mask O M22 ddr2_dqs0 Data strobe 0 input/output for byte 0 of the 32-bit data bus. This signal is output to the EMIF2 memory when writing and input when reading. IO G28 ddr2_dqsn0 Data strobe 0 invert IO G27 ddr2_dqs1 Data strobe 1 input/output for byte 1 of the 32-bit data bus. This signal is output to the EMIF2 memory when writing and input when reading. IO H27 ddr2_dqsn1 Data strobe 1 invert IO H28 ddr2_dqs2 Data strobe 2 input/output for byte 2 of the 32-bit data bus. This signal is output to the EMIF2 memory when writing and input when reading. IO K27 ddr2_dqsn2 Data strobe 2 invert IO K28 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 109 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-7. EMIF Signal Descriptions (continued) SIGNAL NAME TYPE BALL ddr2_dqs3 DESCRIPTION Data strobe 3 input/output for byte 3 of the 32-bit data bus. This signal is output to the EMIF2 memory when writing and input when reading. IO M28 ddr2_dqsn3 Data strobe 3 invert IO M27 ddr2_vref0 Reference Power Supply EMIF2 A N22 (1) The ECC module (EMIF1 ECC Data Bus in Table 4-4 ) signal sets are NOT supported in the DRA74x device. For more details on the device differentiation, refer to the Table 3-1, Device Comparison. 4.4.5 General-Purpose Memory Controller (GPMC) NOTE For more information, see the Memory Subsystem / General-Purpose Memory Controller section of the device TRM. Table 4-8. GPMC Signal Descriptions SIGNAL NAME 110 TYPE BALL gpmc_ad0 DESCRIPTION GPMC Data 0 in A/D nonmultiplexed mode and additionally Address 1 in A/D multiplexed mode IO M6 gpmc_ad1 GPMC Data 1 in A/D nonmultiplexed mode and additionally Address 2 in A/D multiplexed mode IO M2 gpmc_ad2 GPMC Data 2 in A/D nonmultiplexed mode and additionally Address 3 in A/D multiplexed mode IO L5 gpmc_ad3 GPMC Data 3 in A/D nonmultiplexed mode and additionally Address 4 in A/D multiplexed mode IO M1 gpmc_ad4 GPMC Data 4 in A/D nonmultiplexed mode and additionally Address 5 in A/D multiplexed mode IO L6 gpmc_ad5 GPMC Data 5 in A/D nonmultiplexed mode and additionally Address 6 in A/D multiplexed mode IO L4 gpmc_ad6 GPMC Data 6 in A/D nonmultiplexed mode and additionally Address 7 in A/D multiplexed mode IO L3 gpmc_ad7 GPMC Data 7 in A/D nonmultiplexed mode and additionally Address 8 in A/D multiplexed mode IO L2 gpmc_ad8 GPMC Data 8 in A/D nonmultiplexed mode and additionally Address 9 in A/D multiplexed mode IO L1 gpmc_ad9 GPMC Data 9 in A/D nonmultiplexed mode and additionally Address 10 in A/D multiplexed mode IO K2 gpmc_ad10 GPMC Data 10 in A/D nonmultiplexed mode and additionally Address 11 in A/D multiplexed mode IO J1 gpmc_ad11 GPMC Data 11 in A/D nonmultiplexed mode and additionally Address 12 in A/D multiplexed mode IO J2 gpmc_ad12 GPMC Data 12 in A/D nonmultiplexed mode and additionally Address 13 in A/D multiplexed mode IO H1 gpmc_ad13 GPMC Data 13 in A/D nonmultiplexed mode and additionally Address 14 in A/D multiplexed mode IO J3 gpmc_ad14 GPMC Data 14 in A/D nonmultiplexed mode and additionally Address 15 in A/D multiplexed mode IO H2 gpmc_ad15 GPMC Data 15 in A/D nonmultiplexed mode and additionally Address 16 in A/D multiplexed mode IO H3 gpmc_a0 GPMC Address 0. Only used to effectively address 8-bit data nonmultiplexed memories O R6 / P4 gpmc_a1 GPMC address 1 in A/D nonmultiplexed mode and Address 17 in A/D multiplexed mode O T9 / P1 gpmc_a2 GPMC address 2 in A/D nonmultiplexed mode and Address 18 in A/D multiplexed mode O T6 / N1 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-8. GPMC Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpmc_a3 DESCRIPTION GPMC address 3 in A/D nonmultiplexed mode and Address 19 in A/D multiplexed mode O T7 / M4 gpmc_a4 GPMC address 4 in A/D nonmultiplexed mode and Address 20 in A/D multiplexed mode O P6 gpmc_a5 GPMC address 5 in A/D nonmultiplexed mode and Address 21 in A/D multiplexed mode O R9 gpmc_a6 GPMC address 6 in A/D nonmultiplexed mode and Address 22 in A/D multiplexed mode O R5 gpmc_a7 GPMC address 7 in A/D nonmultiplexed mode and Address 23 in A/D multiplexed mode O P5 gpmc_a8 GPMC address 8 in A/D nonmultiplexed mode and Address 24 in A/D multiplexed mode O N7 gpmc_a9 GPMC address 9 in A/D nonmultiplexed mode and Address 25 in A/D multiplexed mode O R4 gpmc_a10 GPMC address 10 in A/D nonmultiplexed mode and Address 26 in A/D multiplexed mode O N9 gpmc_a11 GPMC address 11 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O P9 gpmc_a12 GPMC address 12 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O P4 gpmc_a13 GPMC address 13 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O R3 / K7 gpmc_a14 GPMC address 14 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O T2 / M7 gpmc_a15 GPMC address 15 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O U2 / J5 gpmc_a16 GPMC address 16 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O U1 / K6 gpmc_a17 GPMC address 17 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O P3 / J7 gpmc_a18 GPMC address 18 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O R2 / J4 gpmc_a19 GPMC address 19 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O K7 / J6 gpmc_a20 GPMC address 20 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O M7 / H4 gpmc_a21 GPMC address 21 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O J5 / H5 gpmc_a22 GPMC address 22 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O K6 / H6 gpmc_a23 GPMC address 23 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O J7/ AG5/ N1 gpmc_a24 GPMC address 24 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O J4 / AF2 gpmc_a25 GPMC address 25 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O J6 / AF6 gpmc_a26 GPMC address 26 in A/D nonmultiplexed mode and unused in A/D multiplexed mode O H4 / AF3 gpmc_a27 GPMC address 27 in A/D nonmultiplexed mode and Address 27 in A/D multiplexed mode O H5 / AF4 gpmc_cs0 GPMC Chip Select 0 (active low) O T1 gpmc_cs1 GPMC Chip Select 1 (active low) O H6 gpmc_cs2 GPMC Chip Select 2 (active low) O P2 gpmc_cs3 GPMC Chip Select 3 (active low) O P1 gpmc_cs4 GPMC Chip Select 4 (active low) O N6 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 111 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-8. GPMC Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpmc_cs5 GPMC Chip Select 5 (active low) O M4 gpmc_cs6 GPMC Chip Select 6 (active low) O N1 gpmc_cs7 GPMC Chip Select 7 (active low) O P7 GPMC Clock output IO P7 gpmc_advn_ale GPMC address valid active low or address latch enable O N1 gpmc_oen_ren GPMC output enable active low or read enable O M5 gpmc_wen GPMC write enable active low O M3 gpmc_ben0 GPMC lower-byte enable active low O N6 gpmc_ben1 GPMC upper-byte enable active low O M4 gpmc_wait0 GPMC external indication of wait 0 I N2 gpmc_wait1 GPMC external indication of wait 1 I P7 / N1 gpmc_clk(1)(2) DESCRIPTION (1) This clock signal is implemented as 'pad loopback' inside the device - the output signal is looped back through the input buffer to serve as the internal reference signal. Series termination is recommended (as close to device pin as possible) to improve signal integrity of the clock input. Any nonmonotonicity in voltage that occurs at the pad loopback clock pin between VIH and VIL must be less than VHYS. (2) The gpio6_16.clkout1 signal can be used as an “always-on” alternative to gpmc_clk provided that the external device can support the associated timing. See Table 7-24 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 1 Load and Table 7-26 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 5 Loads for timing information. 4.4.6 Timers NOTE For more information, see the Timers section of the device TRM. Table 4-9. Timers Signal Descriptions SIGNAL NAME TYPE BALL timer1 DESCRIPTION PWM output/event trigger input IO M4 / E21 timer2 PWM output/event trigger input IO N6 / F20 timer3 PWM output/event trigger input IO N1 / F21 timer4 PWM output/event trigger input IO P7 / D12 timer5 PWM output/event trigger input IO U2 / B12 timer6 PWM output/event trigger input IO T2 / A11 timer7 PWM output/event trigger input IO R3 / B13 timer8 PWM output/event trigger input IO P4 / A12 timer9 PWM output/event trigger input IO P9 / E14 timer10 PWM output/event trigger input IO N9 / A13 timer11 PWM output/event trigger input IO R4 / G14 timer12 PWM output/event trigger input IO N7 / F14 timer13 PWM output/event trigger input IO D18 / AF8 timer14 PWM output/event trigger input IO E17 / AE9 timer15 PWM output/event trigger input IO B26/ AF9/ AC10 timer16 PWM output/event trigger input IO C23/ AD9/ AB10 4.4.7 Inter-Integrated Circuit Interface (I2C) NOTE For more information, see the Serial Communication Interface / Multimaster High-Speed I2C Controller / HS I2C Environment / HS I2C in I2C Mode section of the device TRM. 112 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE I2C1 and I2C2 do NOT support HS-mode. Table 4-10. I2C Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL Inter-Integrated Circuit Interface (I2C1) i2c1_scl I2C1 Clock IOD C20 i2c1_sda I2C1 Data IOD C21 Inter-Integrated Circuit Interface (I2C2) i2c2_scl I2C2 Clock IOD F17 i2c2_sda I2C2 Data IOD C25 Inter-Integrated Circuit Interface (I2C3) i2c3_scl I2C3 Clock IOD P7/ D14/ AB4/ F20 i2c3_sda I2C3 Data IOD N1/ C14/ AC5/ E21 Inter-Integrated Circuit Interface (I2C4) i2c4_scl I2C4 Clock IOD R6/ J14/ A21/ Y9 i2c4_sda I2C4 Data IOD T9/ B14/ C18/ W7 Inter-Integrated Circuit Interface (I2C5) 4.4.8 i2c5_scl I2C5 Clock IOD AB9/ P6/ F12 i2c5_sda I2C5 Data IOD AA3/ R9/ G12 HDQ / 1-Wire Interface (HDQ1W) NOTE For more information, see the Serial Communication Interface / HDQ/1-Wire section of the device TRM. Table 4-11. HDQ / 1-Wire Signal Descriptions SIGNAL NAME hdq0 4.4.9 DESCRIPTION HDQ or 1-wire protocol single interface pin TYPE BALL IOD D18/ C23 Universal Asynchronous Receiver Transmitter (UART) NOTE For more information see the Serial Communication Interface /UART/IrDA/CIR section of the device TRM. Table 4-12. UART Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL Universal Asynchronous Receiver/Transmitter (UART1) uart1_dcdn UART1 Data Carrier Detect active low I D28 uart1_dsrn UART1 Data Set Ready Active Low I D26 uart1_dtrn UART1 Data Terminal Ready Active Low O D27 uart1_rin UART1 Ring Indicator I C28 uart1_rxd UART1 Receive Data I B27 uart1_txd UART1 Transmit Data O C26 uart1_ctsn UART1 clear to send active low I E25 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 113 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-12. UART Signal Descriptions (continued) SIGNAL NAME uart1_rtsn DESCRIPTION UART1 request to send active low TYPE BALL O C27 Universal Asynchronous Receiver/Transmitter (UART2) uart2_rxd UART2 Receive Data I D28 uart2_txd UART2 Transmit Data O D26 uart2_ctsn UART2 clear to send active low I D27 uart2_rtsn UART2 request to send active low O C28 Universal Asynchronous Receiver/Transmitter (UART3)/IrDA uart3_rxd UART3 Receive Data for both normal UART mode and IrDA mode I V2/ AB3/ A26 / D27 uart3_txd UART3 Transmit Data O Y1/ AA4/ B22/ C28 uart3_ctsn UART3 clear to send active low I U4/ W9/ G17/ D28 uart3_rtsn UART3 request to send active low O V1/ V9/ D28/ B24 uart3_rctx Remote control data O D28 uart3_sd Infrared transceiver configure/shutdown O D26 uart3_irtx Infrared data output O C28 Universal Asynchronous Receiver/Transmitter (UART4) uart4_rxd UART4 Receive Data I V7/ G16/ B21 uart4_txd UART4 Transmit Data O U7/ D17/ B20 uart4_ctsn UART4 clear to send active low I V6 uart4_rtsn UART4 request to send active low O U6 Universal Asynchronous Receiver/Transmitter (UART5) uart5_rxd UART5 Receive Data I R6/ F11/ B19/ AC7/ G17 uart5_txd UART5 Transmit Data O T9/ G10/ C17/ AC6/ B24 uart5_ctsn UART5 clear to send active low I T6 / AC9 uart5_rtsn UART5 request to send active low O T7 / AC3 Universal Asynchronous Receiver/Transmitter (UART6) uart6_rxd UART6 Receive Data I P6/ E8/ G12/ W7 uart6_txd UART6 Transmit Data O R9/ D9/ F12/ Y9 uart6_ctsn UART6 clear to send active low I R5 / G13 uart6_rtsn UART6 request to send active low O P5 / J11 Universal Asynchronous Receiver/Transmitter (UART7) uart7_rxd UART7 Receive Data I T6/ AD9/ B7/ B18 uart7_txd UART7 Transmit Data O T7/ AF9/ B8/ F15 uart7_ctsn UART7 clear to send active low I AE9 / B19 uart7_rtsn UART7 request to send active low O AF8 / C17 Universal Asynchronous Receiver/Transmitter (UART8) uart8_rxd UART8 Receive Data I AE8/ R5/ C18/ G20 uart8_txd UART8 Transmit Data O AD8/ P5/ A21/ G19 uart8_ctsn UART8 clear to send active low I AG7 / G16 uart8_rtsn UART8 request to send active low O AH6 / D17 Universal Asynchronous Receiver/Transmitter (UART9) uart9_rxd UART9 Receive Data I G1/ AA3/ E25 uart9_txd UART9 Transmit Data O G6/ AB9/ C27 uart9_ctsn UART9 clear to send active low I F2 / AB3 uart9_rtsn UART9 request to send active low O F3/ AA4 I D1/ E21/ AC8/ D27 Universal Asynchronous Receiver/Transmitter (UART10) uart10_rxd 114 UART10 Receive Data Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-12. UART Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL O E2/ F20/ AD6/ C28 UART10 clear to send active low I D2 / AB8 UART10 request to send active low O F4 / AB5 uart10_txd UART10 Transmit Data uart10_ctsn uart10_rtsn 4.4.10 Multichannel Serial Peripheral Interface (McSPI) CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are applicable for all combinations of signals for SPI1 and SPI2. However, the timings are valid only for SPI3 and SPI4 if signals within a single IOSET are used. The IOSETS are defined in the Table 7-43. NOTE For more information, see the Serial Communication Interface / Multichannel Serial Peripheral Interface (MCSPI) section of the device TRM. Table 4-13. SPI Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL A25 Serial Peripheral Interface 1 spi1_sclk(1) SPI1 Clock IO spi1_d1 SPI1 Data. Can be configured as either MISO or MOSI. IO F16 spi1_d0 SPI1 Data. Can be configured as either MISO or MOSI. IO B25 spi1_cs0 SPI1 Chip Select IO A24 spi1_cs1 SPI1 Chip Select IO A22 spi1_cs2 SPI1 Chip Select IO B21 spi1_cs3 SPI1 Chip Select IO B20 Serial Peripheral Interface 2 spi2_sclk(1) SPI2 Clock IO A26 spi2_d1 SPI2 Data. Can be configured as either MISO or MOSI. IO B22 spi2_d0 SPI2 Data. Can be configured as either MISO or MOSI. IO G17 spi2_cs0 SPI2 Chip Select IO B24 spi2_cs1 SPI2 Chip Select IO A22 spi2_cs2 SPI2 Chip Select IO B21 spi2_cs3 SPI2 Chip Select IO B20 SPI3 Clock IO AD9/ V2/ B12/ E11/ AC4/ C18 spi3_d1 SPI3 Data. Can be configured as either MISO or MOSI. IO AF9/ Y1/ B10/ A11/ A21/ AC7 spi3_d0 SPI3 Data. Can be configured as either MISO or MOSI. IO AE9/ W9/ C11/ B13/ AC6/ G16 spi3_cs0 SPI3 Chip Select IO AF8/ V9/ D11/ A12/ AC9/ D17 spi3_cs1 SPI3 Chip Select IO B11/ AC3/ E14 spi3_cs2 SPI3 Chip Select IO F11 spi3_cs3 SPI3 Chip Select IO A10 Serial Peripheral Interface 3 spi3_sclk(1) Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 115 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-13. SPI Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL SPI4 Clock IO N7/ G1/ AA3/ V7/ AC8 spi4_d1 SPI4 Data. Can be configured as either MISO or MOSI. IO R4/ G6/ AB9/ U7/ AD6 spi4_d0 SPI4 Data. Can be configured as either MISO or MOSI. IO N9/ F2/ AB3/ V6/ AB8 spi4_cs0 SPI4 Chip Select IO P9/ F3/ AA4/ U6/ AB5 spi4_cs1 SPI4 Chip Select IO P4 / Y1 spi4_cs2 SPI4 Chip Select IO R3 / W9 spi4_cs3 SPI4 Chip Select IO T2 / V9 Serial Peripheral Interface 4 spi4_sclk(1) (1) This clock signal is implemented as 'pad loopback' inside the device - the output signal is looped back through the input buffer to serve as the internal reference signal. Series termination is recommended (as close to device pin as possible) to improve signal integrity of the clock input. Any non-monotonicity in voltage that occurs at the pad loopback clock pin between VIH and VIL must be less than VHYS. 4.4.11 Quad Serial Peripheral Interface (QSPI) NOTE For more information see the Serial Communication Interface / Quad Serial Peripheral Interface section of the device TRM. Table 4-14. QSPI Signal Descriptions SIGNAL NAME TYPE BALL qspi1_sclk DESCRIPTION QSPI1 Serial Clock O R2 qspi1_rtclk QSPI1 Return Clock Input.Must be connected from QSPI1_SCLK on PCB. Refer to PCB Guidelines for QSPI1 I R3 qspi1_d0 QSPI1 Data[0]. This pin is output data for all commands/writes and for dual read and quad read modes it becomes input data pin during read phase. IO U1 qspi1_d1 QSPI1 Data[1]. Input read data in all modes I P3 qspi1_d2 QSPI1 Data[2]. This pin is used only in quad read mode as input data pin during read phase I U2 qspi1_d3 QSPI1 Data[3]. This pin is used only in quad read mode as input data pin during read phase I T2 qspi1_cs0 QSPI1 Chip Select[0]. This pin is Used for QSPI1 boot modes O P2 qspi1_cs1 QSPI1 Chip Select[1] O P1 qspi1_cs2 QSPI1 Chip Select[2] O T7 qspi1_cs3 QSPI1 Chip Select[3] O P6 4.4.12 Multichannel Audio Serial Port (McASP) NOTE For more information, see the Serial Communication Interface / Multichannel Audio Serial Port (MCASP) section of the device TRM. Table 4-15. MCASP Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL IO G12 Multichannel Audio Serial Port 1 mcasp1_axr0 116 MCASP1 Transmit/Receive Data Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-15. MCASP Signal Descriptions (continued) SIGNAL NAME TYPE BALL mcasp1_axr1 MCASP1 Transmit/Receive Data IO F12 mcasp1_axr2 MCASP1 Transmit/Receive Data IO G13 mcasp1_axr3 MCASP1 Transmit/Receive Data IO J11 mcasp1_axr4 MCASP1 Transmit/Receive Data IO D18/ E12 mcasp1_axr5 MCASP1 Transmit/Receive Data IO E17 / F13 mcasp1_axr6 MCASP1 Transmit/Receive Data IO B26 / C12 mcasp1_axr7 MCASP1 Transmit/Receive Data IO C23 / D12 mcasp1_axr8 MCASP1 Transmit/Receive Data IO E21 / B12 mcasp1_axr9 MCASP1 Transmit/Receive Data IO F20/ A11 mcasp1_axr10 MCASP1 Transmit/Receive Data IO F21 / B13 mcasp1_axr11 MCASP1 Transmit/Receive Data IO A12 mcasp1_axr12 MCASP1 Transmit/Receive Data IO E14 mcasp1_axr13 MCASP1 Transmit/Receive Data IO A13 mcasp1_axr14 MCASP1 Transmit/Receive Data IO G14 mcasp1_axr15 MCASP1 Transmit/Receive Data IO F14 mcasp1_fsx MCASP1 Transmit Frame Sync IO D14 MCASP1 Receive Bit Clock IO B14 mcasp1_aclkr (1) mcasp1_fsr DESCRIPTION MCASP1 Receive Frame Sync IO J14 mcasp1_ahclkx MCASP1 Transmit High-Frequency Master Clock O D18 mcasp1_aclkx(1) MCASP1 Transmit Bit Clock IO C14 B15 Multichannel Audio Serial Port 2 mcasp2_axr0 MCASP2 Transmit/Receive Data IO mcasp2_axr1 MCASP2 Transmit/Receive Data IO A15 mcasp2_axr2 MCASP2 Transmit/Receive Data IO C15 mcasp2_axr3 MCASP2 Transmit/Receive Data IO A16 mcasp2_axr4 MCASP2 Transmit/Receive Data IO D15 mcasp2_axr5 MCASP2 Transmit/Receive Data IO B16 mcasp2_axr6 MCASP2 Transmit/Receive Data IO B17 mcasp2_axr7 MCASP2 Transmit/Receive Data IO A17 mcasp2_axr8 MCASP2 Transmit/Receive Data IO D18 mcasp2_axr9 MCASP2 Transmit/Receive Data IO E17 mcasp2_axr10 MCASP2 Transmit/Receive Data IO B26 mcasp2_axr11 MCASP2 Transmit/Receive Data IO C23 mcasp2_axr12 MCASP2 Transmit/Receive Data IO B18 mcasp2_axr13 MCASP2 Transmit/Receive Data IO F15 mcasp2_axr14 MCASP2 Transmit/Receive Data IO B19 mcasp2_axr15 MCASP2 Transmit/Receive Data IO C17 mcasp2_fsx MCASP2 Transmit Frame Sync IO A18 MCASP2 Receive Bit Clock IO E15 MCASP2 Receive Frame Sync IO A20 MCASP2 Transmit High-Frequency Master Clock O E17 MCASP2 Transmit Bit Clock IO A19 mcasp2_aclkr(1) mcasp2_fsr mcasp2_ahclkx (1) mcasp2_aclkx Multichannel Audio Serial Port 3 mcasp3_axr0 MCASP3 Transmit/Receive Data IO B19 mcasp3_axr1 MCASP3 Transmit/Receive Data IO C17 mcasp3_axr2 MCASP3 Transmit/Receive Data IO C15 mcasp3_axr3 MCASP3 Transmit/Receive Data IO A16 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 117 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-15. MCASP Signal Descriptions (continued) SIGNAL NAME mcasp3_fsx DESCRIPTION MCASP3 Transmit Frame Sync TYPE BALL IO F15 mcasp3_ahclkx MCASP3 Transmit High-Frequency Master Clock O B26 mcasp3_aclkx(1) MCASP3 Transmit Bit Clock IO B18 mcasp3_aclkr(1) MCASP3 Receive Bit Clock IO B18 MCASP3 Receive Frame Sync IO F15 mcasp3_fsr Multichannel Audio Serial Port 4 mcasp4_axr0 MCASP4 Transmit/Receive Data IO G16 mcasp4_axr1 MCASP4 Transmit/Receive Data IO D17 mcasp4_axr2 MCASP4 Transmit/Receive Data IO E12 mcasp4_axr3 MCASP4 Transmit/Receive Data IO F13 mcasp4_fsx MCASP4 Transmit Frame Sync IO A21 mcasp4_ahclkx MCASP4 Transmit High-Frequency Master Clock O C23 mcasp4_aclkx(1) MCASP4 Transmit Bit Clock IO C18 mcasp4_aclkr(1) MCASP4 Receive Bit Clock IO C18 MCASP4 Receive Frame Sync IO A21 mcasp4_fsr Multichannel Audio Serial Port 5 mcasp5_axr0 MCASP5 Transmit/Receive Data IO AB3 mcasp5_axr1 MCASP5 Transmit/Receive Data IO AA4 mcasp5_axr2 MCASP5 Transmit/Receive Data IO C12 mcasp5_axr3 MCASP5 Transmit/Receive Data IO D12 mcasp5_fsx MCASP5 Transmit Frame Sync IO AB9 mcasp5_ahclkx MCASP5 Transmit High-Frequency Master Clock O D18 mcasp5_aclkx(1) MCASP5 Transmit Bit Clock IO AA3 mcasp5_aclkr(1) MCASP5 Receive Bit Clock IO AA3 MCASP5 Receive Frame Sync IO AB9 B12 mcasp5_fsr Multichannel Audio Serial Port 6 mcasp6_axr0 MCASP6 Transmit/Receive Data IO mcasp6_axr1 MCASP6 Transmit/Receive Data IO A11 mcasp6_axr2 MCASP6 Transmit/Receive Data IO G13 mcasp6_axr3 MCASP6 Transmit/Receive Data IO J11 mcasp6_ahclkx MCASP6 Transmit High-Frequency Master Clock O E17 mcasp6_aclkx(1) MCASP6 Transmit Bit Clock IO B13 MCASP6 Transmit Frame Sync IO A12 MCASP6 Receive Bit Clock IO B13 MCASP6 Receive Frame Sync IO A12 mcasp6_fsx mcasp6_aclkr(1) mcasp6_fsr Multichannel Audio Serial Port 7 mcasp7_axr0 MCASP7 Transmit/Receive Data IO E14 mcasp7_axr1 MCASP7 Transmit/Receive Data IO A13 mcasp7_axr2 MCASP7 Transmit/Receive Data IO B14 mcasp7_axr3 MCASP7 Transmit/Receive Data IO J14 mcasp7_ahclkx MCASP7 Transmit High-Frequency Master Clock O B26 mcasp7_aclkx(1) MCASP7 Transmit Bit Clock IO G14 MCASP7 Transmit Frame Sync IO F14 MCASP7 Receive Bit Clock IO G14 MCASP7 Receive Frame Sync IO F14 IO D15 mcasp7_fsx mcasp7_aclkr(1) mcasp7_fsr Multichannel Audio Serial Port 8 mcasp8_axr0 118 MCASP8 Transmit/Receive Data Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-15. MCASP Signal Descriptions (continued) SIGNAL NAME TYPE BALL mcasp8_axr1 DESCRIPTION MCASP8 Transmit/Receive Data IO B16 mcasp8_axr2 MCASP8 Transmit/Receive Data IO E15 mcasp8_axr3 MCASP8 Transmit/Receive Data IO A20 mcasp8_ahclkx MCASP8 Transmit High-Frequency Master Clock O C23 mcasp8_aclkx(1) MCASP8 Transmit Bit Clock IO B17 MCASP8 Transmit Frame Sync IO A17 MCASP8 Receive Bit Clock IO B17 MCASP8 Receive Frame Sync IO A17 mcasp8_fsx mcasp8_aclkr(1) mcasp8_fsr (1) This clock signal is implemented as 'pad loopback' inside the device - the output signal is looped back through the input buffer to serve as the internal reference signal. Series termination is recommended (as close to device pin as possible) to improve signal integrity of the clock input. Any non-monotonicity in voltage that occurs at the pad loopback clock pin between VIH and VIL must be less than VHYS. 4.4.13 Universal Serial Bus (USB) NOTE For more information, see: Serial Communication Interface / SuperSpeed USB DRD Subsystem section of the device TRM. Table 4-16. Universal Serial Bus Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL Universal Serial Bus 1 usb1_dp USB1 USB2.0 differential signal pair (positive) IO AD12 usb1_dm USB1 USB2.0 differential signal pair (negative) IO AC12 USB1 Drive VBUS signal O AB10 usb_rxn0 USB1 USB3.0 receiver negative lane I AF12 usb_rxp0 USB1 USB3.0 receiver positive lane I AE12 usb_txn0 USB1 USB3.0 transmitter negative lane O AC11 usb_txp0 USB1 USB3.0 transmitter positive lane O AD11 usb2_dp USB2 USB2.0 differential signal pair (positive) IO AE11 usb2_dm USB2 USB2.0 differential signal pair (negative) IO AF11 USB2 Drive VBUS signal O AC10 usb3_ulpi_d0 USB3 - ULPI 8-bit data bus IO AC3 / AE1 usb3_ulpi_d1 USB3 - ULPI 8-bit data bus IO AC9 / AE5 usb3_ulpi_d2 USB3 - ULPI 8-bit data bus IO AC6 / AE3 usb3_ulpi_d3 USB3 - ULPI 8-bit data bus IO AC7 / AF1 usb3_ulpi_d4 USB3 - ULPI 8-bit data bus IO AC4 / AF4 usb3_ulpi_d5 USB3 - ULPI 8-bit data bus IO AD4 / AF3 usb3_ulpi_d6 USB3 - ULPI 8-bit data bus IO AB4 / AF6 usb3_ulpi_d7 USB3 - ULPI 8-bit data bus IO AC5 / AF2 usb3_ulpi_nxt USB3 - ULPI next I AC8 / AE2 usb3_ulpi_dir USB3 - ULPI bus direction I AD6 / AE6 usb3_ulpi_stp USB3 - ULPI stop O AB8 / AD2 usb3_ulpi_clk USB3 - ULPI functional clock I AB5 / AD3 usb1_drvvbus Universal Serial Bus 2 usb2_drvvbus Universal Serial Bus 3 Universal Serial Bus 4 usb4_ulpi_d0 usb4_ulpi_d1 USB4 - ULPI 8-bit data bus (1) IO V6 USB4 - ULPI 8-bit data bus (1) IO U6 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 119 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-16. Universal Serial Bus Signal Descriptions (continued) SIGNAL NAME TYPE BALL USB4 - ULPI 8-bit data bus (1) IO U5 usb4_ulpi_d3 USB4 - ULPI 8-bit data bus (1) IO V5 usb4_ulpi_d4 USB4 - ULPI 8-bit data bus (1) IO V4 usb4_ulpi_d5 USB4 - ULPI 8-bit data bus (1) IO V3 usb4_ulpi_d6 USB4 - ULPI 8-bit data bus (1) IO Y2 usb4_ulpi_d7 USB4 - ULPI 8-bit data bus (1) IO W2 usb4_ulpi_nxt USB4 - ULPI next (1) I U7 I V7 usb4_ulpi_d2 DESCRIPTION (1) usb4_ulpi_dir USB4 - ULPI bus direction usb4_ulpi_stp USB4 - ULPI stop (1) O V9 usb4_ulpi_clk USB4 - ULPI functional clock (1) I W9 (1) USB4 will not be supported on some pin-compatible roadmap devices. USB3 will be mapped to these balls instead. Pin compatibility can be maintained in the future by either not using USB4, or via software change to use USB4 on this device, but USB3 on these balls in the future. 4.4.14 SATA NOTE For more information, see the Serial Communication Interfaces / SATA section of the device TRM. Table 4-17. SATA Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL sata1_rxn0 SATA differential negative receiver lane 0 IOS AH9 sata1_rxp0 SATA differential positive receiver lane 0 IOS AG9 sata1_txn0 SATA differential negative transmitter lane 0 ODS AG10 sata1_txp0 SATA differential positive transmitter lane 0 ODS AH10 sata1_led SATA channel activity indicator O A22 / G19 4.4.15 Peripheral Component Interconnect Express (PCIe) NOTE For more information, see the Serial Communication Interfaces / PCIe Controllers and the Shared PHY Component Subsystems / PCIe Shared PHY Susbsytem sections of the device TRM. NOTE In the DRA74x device, the PCIe_SS2 controller is NOT available, and the PCIe_SS1 controller supports only a single lane. The PCIe2_PHY interface signal set (pcie_rxn1/rxp1, pcie_txn1/txp1 in Table 4-18) is NOT supported in the DRA74x device. For more details on the device differentiation, refer to the Table 3-1, Device Comparison. Table 4-18. PCIe Signal Descriptions SIGNAL NAME 120 DESCRIPTION TYPE BALL IOS AG13 pcie_rxn0 PCIe1_PHY_RX Receive Data Lane 0 (negative) - mapped to PCIe_SS1 only. pcie_rxp0 PCIe1_PHY_RX Receive Data Lane 0 (positive) - mapped to PCIe_SS1 only. IOS AH13 pcie_txn0 PCIe1_PHY_TX Transmit Data Lane 0 (negative) - mapped to PCIe_SS1 only. ODS AG14 pcie_txp0 PCIe1_PHY_TX Transmit Data Lane 0 (positive) - mapped to PCIe_SS1 only. ODS AH14 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-18. PCIe Signal Descriptions (continued) SIGNAL NAME TYPE BALL pcie_rxn1(1) DESCRIPTION PCIe2_PHY_RX Receive Data Lane 1 (negative) - mapped to either PCIe_SS1 (dual lane- mode) or PCIe_SS2 (single lane- mode) IOS AG11 pcie_rxp1(1) PCIe2_PHY_RX Receive Data Lane 1 (positive) - mapped to either PCIe_SS1 (dual lane- mode) or PCIe_SS2 (single lane- mode) IOS AH11 pcie_txn1(1) PCIe2_PHY_TX Transmit Data Lane 1 (negative) - mapped to either PCIe_SS1 (dual lane- mode) or PCIe_SS2 (single lane- mode) ODS AG12 pcie_txp1(1) PCIe2_PHY_TX Transmit Data Lane 1 (positive) - mapped to either PCIe_SS1 (dual lane- mode) or PCIe_SS2 (single lane- mode) ODS AH12 ljcb_clkp PCIe1_PHY / PCIe2_PHY shared Reference Clock Input / Output Differential Pair (positive) IODS AG15 ljcb_clkn PCIe1_PHY / PCIe2_PHY shared Reference Clock Input / Output Differential Pair (negative) IODS AH15 (1) This is not applicable for DRA74x devices. 4.4.16 Controller Area Network Interface (DCAN) NOTE For more information, see the Serial Communication Interface / DCAN section of the device TRM. Table 4-19. DCAN Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL DCAN 1 dcan1_tx DCAN1 transmit data pin IO G20 dcan1_rx DCAN1 receive data pin IO G19 / AD17 dcan2_tx DCAN2 transmit data pin IO E21/ B21 dcan2_rx DCAN2 receive data pin IO F20/ AC17/ B20 DCAN 2 4.4.17 Ethernet Interface (GMAC_SW) CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are valid only if signals within a single IOSET are used. The IOSETs are defined in the Table 7-73, Table 7-76, Table 7-81 and Table 7-88. NOTE For more information, see the Serial Communication Interfaces / Ethernet Controller section of the device TRM. Table 4-20. GMAC Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL rgmii0_txc RGMII0 Transmit Clock O W9 rgmii0_txctl RGMII0 Transmit Enable O V9 rgmii0_txd3 RGMII0 Transmit Data O V7 rgmii0_txd2 RGMII0 Transmit Data O U7 rgmii0_txd1 RGMII0 Transmit Data O V6 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 121 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-20. GMAC Signal Descriptions (continued) SIGNAL NAME 122 TYPE BALL rgmii0_txd0 DESCRIPTION RGMII0 Transmit Data O U6 rgmii0_rxc RGMII0 Receive Clock I U5 rgmii0_rxctl RGMII0 Receive Control I V5 rgmii0_rxd3 RGMII0 Receive Data I V4 rgmii0_rxd2 RGMII0 Receive Data I V3 rgmii0_rxd1 RGMII0 Receive Data I Y2 rgmii0_rxd0 RGMII0 Receive Data I W2 rgmii1_txc RGMII1 Transmit Clock O D5 rgmii1_txctl RGMII1 Transmit Enable O C2 rgmii1_txd3 RGMII1 Transmit Data O C3 rgmii1_txd2 RGMII1 Transmit Data O C4 rgmii1_txd1 RGMII1 Transmit Data O B2 rgmii1_txd0 RGMII1 Transmit Data O D6 rgmii1_rxc RGMII1 Receive Clock I C5 rgmii1_rxctl RGMII1 Receive Control I A3 rgmii1_rxd3 RGMII1 Receive Data I B3 rgmii1_rxd2 RGMII1 Receive Data I B4 rgmii1_rxd1 RGMII1 Receive Data I B5 rgmii1_rxd0 RGMII1 Receive Data I A4 mii1_rxd1 MII1 Receive Data I C1 mii1_rxd2 MII1 Receive Data I E4 mii1_rxd3 MII1 Receive Data I F5 mii1_rxd0 MII1 Receive Data I E6 mii1_rxclk MII1 Receive Clock I D5 mii1_rxdv MII1 Receive Data Valid I C2 mii1_txclk MII1 Transmit Clock I C3 mii1_txd0 MII1 Transmit Data O C4 mii1_txd1 MII1 Transmit Data O B2 mii1_txd2 MII1 Transmit Data O D6 mii1_txd3 MII1 Transmit Data O C5 mii1_txer MII1 Transmit Error I A3 mii1_rxer MII1 Receive Data Error I B3 mii1_col MII1 Collision Detect (Sense) I B4 mii1_crs MII1 Carrier Sense I B5 mii1_txen MII1 Transmit Data Enable O A4 mii0_rxd1 MII0 Receive Data I V6 mii0_rxd2 MII0 Receive Data I V9 mii0_rxd3 MII0 Receive Data I W9 mii0_rxd0 MII0 Receive Data I U6 mii0_rxclk MII0 Receive Clock I Y1 mii0_rxdv MII0 Receive Data Valid I V2 mii0_txclk MII0 Transmit Clock I U5 mii0_txd0 MII0 Transmit Data O W2 mii0_txd1 MII0 Transmit Data O Y2 mii0_txd2 MII0 Transmit Data O V4 mii0_txd3 MII0 Transmit Data O V5 mii0_txer MII0 Transmit Error I U4 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-20. GMAC Signal Descriptions (continued) SIGNAL NAME TYPE BALL mii0_rxer DESCRIPTION MII0 Receive Data Error I U7 mii0_col MII0 Collision Detect (Sense) I V1 mii0_crs MII0 Carrier Sense I V7 mii0_txen MII0 Transmit Data Enable O V3 V2 rmii1_crs RMII1 Carrier Sense I rmii1_rxer RMII1 Receive Data Error I Y1 rmii1_rxd1 RMII1 Receive Data I W9 rmii1_rxd0 RMII1 Receive Data I V9 rmii1_txen RMII1 Transmit Data Enable O U5 rmii1_txd1 RMII1 Transmit Data O V5 rmii1_txd0 RMII1 Transmit Data O V4 rmii0_crs RMII0 Carrier Sense I V7 rmii0_rxer RMII0 Receive Data Error I U7 rmii0_rxd1 RMII0 Receive Data I V6 rmii0_rxd0 RMII0 Receive Data I U6 rmii0_txen RMII0 Transmit Data Enable O V3 rmii0_txd1 RMII0 Transmit Data O Y2 rmii0_txd0 RMII0 Transmit Data O W2 mdio_mclk Management Data Serial Clock O AC5 / V1 / B21 / D3 Management Data IO AB4 / U4 / B20 / F6 mdio_d 4.4.18 Media Local Bus (MLB) Interface NOTE MLB in 6-pin mode may require pullups/ pulldowns on SIG and DAT bus signals. For additional details, please consult the MLB bus interface specification. NOTE For more information, see the Serial Communication Interface / Media Local Bus (MLB) section of the device TRM. Table 4-21. MLB Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL mlb_sig Media Local Bus (MLB) Subsystem signal IO AB3 mlb_dat Media Local Bus (MLB) Subsystem data IO AA4 mlb_clk Media Local Bus (MLB) Subsystem clock I AA3 mlbp_sig_p Media Local Bus (MLB) Subsystem signal differential pair (positive) IODS AC1 mlbp_sig_n Media Local Bus (MLB) Subsystem signal differential pair (negative) IODS AC2 mlbp_dat_p Media Local Bus (MLB) Subsystem data differential pair (positive) IODS AA1 mlbp_dat_n Media Local Bus (MLB) Subsystem data differential pair (negative) IODS AA2 mlbp_clk_p Media Local Bus (MLB) Subsystem clock differential pair (positive) IOS AB1 mlbp_clk_n Media Local Bus (MLB) Subsystem clock differential pair (negative) IOS AB2 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 123 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 4.4.19 eMMC/SD/SDIO NOTE For more information, see the HS MMC/SDIO section of the device TRM. Table 4-22. eMMC/SD/SDIO Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL Multi Media Card 1 mmc1_clk(1) MMC1 clock IO W6 mmc1_cmd MMC1 command IO Y6 W7 mmc1_sdcd MMC1 Card Detect I mmc1_sdwp MMC1 Write Protect I Y9 mmc1_dat0 MMC1 data bit 0 IO AA6 mmc1_dat1 MMC1 data bit 1 IO Y4 mmc1_dat2 MMC1 data bit 2 IO AA5 mmc1_dat3 MMC1 data bit 3 IO Y3 mmc2_clk(1) MMC2 clock IO J7 mmc2_cmd MMC2 command IO H6 mmc2_sdcd MMC2 Card Detect I G20 mmc2_sdwp MMC2 Write Protect I G19 mmc2_dat0 MMC2 data bit 0 IO J4 mmc2_dat1 MMC2 data bit 1 IO J6 mmc2_dat2 MMC2 data bit 2 IO H4 mmc2_dat3 MMC2 data bit 3 IO H5 mmc2_dat4 MMC2 data bit 4 IO K7 mmc2_dat5 MMC2 data bit 5 IO M7 mmc2_dat6 MMC2 data bit 6 IO J5 mmc2_dat7 MMC2 data bit 7 IO K6 mmc3_clk(1) MMC3 clock IO AD4 mmc3_cmd MMC3 command IO AC4 mmc3_sdcd MMC3 Card Detect I B21 mmc3_sdwp MMC3 Write Protect I B20 mmc3_dat0 MMC3 data bit 0 IO AC7 mmc3_dat1 MMC3 data bit 1 IO AC6 mmc3_dat2 MMC3 data bit 2 IO AC9 mmc3_dat3 MMC3 data bit 3 IO AC3 mmc3_dat4 MMC3 data bit 4 IO AC8 mmc3_dat5 MMC3 data bit 5 IO AD6 mmc3_dat6 MMC3 data bit 6 IO AB8 mmc3_dat7 MMC3 data bit 7 IO AB5 Multi Media Card 2 Multi Media Card 3 Multi Media Card 4 124 mmc4_sdcd MMC4 Card Detect I B27 mmc4_sdwp MMC4 Write Protect I C26 mmc4_clk(1) MMC4 clock IO E25 mmc4_cmd MMC4 command IO C27 mmc4_dat0 MMC4 data bit 0 IO D28 mmc4_dat1 MMC4 data bit 1 IO D26 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-22. eMMC/SD/SDIO Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL mmc4_dat2 MMC4 data bit 2 IO D27 mmc4_dat3 MMC4 data bit 3 IO C28 (1) By default, this clock signal is implemented as 'pad loopback' inside the device - the output signal is looped back through the input buffer to serve as the internal reference signal. mmc1_clk and mmc2_clk have an optional software programmable setting to use an 'internal loopback clock' instead of the default 'pad loopback clock'. If the 'pad loopback clock' is used, series termination is recommended (as close to device pin as possible) to improve signal integrity of the clock input. Any non-monotonicity in voltage that occurs at the pad loopback clock pin between VIH and VIL must be less than VHYS. 4.4.20 General-Purpose Interface (GPIO) NOTE For more information, see the General-Purpose Interface section of the device TRM. Table 4-23. GPIOs Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL GPIO 1 gpio1_0 General-Purpose Input I AD17 gpio1_1 General-Purpose Input I AC17 gpio1_2 General-Purpose Input I AB16 gpio1_3 General-Purpose Input I AC16 gpio1_4 General-Purpose Input/Output IO D15 gpio1_5 General-Purpose Input/Output IO A17 gpio1_6 General-Purpose Input/Output IO M6 gpio1_7 General-Purpose Input/Output IO M2 gpio1_8 General-Purpose Input/Output IO L5 gpio1_9 General-Purpose Input/Output IO M1 gpio1_10 General-Purpose Input/Output IO L6 gpio1_11 General-Purpose Input/Output IO L4 gpio1_12 General-Purpose Input/Output IO L3 gpio1_13 General-Purpose Input/Output IO L2 gpio1_14 General-Purpose Input/Output IO G20 gpio1_15 General-Purpose Input/Output IO G19 gpio1_16 General-Purpose Input/Output IO D27 gpio1_17 General-Purpose Input/Output IO C28 gpio1_18 General-Purpose Input/Output IO H1 gpio1_19 General-Purpose Input/Output IO J3 gpio1_20 General-Purpose Input/Output IO H2 gpio1_21 General-Purpose Input/Output IO H3 gpio1_22 General-Purpose Input/Output IO AC8 gpio1_23 General-Purpose Input/Output IO AD6 gpio1_24 General-Purpose Input/Output IO AB8 gpio1_25 General-Purpose Input/Output IO AB5 gpio1_26 General-Purpose Input/Output IO P6 gpio1_27 General-Purpose Input/Output IO R9 gpio1_28 General-Purpose Input/Output IO R5 gpio1_29 General-Purpose Input/Output IO P5 gpio1_30 General-Purpose Input/Output IO N7 gpio1_31 General-Purpose Input/Output IO R4 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 125 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-23. GPIOs Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL GPIO 2 gpio2_0 General-Purpose Input/Output IO N9 gpio2_1 General-Purpose Input/Output IO P9 gpio2_2 General-Purpose Input/Output IO P4 gpio2_3 General-Purpose Input/Output IO R3 gpio2_4 General-Purpose Input/Output IO T2 gpio2_5 General-Purpose Input/Output IO U2 gpio2_6 General-Purpose Input/Output IO U1 gpio2_7 General-Purpose Input/Output IO P3 gpio2_8 General-Purpose Input/Output IO R2 gpio2_9 General-Purpose Input/Output IO K7 gpio2_10 General-Purpose Input/Output IO M7 gpio2_11 General-Purpose Input/Output IO J5 gpio2_12 General-Purpose Input/Output IO K6 gpio2_13 General-Purpose Input/Output IO J7 gpio2_14 General-Purpose Input/Output IO J4 gpio2_15 General-Purpose Input/Output IO J6 gpio2_16 General-Purpose Input/Output IO H4 gpio2_17 General-Purpose Input/Output IO H5 gpio2_18 General-Purpose Input/Output IO H6 gpio2_19 General-Purpose Input/Output IO T1 gpio2_20 General-Purpose Input/Output IO P2 gpio2_21 General-Purpose Input/Output IO P1 gpio2_22 General-Purpose Input/Output IO P7 gpio2_23 General-Purpose Input/Output IO N1 gpio2_24 General-Purpose Input/Output IO M5 gpio2_25 General-Purpose Input/Output IO M3 gpio2_26 General-Purpose Input/Output IO N6 gpio2_27 General-Purpose Input/Output IO M4 gpio2_28 General-Purpose Input/Output IO N2 gpio2_29 General-Purpose Input/Output IO B17 gpio2_30 General-Purpose Input/Output IO AG8 gpio2_31 General-Purpose Input/Output IO AH7 gpio3_0 General-Purpose Input/Output IO AD9 gpio3_1 General-Purpose Input/Output IO AF9 gpio3_2 General-Purpose Input/Output IO AE9 gpio3_3 General-Purpose Input/Output IO AF8 gpio3_4 General-Purpose Input/Output IO AE8 gpio3_5 General-Purpose Input/Output IO AD8 gpio3_6 General-Purpose Input/Output IO AG7 gpio3_7 General-Purpose Input/Output IO AH6 gpio3_8 General-Purpose Input/Output IO AH3 gpio3_9 General-Purpose Input/Output IO AH5 gpio3_10 General-Purpose Input/Output IO AG6 gpio3_11 General-Purpose Input/Output IO AH4 gpio3_12 General-Purpose Input/Output IO AG4 GPIO 3 126 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-23. GPIOs Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpio3_13 DESCRIPTION General-Purpose Input/Output IO AG2 gpio3_14 General-Purpose Input/Output IO AG3 gpio3_15 General-Purpose Input/Output IO AG5 gpio3_16 General-Purpose Input/Output IO AF2 gpio3_17 General-Purpose Input/Output IO AF6 gpio3_18 General-Purpose Input/Output IO AF3 gpio3_19 General-Purpose Input/Output IO AF4 gpio3_20 General-Purpose Input/Output IO AF1 gpio3_21 General-Purpose Input/Output IO AE3 gpio3_22 General-Purpose Input/Output IO AE5 gpio3_23 General-Purpose Input/Output IO AE1 gpio3_24 General-Purpose Input/Output IO AE2 gpio3_25 General-Purpose Input/Output IO AE6 gpio3_26 General-Purpose Input/Output IO AD2 gpio3_27 General-Purpose Input/Output IO AD3 gpio3_28 General-Purpose Input/Output IO E1 gpio3_29 General-Purpose Input/Output IO G2 gpio3_30 General-Purpose Input/Output IO H7 gpio3_31 General-Purpose Input/Output IO G1 gpio4_0 General-Purpose Input/Output IO G6 gpio4_1 General-Purpose Input/Output IO F2 gpio4_2 General-Purpose Input/Output IO F3 gpio4_3 General-Purpose Input/Output IO D1 gpio4_4 General-Purpose Input/Output IO E2 gpio4_5 General-Purpose Input/Output IO D2 gpio4_6 General-Purpose Input/Output IO F4 gpio4_7 General-Purpose Input/Output IO C1 gpio4_8 General-Purpose Input/Output IO E4 gpio4_9 General-Purpose Input/Output IO F5 gpio4_10 General-Purpose Input/Output IO E6 gpio4_11 General-Purpose Input/Output IO D3 gpio4_12 General-Purpose Input/Output IO F6 gpio4_13 General-Purpose Input/Output IO D5 gpio4_14 General-Purpose Input/Output IO C2 gpio4_15 General-Purpose Input/Output IO C3 gpio4_16 General-Purpose Input/Output IO C4 gpio4_17 General-Purpose Input/Output IO A12 gpio4_18 General-Purpose Input/Output IO E14 gpio4_19 General-Purpose Input/Output IO D11 gpio4_20 General-Purpose Input/Output IO B10 gpio4_21 General-Purpose Input/Output IO B11 gpio4_22 General-Purpose Input/Output IO C11 gpio4_23 General-Purpose Input/Output IO E11 gpio4_24 General-Purpose Input/Output IO B2 gpio4_25 General-Purpose Input/Output IO D6 gpio4_26 General-Purpose Input/Output IO C5 GPIO 4 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 127 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-23. GPIOs Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpio4_27 DESCRIPTION General-Purpose Input/Output IO A3 gpio4_28 General-Purpose Input/Output IO B3 gpio4_29 General-Purpose Input/Output IO B4 gpio4_30 General-Purpose Input/Output IO B5 gpio4_31 General-Purpose Input/Output IO A4 gpio5_0 General-Purpose Input/Output IO B14 gpio5_1 General-Purpose Input/Output IO J14 gpio5_2 General-Purpose Input/Output IO G12 gpio5_3 General-Purpose Input/Output IO F12 gpio5_4 General-Purpose Input/Output IO G13 gpio5_5 General-Purpose Input/Output IO J11 gpio5_6 General-Purpose Input/Output IO E12 gpio5_7 General-Purpose Input/Output IO F13 gpio5_8 General-Purpose Input/Output IO C12 gpio5_9 General-Purpose Input/Output IO D12 gpio5_10 General-Purpose Input/Output IO B12 gpio5_11 General-Purpose Input/Output IO A11 gpio5_12 General-Purpose Input/Output IO B13 gpio5_13 General-Purpose Input/Output IO B18 gpio5_14 General-Purpose Input/Output IO F15 gpio5_15 General-Purpose Input/Output IO V1 gpio5_16 General-Purpose Input/Output IO U4 gpio5_17 General-Purpose Input/Output IO U3 gpio5_18 General-Purpose Input/Output IO V2 gpio5_19 General-Purpose Input/Output IO Y1 gpio5_20 General-Purpose Input/Output IO W9 gpio5_21 General-Purpose Input/Output IO V9 gpio5_22 General-Purpose Input/Output IO V7 gpio5_23 General-Purpose Input/Output IO U7 gpio5_24 General-Purpose Input/Output IO V6 gpio5_25 General-Purpose Input/Output IO U6 gpio5_26 General-Purpose Input/Output IO U5 gpio5_27 General-Purpose Input/Output IO V5 gpio5_28 General-Purpose Input/Output IO V4 gpio5_29 General-Purpose Input/Output IO V3 gpio5_30 General-Purpose Input/Output IO Y2 gpio5_31 General-Purpose Input/Output IO W2 gpio6_4 General-Purpose Input/Output IO A13 gpio6_5 General-Purpose Input/Output IO G14 gpio6_6 General-Purpose Input/Output IO F14 gpio6_7 General-Purpose Input/Output IO B16 gpio6_8 General-Purpose Input/Output IO C15 GPIO 5 GPIO 6 128 gpio6_9 General-Purpose Input/Output IO A16 gpio6_10 General-Purpose Input/Output IO AC5 gpio6_11 General-Purpose Input/Output IO AB4 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-23. GPIOs Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpio6_12 DESCRIPTION General-Purpose Input/Output IO AB10 gpio6_13 General-Purpose Input/Output IO AC10 gpio6_14 General-Purpose Input/Output IO E21 gpio6_15 General-Purpose Input/Output IO F20 gpio6_16 General-Purpose Input/Output IO F21 gpio6_17 General-Purpose Input/Output IO D18 gpio6_18 General-Purpose Input/Output IO E17 gpio6_19 General-Purpose Input/Output IO B26 gpio6_20 General-Purpose Input/Output IO C23 gpio6_21 General-Purpose Input/Output IO W6 gpio6_22 General-Purpose Input/Output IO Y6 gpio6_23 General-Purpose Input/Output IO AA6 gpio6_24 General-Purpose Input/Output IO Y4 gpio6_25 General-Purpose Input/Output IO AA5 gpio6_26 General-Purpose Input/Output IO Y3 gpio6_27 General-Purpose Input/Output IO W7 gpio6_28 General-Purpose Input/Output IO Y9 gpio6_29 General-Purpose Input/Output IO AD4 gpio6_30 General-Purpose Input/Output IO AC4 gpio6_31 General-Purpose Input/Output IO AC7 gpio7_0 General-Purpose Input/Output IO AC6 gpio7_1 General-Purpose Input/Output IO AC9 gpio7_2 General-Purpose Input/Output IO AC3 gpio7_3 General-Purpose Input/Output IO R6 gpio7_4 General-Purpose Input/Output IO T9 gpio7_5 General-Purpose Input/Output IO T6 gpio7_6 General-Purpose Input/Output IO T7 gpio7_7 General-Purpose Input/Output IO A25 gpio7_8 General-Purpose Input/Output IO F16 gpio7_9 General-Purpose Input/Output IO B25 gpio7_10 General-Purpose Input/Output IO A24 gpio7_11 General-Purpose Input/Output IO A22 gpio7_12 General-Purpose Input/Output IO B21 gpio7_13 General-Purpose Input/Output IO B20 gpio7_14 General-Purpose Input/Output IO A26 gpio7_15 General-Purpose Input/Output IO B22 gpio7_16 General-Purpose Input/Output IO G17 gpio7_17 General-Purpose Input/Output IO B24 gpio7_18 General-Purpose Input/Output IO L1 gpio7_19 General-Purpose Input/Output IO K2 gpio7_22 General-Purpose Input/Output IO B27 gpio7_23 General-Purpose Input/Output IO C26 gpio7_24 General-Purpose Input/Output IO E25 gpio7_25 General-Purpose Input/Output IO C27 gpio7_26 General-Purpose Input/Output IO D28 gpio7_27 General-Purpose Input/Output IO D26 GPIO 7 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 129 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-23. GPIOs Signal Descriptions (continued) SIGNAL NAME TYPE BALL gpio7_28 DESCRIPTION General-Purpose Input/Output IO J1 gpio7_29 General-Purpose Input/Output IO J2 gpio7_30 General-Purpose Input/Output IO D14 gpio7_31 General-Purpose Input/Output IO C14 gpio8_0 General-Purpose Input/Output IO F11 gpio8_1 General-Purpose Input/Output IO G10 gpio8_2 General-Purpose Input/Output IO F10 gpio8_3 General-Purpose Input/Output IO G11 gpio8_4 General-Purpose Input/Output IO E9 gpio8_5 General-Purpose Input/Output IO F9 gpio8_6 General-Purpose Input/Output IO F8 gpio8_7 General-Purpose Input/Output IO E7 gpio8_8 General-Purpose Input/Output IO E8 GPIO 8 gpio8_9 General-Purpose Input/Output IO D9 gpio8_10 General-Purpose Input/Output IO D7 gpio8_11 General-Purpose Input/Output IO D8 gpio8_12 General-Purpose Input/Output IO A5 gpio8_13 General-Purpose Input/Output IO C6 gpio8_14 General-Purpose Input/Output IO C8 gpio8_15 General-Purpose Input/Output IO C7 gpio8_16 General-Purpose Input/Output IO B7 gpio8_17 General-Purpose Input/Output IO B8 gpio8_18 General-Purpose Input/Output IO A7 gpio8_19 General-Purpose Input/Output IO A8 gpio8_20 General-Purpose Input/Output IO C9 gpio8_21 General-Purpose Input/Output IO A9 gpio8_22 General-Purpose Input/Output IO B9 gpio8_23 General-Purpose Input/Output IO A10 gpio8_27 General-Purpose Input I D23 gpio8_28 General-Purpose Input/Output IO F19 gpio8_29 General-Purpose Input/Output IO E18 gpio8_30 General-Purpose Input/Output IO G21 gpio8_31 General-Purpose Input/Output IO D24 4.4.21 Keyboard controller (KBD) NOTE For more information, see Keyboard Controller section of the device TRM. Table 4-24. Keyboard Signal Descriptions SIGNAL NAME 130 TYPE BALL kbd_row0 DESCRIPTION Keypad row 0 I AD9/ E1 kbd_row1 Keypad row 1 I AF9/ G2 kbd_row2 Keypad row 2 I AG4/ G1 kbd_row3 Keypad row 3 I AG2/ G6 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-24. Keyboard Signal Descriptions (continued) SIGNAL NAME TYPE BALL kbd_row4 DESCRIPTION Keypad row 4 I AG3/ F2 kbd_row5 Keypad row 5 I AG5/ F3 kbd_row6 Keypad row 6 I AF2/ D1 kbd_row7 Keypad row 7 I AF6/ F6 kbd_row8 Keypad row 8 I AF3/ C2 kbd_col0 Keypad column 0 O AF4/ E2 kbd_col1 Keypad column 1 O AF1/ D2 kbd_col2 Keypad column 2 O AE3/ F4 kbd_col3 Keypad column 3 O AE5/ C1 kbd_col4 Keypad column 4 O AE1/ E4 kbd_col5 Keypad column 5 O AE2/ F5 kbd_col6 Keypad column 6 O AE6/ E6 kbd_col7 Keypad column 7 O AD2/ D3 kbd_col8 Keypad column 8 O AD3/ D5 4.4.22 Pulse Width Modulation (PWM) Interface NOTE For more information, see the Pulse-Width Modulation (PWM) SS section of the device TRM. Table 4-25. PWM Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL PWMSS1 eQEP1A_in EQEP1 Quadrature Input A I E1 / AD9 eQEP1B_in EQEP1 Quadrature Input B I G2 / AF9 AE9 / H7 eQEP1_index EQEP1 Index Input IO eQEP1_strobe EQEP1 Strobe Input IO G1 / AF8 ehrpwm1A EHRPWM1 Output A O AE8 / G6 ehrpwm1B EHRPWM1 Output B O AD8 / F2 EHRPWM1 Trip Zone Input IO AG7 / F3 ehrpwm1_tripzone_in put eCAP1_in_PWM1_out ECAP1 Capture Iniput / PWM Output IO AH6 / D1 ehrpwm1_synci EHRPWM1 Sync Input I AH3 / E2 ehrpwm1_synco EHRPWM1 Sync Output O AH5 / D2 eQEP2A_in EQEP2 Quadrature Input A I AG6 / F4 eQEP2B_in EQEP2 Quadrature Input B PWMSS2 I AH4 / C1 eQEP2_index EQEP2 Index Input IO AG4 / E4 eQEP2_strobe EQEP2 Strobe Input IO AG2 / F5 ehrpwm2A EHRPWM2 Output A O AC5 / E6 ehrpwm2B EHRPWM2 Output B O AB4 / D3 EHRPWM2 Trip Zone Input IO AD4 / F6 IO AC4 / D5 ehrpwm2_tripzone_in put eCAP2_in_PWM2_out ECAP2 Capture Iniput / PWM Output PWMSS3 eQEP3A_in EQEP3 Quadrature Input A I AC7 / C2 eQEP3B_in EQEP3 Quadrature Input B I AC6 / C3 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 131 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-25. PWM Signal Descriptions (continued) SIGNAL NAME TYPE BALL eQEP3_index DESCRIPTION EQEP3 Index Input IO AC9 / C4 eQEP3_strobe EQEP3 Strobe Input IO AC3 / B2 ehrpwm3A EHRPWM3 Output A O AC8 / D6 ehrpwm3B EHRPWM3 Output B O AD6 / C5 EHRPWM3 Trip Zone Input IO AB8 / A3 IO AB5 / B3 ehrpwm3_tripzone_in put eCAP3_in_PWM3_out ECAP3 Capture Iniput / PWM Output 4.4.23 Audio Tracking Logic (ATL) NOTE For more information, see the Audio Tracking Logic (ATL) section of the device TRM. Table 4-26. ATL Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL atl_clk0 Audio Tracking Logic Clock 0 O D18 atl_clk1 Audio Tracking Logic Clock 1 O E17 atl_clk2 Audio Tracking Logic Clock 2 O B26 atl_clk3 Audio Tracking Logic Clock 3 O C23 4.4.24 Test Interfaces CAUTION The I/O timings provided in Section 7 Timing Requirements and Switching Characteristics are valid only if signals within a single IOSET are used. The IOSETs are defined in the Table 7-152. NOTE For more information, see the On-Chip Debug Support / Debug Ports section of the device TRM. Table 4-27. Debug Signal Descriptions SIGNAL NAME 132 DESCRIPTION tms JTAG test port mode select. An external pullup resistor should be used on this ball. TYPE BALL IO F18 tdi JTAG test data I D23 tdo JTAG test port data O F19 tclk JTAG test clock I E20 trstn JTAG test reset I D20 rtck JTAG return clock O E18 emu0 Emulator pin 0 IO G21 emu1 Emulator pin 1 IO D24 emu2 Emulator pin 2 O F10 emu3 Emulator pin 3 O D7 emu4 Emulator pin 4 O A7 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-27. Debug Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL emu5 Emulator pin 5 O E1 / G11 emu6 Emulator pin 6 O G2 / E9 emu7 Emulator pin 7 O H7 / F9 emu8 Emulator pin 8 O G1 / F8 emu9 Emulator pin 9 O G6 / E7 emu10 Emulator pin 10 O F2 / D8 emu11 Emulator pin 11 O F3 / A5 emu12 Emulator pin 12 O D1 / C6 emu13 Emulator pin 13 O E2 / C8 emu14 Emulator pin 14 O D2 / C7 emu15 Emulator pin 15 O F4 / A8 emu16 Emulator pin 16 O C1 / C9 emu17 Emulator pin 17 O E4 / A9 emu18 Emulator pin 18 O F5 / B9 emu19 Emulator pin 19 O E6 / A10 4.4.25 System and Miscellaneous 4.4.25.1 Sysboot NOTE For more information, see the Initialization (ROM Code) section of the device TRM. Table 4-28. Sysboot Signal Descriptions SIGNAL NAME TYPE BALL sysboot0 DESCRIPTION Boot Mode Configuration 0. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I M6 sysboot1 Boot Mode Configuration 1. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I M2 sysboot2 Boot Mode Configuration 2. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L5 sysboot3 Boot Mode Configuration 3. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I M1 sysboot4 Boot Mode Configuration 4. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L6 sysboot5 Boot Mode Configuration 5. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L4 sysboot6 Boot Mode Configuration 6. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L3 sysboot7 Boot Mode Configuration 7. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L2 sysboot8 Boot Mode Configuration 8. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I L1 sysboot9 Boot Mode Configuration 9. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I K2 sysboot10 Boot Mode Configuration 10. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I J1 sysboot11 Boot Mode Configuration 11. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I J2 sysboot12 Boot Mode Configuration 12. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I H1 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 133 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-28. Sysboot Signal Descriptions (continued) SIGNAL NAME TYPE BALL sysboot13 DESCRIPTION Boot Mode Configuration 13. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I J3 sysboot14 Boot Mode Configuration 14. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I H2 sysboot15 Boot Mode Configuration 15. The value latched on this pin upon porz reset release will determine the boot mode configuration of the device. I H3 4.4.25.2 Power, Reset, and Clock Management (PRCM) NOTE For more information, see PRCM section of the device TRM. Table 4-29. PRCM Signal Descriptions SIGNAL NAME TYPE BALL clkout1 Device Clock output 1. Can be used externally for devices with non-critical timing requirements, or for debug, or as a reference clock on GPMC as described in Table 7-24 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 1 Load and Table 7-26 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 5 Loads. O F21 / P7 clkout2 Device Clock output 2. Can be used externally for devices with non-critical timing requirements, or for debug. O D18 / N1 clkout3 Device Clock output 3. Can be used externally for devices with non-critical timing requirements, or for debug. O C23 rstoutn Reset out (Active low). This pin asserts low in response to any global reset condition on the device. O F23 resetn Device Reset Input I E23 Power on Reset (active low). This pin must be asserted low until all device supplies are valid (see reset sequence/requirements) I F22 xref_clk0 External Reference Clock 0. For Audio and other Peripherals. I D18 xref_clk1 External Reference Clock 1. For Audio and other Peripherals. I E17 xref_clk2 External Reference Clock 2. For Audio and other Peripherals. I B26 xref_clk3 External Reference Clock 3. For Audio and other Peripherals. I C23 xi_osc0 System Oscillator OSC0 Crystal input / LVCMOS clock input. Functions as the input connection to a crystal when the internal oscillator OSC0 is used. Functions as an LVCMOS-compatible input clock when an external oscillator is used. I AE15 xo_osc0 System Oscillator OSC0 Crystal output O AD15 xi_osc1 Auxiliary Oscillator OSC1 Crystal input / LVCMOS clock input. Functions as the input connection to a crystal when the internal oscillator OSC1 is used. Functions as an LVCMOS-compatible input clock when an external oscillator is used I AC15 xo_osc1 Auxiliary Oscillator OSC1 Crystal output O AC13 IO U3 porz DESCRIPTION RMII_MHZ_50_C RMII Reference Clock (50MHz). This pin is an input when external reference is used LK(1) or output when internal reference is used. (1) This clock signal is implemented as 'pad loopback' inside the device - the output signal is looped back through the input buffer to serve as the internal reference signal. Series termination is recommended (as close to device pin as possible) to improve signal integrity of the clock input. Any non-monotonicity in voltage that occurs at the pad loopback clock pin between VIH and VIL must be less than VHYS. 4.4.25.3 Real Time Clock (RTC) Interface NOTE For more information, see the Real Time Clock (RTC) SS section of the device TRM. 134 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-30. RTC Signal Descriptions SIGNAL NAME TYPE BALL Wakeup0 RTC External Wakeup Input 0 I AD17 Wakeup1 RTC External Wakeup Input 1 I AC17 Wakeup2 RTC External Wakeup Input 2 I AB16 Wakeup3 RTC External Wakeup Input 3 I AC16 RTC Power Domain Power-On Reset Input I AB17 I AE14 rtc_porz DESCRIPTION rtc_osc_xi_clkin3 RTC Oscillator Input. Crystal connection to internal RTC oscillator. Functions as an 2 RTC clock input when an external oscillator is used. rtc_osc_xo RTC Oscillator Output O AD14 rtc_iso(1) RTC domain isolation signal. I AF14 on_off RTC Power Enable output pin O Y11 (1) This signal must be kept 0 if device power supplies are not valid during RTC mode and 1 during normal operation. This can typically be achieved by connecting rtc_iso to the same signal driving porz (not rtc_porz) with appropriate voltage level translation if necessary. 4.4.25.4 System Direct Memory Access (SDMA) NOTE For more information, see the DMA Controllers / System DMA section of the device TRM. Table 4-31. SDMA Signal Descriptions SIGNAL NAME TYPE BALL dma_evt1 DESCRIPTION System DMA Event Input 1 I P7 / P4 dma_evt2 System DMA Event Input 2 I N1 / R3 dma_evt3 System DMA Event Input 3 I N6 dma_evt4 System DMA Event Input 4 I M4 4.4.25.5 Interrupt Controllers (INTC) NOTE For more information, see the Interrupt Controllers section of the device TRM. Table 4-32. INTC Signal Descriptions SIGNAL NAME TYPE BALL nmin_dsp DESCRIPTION Non maskable interrupt input, active-low. This pin can be optionally routed to the DSP NMI input or as generic input to the ARM cores. Note that by default this pin has an internal pulldown resistor enabled. This internal pulldown should be disabled or countered by a stronger external pullup resistor before routing to the DSP or ARM processors. I D21 sys_nirq2 External interrupt event to any device INTC I AB16 sys_nirq1 External interrupt event to any device INTC I AC16 4.4.25.6 Observability NOTE For more information, see the Control Module section of the device TRM. Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 135 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-33. Observability Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL obs0 Observation Output 0 O F10 obs1 Observation Output 1 O G11 obs2 Observation Output 2 O E9 obs3 Observation Output 3 O F9 obs4 Observation Output 4 O F8 obs5 Observation Output 5 O D7 obs6 Observation Output 6 O D8 obs7 Observation Output 7 O A5 obs8 Observation Output 8 O C6 obs9 Observation Output 9 O C8 obs10 Observation Output 10 O C7 obs11 Observation Output 11 O A7 obs12 Observation Output 12 O A8 obs13 Observation Output 13 O C9 obs14 Observation Output 14 O A9 obs15 Observation Output 15 O B9 obs16 Observation Output 16 O F10 obs17 Observation Output 17 O G11 obs18 Observation Output 18 O E9 obs19 Observation Output 19 O F9 obs20 Observation Output 20 O F8 obs21 Observation Output 21 O D7 obs22 Observation Output 22 O D8 obs23 Observation Output 23 O A5 obs24 Observation Output 24 O C6 obs25 Observation Output 25 O C8 obs26 Observation Output 26 O C7 obs27 Observation Output 27 O A7 obs28 Observation Output 28 O A8 obs29 Observation Output 29 O C9 obs30 Observation Output 30 O A9 obs31 Observation Output 31 O B9 obs_dmarq1 DMA Request External Observation Output 1 O G11 obs_dmarq2 DMA Request External Observation Output 2 O D8 obs_irq1 IRQ External Observation Output 1 O F10 obs_irq2 IRQ External Observation Output 2 O D7 4.4.26 Power Supplies NOTE For more information, see Power, Reset, and Clock Management / PRCM Subsystem Environment / External Voltage Inputs section of the device TRM. 136 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-34. Power Supply Signal Descriptions SIGNAL NAME DESCRIPTION TYPE BALL vdd Core voltage domain supply PWR H13/ H14/ J17/ J18/ L7/ L8/ N10/ N13/ P11/ P12/ P13/ R11/ R16/ R19/ T13/ T16/ T19/ U8/ U9/ U13/ U16/ V8/ V16 vss Ground GND A1/ A2/ A6/ A14/ A23/ A28/ B1/ D13/ D19/ E13/ E19/ F1/ F7/ G7/ G8/ G9/ H12/ J12/ J15/ J28/ K1/ K4/ K5/ K15/ K24/ K25/ L13/ L14/ M19/ N14/ N15/ N19/ N24/ N25/ P28/ R1/ R12/ R13/ R15/ R21/ T10/ T11/ T12/ T14/ T15/ T17/ T18/ T21/ U15/ U17/ U20/ U21/ V15/ V17/ W1/ W15/ W24/ W25/ W28/ AA8/ AA9/ AA10/ AA14/ AA15/ AA20/ AB14/ AB20/ AD1/ AD24/ AG1/ AH1/ AH2/ AH8/ AH20/ AH28 DSP-EVE voltage domain supply PWR J13/ K10/ K11/ K12/ K13/ L10/ L11/ L12/ M10/ M11/ M12/ M13 vdd_iva IVA voltage domain supply PWR U18/ U19/ V18/ V19 vdd_gpu GPU voltage domain supply PWR U11/ U12/ V10/ V11/ V14/ W10/ W11/ W13 vdd_mpu MPU voltage domain supply PWR K17/ K18/ L15/ L16/ L17/ L18/ L19/ M15/ M16/ M17/ M18/ N17/ N18/ P17/ P18/ R18 vdd_rtc RTC voltage domain supply PWR AB15 DPLL_USB and HS USB1 1.8V analog power supply PWR AA13 HS USB1 and HS USB2 analog ground GND AB11/ AA11 HS USB2 1.8V analog power supply PWR AB12 vdda33v_usb1 HS USB1 3.3V analog power supply. If USB1 is not used, this pin can alternatively be connected to VSS if the following requirements are met: - The usb1_dm/usb1_dp pins are left unconnected - The USB1 PHY is kept powered down PWR AA12 vdda33v_usb2 HS USB2 3.3V analog power supply. If USB2 is not used, this pin can alternatively be connected to VSS if the following requirements are met: - The usb2_dm/usb2_dp pins are left unconnected - The USB2 PHY is kept powered down PWR Y12 vdda_abe_per DPLL_ABE, DPLL_PER, and PER HSDIVIDER analog power supply PWR M14 DPLL_DDR and DDR HSDIVIDER analog power supply PWR P16 DPLL_DEBUG analog power supply PWR N11 DPLL_DSP and DPLL_EVE analog power supply PWR N12 vdd_dspeve vdda_usb1 vssa_usb vdda_usb2 vdda_ddr vdda_debug vdda_dsp_eve vdda_gmac_core DPLL_CORE and CORE HSDIVIDER analog power supply PWR P15 vdda_gpu DPLL_GPU analog power supply PWR R14 vdda_hdmi PLL_HDMI and HDMI analog power supply PWR Y17 vssa_hdmi AE19 / AD19 DPLL_HDMI and HDMI PHY analog ground GND vdda_iva DPLL_IVA analog power supply PWR R17 vdda_pcie DPLL_PCIe_REF and PCIe analog power supply PWR W14 vssa_pcie PCIe analog ground GND AE13 / AD13 Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 137 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 4-34. Power Supply Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL vdda_pcie0 PCIe ch0 RX/TX analog power supply PWR AA17 vdda_pcie1 PCIe ch1 RX/TX analog power supply PWR AA16 vdda_sata DPLL_SATA and SATA RX/TX analog power supply PWR V13 vssa_sata SATA analog ground GND AE10 vdda_usb3 DPLL_USB_OTG_SS and USB3.0 RX/TX analog power supply PWR W12 vssa_usb3 DPLL_USB and USB3.0 RX/TX analog ground GND AD10 vdda_video DPLL_VIDEO1 and DPLL_VIDEO2 analog power supply PWR P14 vssa_video DPLL_VIDEO1 and DPLL_VIDEO2 analog ground GND U14 vdds_mlbp MLBP IO power supply PWR AA7 / Y7 vdda_mpu DPLL_MPU analog power supply PWR N16 vdda_osc HFOSC analog power supply PWR AE16 / AD16 vssa_osc0 OSC0 analog ground GND AF15 vssa_osc1 OSC1 analog ground GND AC14 vdda_rtc RTC bias and RTC LFOSC analog power supply PWR AB13 vdds18v 1.8V power supply PWR W17/ W18/ V21/ V22/ T8/ R8/ P8/ N8/ M8/ M9/ H17/ G18 vdds18v_ddr1 DDR1 bias power supply PWR AA18/ AA19/ Y21/ W21 vdds18v_ddr2 DDR2 bias power supply PWR P20/ P21/ N21/ J21/ J22 vdds_ddr2 DDR2 power supply (1.8V for DDR2 mode / 1.5V for DDR3 mode / 1.35V DDR3L mode) PWR T24/ T25/ M20/ M21/ L20/ L21/ J27/ H20/ H21/ H22/ G22/ G23/ E24 vdds_ddr1 DDR1 power supply (1.8V for DDR2 mode / 1.5V for DDR3 mode / 1.35V DDR3L mode) PWR AH27/ AG20/ AG28/ AD26/ AC22/ AB21/ AB22/ AB24/ AB25/ AA21/ AA22/ W16/ W27 vddshv5 Dual Voltage (1.8V or 3.3V) power supply for the RTC Power Group pins PWR V12 vddshv1 Dual Voltage (1.8V or 3.3V) power supply for the VIN2 Power Group pins PWR H8/ H9/ G4/ G5/ E3/ E5 vddshv10 Dual Voltage (1.8V or 3.3V) power supply for the GPMC Power Group pins PWR T4/ T5/ R7/ R10/ P10/ N4/ N5 vddshv11 Dual Voltage (1.8V or 3.3V) power supply for the MMC2 Power Group pins PWR K8/ J8 vddshv2 Dual Voltage (1.8V or 3.3V) power supply for the VOUT Power Group pins PWR H10/ H11/ E10/ D10/ B6 vddshv3 Dual Voltage (1.8V or 3.3V) power supply for the GENERAL Power Group pins PWR H15/ H16/ H18/ H19/ G15/ E16/ E22/ D16/ D22/ B23 vddshv4 Dual Voltage (1.8V or 3.3V) power supply for the MMC4 Power Group pins PWR C24 vddshv6 Dual Voltage (1.8V or 3.3V) power supply for the VIN1 Power Group pins PWR AF5/ AE7/ AD5/ AD7 vddshv7 Dual Voltage (1.8V or 3.3V) power supply for the WIFI Power Group pins PWR AB6 / AB7 vddshv8 Dual Voltage (1.8V or 3.3V) power supply for the MMC1 Power Group pins PWR Y8 / W8 vddshv9 Dual Voltage (1.8V or 3.3V) power supply for the RGMII Power Group pins PWR W4/ W5/ U10 External capacitor connection for the DSP-EVE SRAM array ldo2 output CAP J9 cap_vddram_dspeve2(1) 138 Terminal Configuration and Functions Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 4-34. Power Supply Signal Descriptions (continued) SIGNAL NAME DESCRIPTION TYPE BALL External capacitor connection for the DSP-EVE SRAM array ldo1 output CAP J10 External capacitor connection for the MPU vbb ldo output CAP J16 External capacitor connection for the Core SRAM array ldo2 output CAP J19 cap_vbbldo_dspeve External capacitor connection for the DSP-EVE vbb ldo output CAP K9 cap_vddram_mpu1(1) External capacitor connection for the MPU SRAM array ldo1 output CAP K16 cap_vddram_mpu2(1) External capacitor connection for the MPU SRAM array ldo2 output CAP K19 cap_vddram_core1(1) External capacitor connection for the Core SRAM array ldo1 output CAP L9 (1) cap_vddram_dspeve1(1) cap_vbbldo_mpu(1) cap_vddram_core2(1) (1) cap_vddram_core4 External capacitor connection for the Core SRAM array ldo4 output CAP P19 cap_vbbldo_iva(1) External capacitor connection for the IVA vbb ldo output CAP R20 cap_vddram_iva(1) External capacitor connection for the IVA SRAM array ldo output CAP T20 External capacitor connection for the GPU SRAM array ldo output CAP Y13 External capacitor connection for the GPU vbb ldo output CAP Y14 cap_vddram_core3(1) External capacitor connection for the Core SRAM array ldo3 output CAP Y15 (1) External capacitor connection for the Core SRAM array ldo5 output CAP Y16 cap_vddram_gpu (1) cap_vbbldo_gpu(1) cap_vddram_core5 (1) This pin must always be connected via a 1-uF capacitor to vss. Terminal Configuration and Functions Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 139 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 5 Specifications NOTE For more information, see Power, Reset, and Clock Management / PRCM Subsystem Environment / External Voltage Inputs or Initialization / Preinitialization / Power Requirements section of the Device TRM. NOTE The index numbers 1 and 2 which are part of the EMIF1 and EMIF2 signal prefixes (ddr1_* and ddr2_*) listed in Table 4-7, EMIF Signal Descriptions, not to be confused with DDR1 and DDR2 types of SDRAM memories. NOTE Audio Back End (ABE) module is not supported for this family of devices, but “ABE” name is still present in some clock or DPLL names. CAUTION All IO Cells are NOT Fail-safe compliant and should not be externally driven in absence of their IO supply. 5.1 Absolute Maximum Ratings Stresses beyond those listed as absolute maximum ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those listed under Section 5.4, Recommended Operating Conditions, is not implied. Exposure to absolute maximum rated conditions for extended periods may affect device reliability. Table 5-1. Absolute Maximum Rating Over Junction Temperature Range PARAMETER(1) VSUPPLY (Steady-State) 140 Specifications Supply Voltage Ranges (SteadyState) MIN MAX UNIT Core (vdd, vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva, vdd_rtc) -0.3 1.5 V Analog (vdda_usb1, vdda_usb2, vdda_abe_per, vdda_ddr, vdda_debug, vdda_dsp_eve, vdda_gmac_core, vdda_gpu, vdda_hdmi, vdda_iva, vdda_pcie, vdda_pcie0, vdda_pcie1, vdda_sata, vdda_usb3, vdda_video, vdda_mpu, vdda_osc, vdda_rtc) -0.3 2.0 V Analog 3.3V (vdda33v_usb1, vdda33v_usb2) -0.3 3.8 V vdds18v, vdds18v_ddr1, vdds18v_ddr2, vdds_mlbp, vdds_ddr1, vdds_ddr2 -0.3 2.1 V vddshv1-11 (1.8V mode) -0.3 2.1 V vddshv1-7 (3.3V mode), vddshv9-11 (3.3V mode) -0.3 3.8 V vddshv8 (3.3V mode) -0.3 3.6 V Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-1. Absolute Maximum Rating Over Junction Temperature Range (continued) PARAMETER(1) VIO (Steady-State) Input and Output Voltage Ranges (Steady-State) MIN MAX UNIT Core I/Os -0.3 1.5 V Analog I/Os (except HDMI) -0.3 2.0 V HDMI I/Os -0.3 3.5 V I/O 1.35V -0.3 1.65 V I/O 1.5V -0.3 1.8 V 1.8V I/Os -0.3 2.1 V 3.3V I/Os (except those powered by vddshv8) -0.3 3.8 V 3.3V I/Os (powered by vddshv8) -0.3 SR Maximum slew rate, all supplies VIO (Transient Overshoot / Undershoot) Input and Output Voltage Ranges (Transient Overshoot/Undershoot) Note: valid for up to 20% of the signal period. TJ Operating junction temperature range TSTG Storage temperature range after soldered onto PC Board Automotive (3) 3.6 V 105 V/s 0.2*VDD V -40 125 °C -55 +150 °C (2) Latch-up I-Test I-test , All I/Os (if different levels then one line per level) -100 100 mA Latch-up OV-Test Over-voltage Test(4), All supplies (if different levels then one line per level) N/A 1.5*Vsup ply max V (1) See I/Os supplied by this power pin in Table 4-2 Ball Characteristics. (2) VDD is the voltage on the corresponding power-supply pin(s) for the IO. (3) Per JEDEC JESD78 at 125°C with specified I/O pin injection current and clamp voltage of 1.5 times maximum recommended I/O voltage and negative 0.5 times maximum recommended I/O voltage. (4) Per JEDEC JESD78 at 125°C. 5.2 ESD Ratings Table 5-2 presents the Device ESD Ratings requirements. Table 5-2. ESD Ratings VALUE V(ESD) Electrostatic discharge Human-Body model (HBM), per AEC Q100-002(1) ±1000 All pins Charged-device model (CDM), per AEC Corner pins (A1, Q100-011 AH1, A28, AH28) ±250 UNIT V ±750 (1) AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification. 5.3 Power on Hour (POH) Limits The information in the section below is provided solely for your convenience and does not extend or modify the warranty provided under TI’s standard terms and conditions for TI semiconductor products. NOTE POH is a functional of voltage, temperature and time. Usage at higher voltages and temperatures will result in a reduction in POH to achieve the same reliability performance. For assessment of alternate use cases, contact your local TI representative. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 141 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-3. Power on Hour (POH) Limits IP Duty Cycle Voltage Domain Voltage (V) (max) Frequency (MHz) (max) Tj(°C) POH ARM 70% vdd_mpu OPP_HIGH 1500 Automotive Profile(1) 20000 30% vdd_mpu Retention 0 40% vdd_mpu OPP_HIGH 1500 Automotive Profile(1) 20000 60% vdd_mpu OPP_HIGH 1000 55% vdd_mpu OPP_HIGH 1500 Automotive Profile(1) 20000 Others(2) 45% vdd_mpu OPP_NOM 1000 100% vdd_mpu OPP_HIGH 1176 Automotive Profile(1) 20000 100% vdd_mpu OPP_NOM 1000 Automotive Profile(1) 20000 100% All Automotive Profile(1) 20000 All Support OPPs (1) Automotive profile is defined as 20000 power on hours with junction temperature as follows: 5%@-40°C, 65%@70°C, 20%@110°C, 10%@125°C. (2) Others covers all other IP's voltage and temperature combinations that are not specified in the table, and are constrained by other sections of this data manual. 142 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 5.4 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Recommended Operating Conditions The device is used under the recommended operating conditions described in Table 5-4. NOTE Logic functions and parameter values are not assured out of the range specified in the recommended operating conditions. Table 5-4. Recommended Operating Conditions PARAMETER DESCRIPTION MIN (2) NOM MAX DC (3) MAX (2) UNIT Input Power Supply Voltage Range vdd Core voltage domain supply See Section 5.5 V vdd_mpu Supply voltage range for MPU domain See Section 5.5 V vdd_gpu GPU voltage domain supply See Section 5.5 V vdd_dspeve DSP-EVE voltage domain supply See Section 5.5 V vdd_iva IVA voltage domain supply See Section 5.5 V vdd_rtc RTC voltage domain supply See Section 5.5 vdda_usb1 DPLL_USB and HS USB1 1.8V analog power supply 1.71 1.80 1.71 1.80 Maximum noise (peak-peak) vdda_usb2 HS USB2 1.8V analog power supply HS USB1 3.3V analog power supply.If USB1 is not used, this pin can alternatively be connected to VSS if the following requirements are met: - The usb1_dm/usb1_dp pins are left unconnected - The USB1 PHY is kept powered down HS USB2 3.3V analog power supply. If USB2 is not used, this pin can alternatively be connected to VSS if the following requirements are met: - The usb2_dm/usb2_dp pins are left unconnected - The USB2 PHY is kept powered down 3.135 3.3 3.135 3.3 DPLL_ABE, DPLL_PER, and PER HSDIVIDER analog power supply 1.71 1.80 DPLL_DDR and DDR HSDIVIDER analog power supply 1.71 1.80 DPLL_DEBUG analog power supply 1.71 1.80 vdda_dsp_eve DPLL_DSP and DPLL_EVE analog power supply DPLL_CORE and CORE HSDIVIDER analog power supply 1.71 1.80 1.71 1.80 DPLL_GPU analog power supply Maximum noise (peak-peak) 3.366 3.465 1.836 1.89 1.836 1.89 1.836 1.89 1.71 1.80 V mVPPmax V mVPPmax V mVPPmax V mVPPmax 1.836 1.89 1.836 1.89 1.836 1.89 V mVPPmax 50 50 V mVPPmax 50 Maximum noise (peak-peak) vdda_gpu 3.465 50 Maximum noise (peak-peak) vdda_gmac_core 3.366 50 Maximum noise (peak-peak) V mVPPmax 50 Maximum noise (peak-peak) vdda_debug V mVPPmax 50 Maximum noise (peak-peak) vdda_ddr 1.89 50 Maximum noise (peak-peak) vdda_abe_per 1.836 50 Maximum noise (peak-peak) vdda33v_usb2 1.89 50 Maximum noise (peak-peak) vdda33v_usb1 V 1.836 V mVPPmax V mVPPmax Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 143 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-4. Recommended Operating Conditions (continued) PARAMETER vdda_hdmi DESCRIPTION PLL_HDMI and HDMI analog power supply MIN (2) NOM MAX DC (3) MAX (2) UNIT 1.71 1.80 1.836 1.89 V 1.71 1.80 1.836 1.89 1.71 1.80 1.836 1.89 Maximum noise (peak-peak) vdda_iva DPLL_IVA analog power supply 50 Maximum noise (peak-peak) vdda_pcie DPLL_PCIe_REF and PCIe analog power supply 50 Maximum noise (peak-peak) vdda_pcie0 PCIe ch0 RX/TX analog power supply 1.71 PCIe ch1 RX/TX analog power supply DPLL_SATA and SATA RX/TX analog power supply vdda_usb3 DPLL_USB_OTG_SS and USB3.0 RX/TX analog power supply DPLL_VIDEO1 and DPLL_VIDEO2 analog power supply 1.71 1.80 MLBP IO power supply 1.71 DPLL_MPU analog power supply vdda_osc HFOSC analog power supply RTC bias and RTC LFOSC analog power supply 1.8V power supply 1.80 vdds18v_ddr1 (4) DDR1 bias power supply 1.71 1.80 DDR1 power supply (1.8V for DDR2 mode / 1.5V for DDR3 mode / 1.35V DDR3L mode) Maximum noise (peakpeak) V V mVPPmax 1.89 V mVPPmax 1.836 1.89 V mVPPmax 1.80 1.89 V mVPPmax 1.71 1.80 1.71 1.80 1.89 50 V mVPPmax 1.836 1.89 50 V mVPPmax 1.80 1.836 1.89 50 V mVPPmax 1.71 1.80 1.35-V Mode 1.28 1.5-V Mode 1.8-V Mode 1.35-V Mode 1.89 50 1.836 1.89 1.35 1.377 1.42 1.43 1.50 1.53 1.57 1.71 1.80 1.836 1.89 Maximum noise (peak-peak) vdds_ddr1 (4) 1.836 50 1.71 DDR2 bias power supply 1.89 50 Maximum noise (peak-peak) vdds18v_ddr2 (4) 1.836 50 Maximum noise (peak-peak) V mVPPmax 1.71 Maximum noise (peak-peak) vdds18v 1.80 1.80 1.71 V mVPPmax 1.71 Maximum noise (peak-peak) vdda_rtc 1.89 50 Maximum noise (peak-peak) V mVPPmax 1.836 50 Maximum noise (peak-peak) vdda_mpu 1.89 50 Maximum noise (peak-peak) vdds_mlbp 1.89 mVPPmax 1.80 Maximum noise (peak-peak) vdda_video 1.80 1.71 Maximum noise (peak-peak) V mVPPmax 50 Maximum noise (peak-peak) vdda_sata V mVPPmax 50 Maximum noise (peak-peak) vdda_pcie1 mVPPmax 50 V mVPPmax 50 V mVPPmax 1.5-V Mode 1.8-V Mode 144 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-4. Recommended Operating Conditions (continued) PARAMETER vdds_ddr2 (4) MIN (2) NOM MAX DC (3) MAX (2) UNIT 1.35-V Mode 1.28 1.35 1.377 1.42 V 1.5-V Mode 1.43 1.50 1.53 1.57 1.8-V Mode 1.71 1.80 1.836 1.89 DESCRIPTION DDR2 power supply (1.8V for DDR2 mode/ 1.5V for DDR3 mode / 1.35V DDR3L mode) Maximum noise (peakpeak) 1.35-V Mode 50 mVPPmax 1.5-V Mode 1.8-V Mode vddshv5 vddshv1 vddshv10 vddshv11 vddshv2 vddshv3 vddshv4 Dual Voltage (1.8V or 3.3V) power supply for the RTC Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the VIN2 Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode Dual Voltage (1.8V or 1.8-V Mode 3.3V) power supply for 3.3-V Mode the GPMC Power Group pins 1.71 1.80 1.836 1.89 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode 50 Dual Voltage (1.8V or 3.3V) power supply for the MMC2 Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the VOUT Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the GENERAL Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the MMC4 Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 145 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-4. Recommended Operating Conditions (continued) PARAMETER vddshv6 vddshv7 vddshv8 vddshv9 DESCRIPTION MIN (2) NOM MAX DC (3) MAX (2) UNIT V Dual Voltage (1.8V or 3.3V) power supply for the VIN1 Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the WIFI Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the MMC1 Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode Dual Voltage (1.8V or 3.3V) power supply for the RGMII Power Group pins 1.8-V Mode 1.71 1.80 1.836 1.89 3.3-V Mode 3.135 3.30 3.366 3.465 Maximum noise (peakpeak) 1.8-V Mode 50 mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode 50 V mVPPmax 3.3-V Mode vss Ground supply 0 V vssa_hdmi DPLL_HDMI and HDMI PHY analog ground 0 V vssa_pcie PCIe analog ground 0 V vssa_usb HS USB1 and HS USB2 analog ground 0 V vssa_usb3 DPLL_USB and USB3.0 RX/TX analog ground 0 V vssa_video DPLL_VIDEO1 and DPLL_VIDEO2 analog ground 0 V vssa_osc0 OSC0 analog ground 0 V vssa_osc1 OSC1 analog ground 0 TJ(1) Operating junction temperature range Automotive -40 V 125 °C Output Power Supply Voltage Range ddr1_vref0 Reference Power Supply DDR1 0.5*vdds_ddr1 V ddr2_vref0 Reference Power Supply DDR2 0.5*vdds_ddr2 V (1) Refer to Power on Hours table Table 5-3 for limitations. (2) The voltage at the device ball should never be below the MIN voltage or above the MAX voltage for any amount of time. This requirement includes dynamic voltage events such as AC ripple, voltage transients, voltage dips, etc. (3) The DC voltage at the device ball should never be above the MAX DC voltage to avoid impact on device reliability and lifetime POH (Power-On-Hours). The MAX DC voltage is defined as the highest allowed DC regulated voltage, without transients, seen at the ball. (4) If DDR2 type of memories are used, the EMIF power supply (vdds_ddrx) and the corresponding bias power supply (vdds18v_ddrx) must be sourced from single power source. 5.5 Operating Performance Points This section describes the operating conditions of the device. This section also contains the description of each OPP (operating performance point) for processor clocks and device core clocks. Table 5-5 describes the maximum supported frequency per speed grade for DRA75x/DRA74x devices. 146 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-5. Speed Grade Maximum Frequency Device Speed Maximum frequency (MHz) MPU DSP EVE IVA GPU IPU L3 DDR3/DDR3L DDR2 DRA7xxxP 1500 700 650 (1) 532 532 212.8 266 532 (DDR3-1066) 400 (DDR2-800) DRA7xxxL 1176 700 650 (1) 532 532 212.8 266 532 (DDR3-1066) 400 (DDR2-800) 700 (1) 532 532 212.8 266 532 (DDR3-1066) 400 (DDR2-800) DRA7xxxJ 1000 650 (1) Applicable for DRA754, DRA755, and DRA756. Not Applicable for all other devices! 5.5.1 AVS and ABB Requirements Adaptive Voltage Scaling (AVS) and Adaptive Body Biasing (ABB) are required on most of the vdd_* supplies as defined in Table 5-6. Table 5-6. AVS and ABB Requirements per vdd_* Supply Supply AVS Required? vdd Yes, for all OPPs No vdd_mpu Yes, for all OPPs Yes, for all OPPs vdd_iva Yes, for all OPPs Yes, for all OPPs vdd_dspeve Yes, for all OPPs Yes, for all OPPs vdd_gpu Yes, for all OPPs Yes, for all OPPs vdd_rtc No No 5.5.2 ABB Required? Voltage And Core Clock Specifications Table 5-7 shows the recommended OPP per voltage domain. Table 5-7. Voltage Domains Operating Performance Points DOMAIN CONDITION OPP_NOM MIN (2) VD_CORE (V) BOOT (Before AVS is enabled) (4) After AVS is enabled (4) VD_MPU (V) BOOT (Before AVS is enabled) (4) After AVS is enabled (4) VD_RTC (V) Others (V) (6) 1.11 1.15 AVS AVS Voltag Voltage (5) e (5) – 3.5% 1.11 OPP_OD NOM (1) MAX (2) 1.15 AVS AVS Voltag Voltage (5) e (5) – 3.5% MIN (2) NOM (1) MAX (2) OPP_HIGH MIN (2) NOM (1) MAX DC (3) 1.2 Not Applicable Not Applicable 1.16 Not Applicable Not Applicable 1.2 Not Applicable Not Applicable 1.16 AVS AVS AVS AVS AVS AVS Voltage Voltage Voltage Voltage Voltage Voltage (5) (5) (5) – (5) + (5) – (5) +2% 3.5% 5% 3.5% - 0.84 0.88 to 1.06 1.16 Not Applicable Not Applicable BOOT (Before AVS is enabled) (4) 1.02 1.06 1.16 Not Applicable Not Applicable After AVS is enabled (4) AVS AVS Voltag Voltage (5) e (5) – 3.5% 1.16 AVS AVS AVS AVS AVS AVS Voltage Voltage Voltage Voltage Voltage Voltage (5) (5) (5) – (5) + (5) – (5) +2% 3.5% 5% 3.5% MAX (2) AVS Voltage (5) + 5% AVS Voltage (5) + 5% (1) In a typical implementation, the power supply should target the NOM voltage. (2) The voltage at the device ball should never be below the MIN voltage or above the MAX voltage for any amount of time. This requirement includes dynamic voltage events such as AC ripple, voltage transients, voltage dips, etc. (3) The DC voltage at the device ball should never be above the MAX DC voltage to avoid impact on device reliability and lifetime POH (Power-On-Hours). The MAX DC voltage is defined as the highest allowed DC regulated voltage, without transients, seen at the ball. (4) For all OPPs, AVS must be enabled to avoid impact on device reliability, lifetime POH (Power-On-Hours), and device power. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 147 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (5) The AVS Voltages are device-dependent, voltage domain-dependent, and OPP-dependent. They must be read from the STD_FUSE_OPP. For information about STD_FUSE_OPP Registers address, please refer to Control Module Section of the TRM. The power supply should be adjustable over the following ranges for each required OPP: – OPP_NOM for MPU: 0.85V – 1.15V – OPP_NOM for CORE and Others: 0.85V - 1.15V – OPP_OD: 0.885V - 1.15V – OPP_HIGH: 0.95V - 1.25V The AVS Voltages will be within the above specified ranges. (6) VD_RTC can optionally be tied to VD_CORE and operate at the VD_CORE AVS voltages. (7) The power supply must be programmed with the AVS voltages for the MPU and the CORE voltage domain, either just after the ROM boot or at the earliest possible time in the secondary boot loader before there is significant activity seen on these domains. Table 5-8 describes the standard processor clocks speed characteristics vs OPP of the device. Table 5-8. Supported OPP vs Max Frequency (2) DESCRIPTION OPP_NOM OPP_OD OPP_HIGH Max Freq. (MHz) Max Freq. (MHz) Max Freq. (MHz) 1000 1176 1500 DSP_CLK 600 700 700 EVE_FCLK 535 650 650 IVA_GCLK 388.3 430 532 GPU_CLK 425.6 500 532 CORE_IPUx_CLK 212.8 N/A N/A L3_CLK 266 N/A N/A DDR2 400 (DDR2-800) N/A N/A DDR3 / DDR3L 532 (DDR3-1066) N/A N/A RTC_FCLK 0.034 N/A N/A VD_MPU MPU_CLK VD_DSPEVE VD_IVA VD_GPU VD_CORE VD_RTC (1) N/A in this table stands for Not Applicable. (2) Maximum supported frequency is limited according to the Device Speed Grade (see Table 5-5). 5.5.3 Maximum Supported Frequency Device modules either receive their clock directly from an external clock input, directly from a PLL, or from a PRCM. Table 5-9 lists the clock source options for each module on this device, along with the maximum frequency that module can accept. To ensure proper module functionality, the device PLLs and dividers must be programmed not to exceed the maximum frequencies listed in this table. Table 5-9. Maximum Supported Frequency Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name AES1 AES1_L3_CLK Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE AES2 AES2_L3_CLK Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE 148 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name ATL ATL_ICLK_L3 Int 266 ATL_L3_GICLK CORE_X2_CLK DPLL_CORE ATLPCLK Func 266 ATL_GFCLK CORE_X2_CLK DPLL_CORE PER_ABE_X1_GF CLK DPLL_ABE FUNC_32K_CLK OSC1 VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 RTC Oscillator HDMI_CLK DPLL_HDMI BB2D_GFCLK DPLL_CORE 266 DSS_L3_GICLK CORE_X2_CLK DPLL_CORE 0.032 FUNC_32K_CLK SYS_32K RTC Oscillator BB2D_FCLK BB2D_ICLK Int COUNTER_32K COUNTER_32K_F CLK Func COUNTER_32K_IC LK Int 38.4 WKUPAON_GICLK CTRL_MODULE_B ANDGAP L3INSTR_TS_GCL K Int CTRL_MODULE_C ORE L4CFG_L4_GICLK Int 133 CTRL_MODULE_ WKUP WKUPAON_GICLK Int 38.4 DCAN1 DCAN1_FCLK DCAN1_ICLK DCAN2 Func BB2D_GFCLK BB2D Func Int 354.6 4.8 38.4 266 L3INSTR_TS_GCLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE L4CFG_L4_GICLK CORE_X2_CLK DPLL_CORE WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 SYS_CLK2 OSC2 DCAN1_SYS_CLK WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE DCAN2_FCLK Func 38.4 DCAN2_SYS_CLK SYS_CLK1 OSC1 DCAN2_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE DES3DES DES_CLK_L3 Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE DLL EMIF_DLL_FCLK Func EMIF_DLL_FC LK EMIF_DLL_GCLK EMIF_DLL_GCLK DPLL_DDR DLL_AGING FCLK Int 38.4 L3INSTR_DLL_AGING _GCLK DMA_CRYPTO SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE DMA_CRYPTO_FC LK Int & Func 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE DMA_CRYPTO_IC LK Int 133 L4SEC_L4_GICLK CORE_X2_CLK DPLL_CORE DMM DMM_CLK Int 266 EMIF_L3_GICLK CORE_X2_CLK DPLL_CORE DPLL_DEBUG SYSCLK Int 38.4 EMU_SYS_CLK SYS_CLK1 OSC1 DSP1 DSP1_FICLK Int & Func DSP_CLK DSP1_GFCLK DSP_GFCLK DPLL_DSP DSP2 DSP2_FICLK Int & Func DSP_CLK DSP2_GFCLK DSP_GFCLK DPLL_DSP Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 149 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name DSS_HDMI_CEC_ CLK Func 0.032 HDMI_CEC_GFCLK SYS_32K RTC Oscillator DSS_HDMI_PHY_ CLK Func 48 HDMI_PHY_GFCLK FUNC_192M_CLK DPLL_PER DSS_CLK Func 192 DSS_GFCLK DSS_CLK DPLL_PER HDMI_CLKINP Func 38.4 HDMI_DPLL_CLK SYS_CLK1 OSC1 Instance Name Input Clock Name DSS SYS_CLK2 OSC2 DSS_L3_ICLK Int 266 DSS_L3_GICLK CORE_X2_CLK DPLL_CORE VIDEO1_CLKINP Func 38.4 VIDEO1_DPLL_CLK SYS_CLK1 OSC1 SYS_CLK2 OSC2 SYS_CLK1 OSC1 SYS_CLK2 OSC2 VIDEO2_CLKINP Func DPLL_DSI1_A_CL K1 Func DPLL_DSI1_B_CL K1 Func DPLL_DSI1_C_CL K1 DSS DISPC Clock Sources Func 38.4 209.3 209.3 209.3 VIDEO2_DPLL_CLK N/A N/A N/A HDMI_CLK DPLL_HDMI VIDEO1_CLKOUT1 DPLL_VIDEO1 VIDEO1_CLKOUT3 DPLL_VIDEO1 VIDEO2_CLKOUT3 DPLL_VIDEO2 HDMI_CLK DPLL_HDMI DPLL_ABE_X2_CL K DPLL_ABE HDMI_CLK DPLL_HDMI VIDEO1_CLKOUT3 DPLL_VIDEO1 VIDEO2_CLKOUT1 DPLL_VIDEO2 DPLL_HDMI_CLK1 Func 185.6 N/A HDMI_CLK DPLL_HDMI LCD1_CLK Func 209.3 N/A DPLL_DSI1_A_CL K1 See DSS data in the rows above LCD2_CLK Func 209.3 N/A DPLL_DSI1_B_CL K1 DSS_CLK DSS_CLK LCD3_CLK Func 209.3 N/A DPLL_DSI1_C_CL K1 DSS_CLK F_CLK Func 209.3 N/A DPLL_DSI1_A_CL K1 DPLL_DSI1_B_CL K1 DPLL_DSI1_C_CL K1 DSS_CLK DPLL_HDMI_CLK1 EFUSE_CTRL_CU ST ocp_clk Int 133 CUSTEFUSE_L4_GICL K CORE_X2_CLK DPLL_CORE sys_clk Func 38.4 CUSTEFUSE_SYS_GF CLK SYS_CLK1 OSC1 ELM ELM_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE EMIF_OCP_FW L3_CLK Int 266 EMIF_L3_GICLK CORE_X2_CLK DPLL_CORE EMIF_PHY1 EMIF_PHY1_FCLK Func DDR EMIF_PHY_GCLK EMIF_PHY_GCLK DPLL_DDR EMIF_PHY2 EMIF_PHY2_FCLK Func DDR EMIF_PHY_GCLK EMIF_PHY_GCLK DPLL_DDR 150 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name EMIF1 EMIF1_ICLK Int 266 EMIF_L3_GICLK CORE_X2_CLK DPLL_CORE EMIF2 EMIF2_ICLK Int 266 EMIF_L3_GICLK CORE_X2_CLK DPLL_CORE EVE1 EVE1_FCLK Func EVE_FCLK EVE1_GFCLK - DPLL_DSP EVE_GFCLK DPLL_EVE DPLL_DSP EVE2 EVE2_FCLK Func EVE_FCLK EVE2_GFCLK EVE_GFCLK DPLL_EVE FPKA PKA_CLK Int & Func 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE GMAC_SW CPTS_RFT_CLK Func 266 GMAC_RFT_CLK PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 GPIO1 GPIO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE MAIN_CLK Int 125 GMAC_MAIN_CLK GMAC_250M_CLK DPLL_GMAC MHZ_250_CLK Func 250 GMII_250MHZ_CLK GMII_250MHZ_CL K DPLL_GMAC MHZ_5_CLK Func 5 RGMII_5MHZ_CLK GMAC_RMII_HS_C LK DPLL_GMAC MHZ_50_CLK Func 50 RMII_50MHZ_CLK GMAC_RMII_HS_C LK DPLL_GMAC RMII1_MHZ_50_CL K Func 50 RMII_50MHZ_CLK GMAC_RMII_HS_C LK DPLL_GMAC RMII2_MHZ_50_CL K Func 50 RMII_50MHZ_CLK GMAC_RMII_HS_C LK DPLL_GMAC GPIO1_ICLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE OSC1 GPIO1_DBCLK Func 0.032 WKUPAON_SYS_GFC LK WKUPAON_32K_G FCLK GPIO2_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK GPIO2_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK RTC Oscillator DPLL_CORE OSC1 RTC Oscillator GPIO3 GPIO3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK GPIO3_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK DPLL_CORE OSC1 RTC Oscillator GPIO4 GPIO5 GPIO6 GPIO4_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK GPIO4_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK PIDBCLK Func 0.032 GPIO_GFCLK DPLL_CORE OSC1 RTC Oscillator GPIO5_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK GPIO5_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK PIDBCLK Func 0.032 GPIO_GFCLK GPIO6_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK GPIO6_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK PIDBCLK Func 0.032 GPIO_GFCLK DPLL_CORE OSC1 RTC Oscillator DPLL_CORE OSC1 RTC Oscillator Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 151 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name GPIO7 GPIO7_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE GPIO7_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK PIDBCLK Func 0.032 GPIO_GFCLK GPIO8 OSC1 RTC Oscillator GPIO8_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE GPIO8_DBCLK Func 0.032 GPIO_GFCLK FUNC_32K_CLK OSC1 PIDBCLK Func 0.032 GPIO_GFCLK GPMC GPMC_FCLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE GPU GPU_FCLK1 Func GPU_CLK GPU_CORE_GCLK CORE_GPU_CLK DPLL_CORE GPU_FCLK2 Func GPU_CLK GPU_HYD_GCLK RTC Oscillator PER_GPU_CLK DPLL_PER GPU_GCLK DPLL_GPU CORE_GPU_CLK DPLL_CORE PER_GPU_CLK DPLL_PER GPU_GCLK DPLL_GPU GPU_ICLK Int 266 GPU_L3_GICLK CORE_X2_CLK DPLL_CORE HDMI PHY DSS_HDMI_PHY_ CLK Func 38.4 HDMI_PHY_GFCLK FUNC_192M_CLK DPLL_PER HDQ1W HDQ1W_ICLK Int & Func 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE HDQ1W_FCLK Func 12 PER_12M_GFCLK FUNC_192M_CLK DPLL_PER I2C1_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE I2C1_FCLK Func 96 PER_96M_GFCLK FUNC_192M_CLK DPLL_PER I2C2_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE I2C2_FCLK Func 96 PER_96M_GFCLK FUNC_192M_CLK DPLL_PER I2C3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE I2C3_FCLK Func 96 PER_96M_GFCLK FUNC_192M_CLK DPLL_PER DPLL_CORE I2C1 I2C2 I2C3 I2C4 I2C5 I2C4_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK I2C4_FCLK Func 96 PER_96M_GFCLK FUNC_192M_CLK DPLL_PER I2C5_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE I2C5_FCLK Func 96 IPU_96M_GFCLK FUNC_192M_CLK DPLL_PER IEEE1500_2_OCP PI_L3CLK Int & Func 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE IPU1 IPU1_GFCLK Int & Func 425.6 IPU1_GFCLK DPLL_ABE_X2_CL K DPLL_ABE CORE_IPU_ISS_B OOST_CLK DPLL_CORE CORE_IPU_ISS_B OOST_CLK DPLL_CORE IPU2 152 IPU2_GFCLK Int & Func 425.6 IPU2_GFCLK IVA IVA_GCLK Int IVA_GCLK IVA_GCLK IVA_GFCLK DPLL_IVA KBD KBD_FCLK Func 0.032 WKUPAON_SYS_GFC LK WKUPAON_32K_G FCLK OSC1 PICLKKBD Func 0.032 WKUPAON_SYS_GFC LK KBD_ICLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 PICLKOCP Int 38.4 WKUPAON_GICLK DPLL_ABE_X2_CL K DPLL_ABE L3_INSTR L3_CLK Int L3_CLK L3INSTR_L3_GICLK CORE_X2_CLK DPLL_CORE L3_MAIN L3_CLK1 Int L3_CLK L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE L3_CLK2 Int L3_CLK L3INSTR_L3_GICLK CORE_X2_CLK DPLL_CORE Specifications RTC Oscillator Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name L4_CFG L4_CFG_CLK Int 133 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE L4_PER1 L4_PER1_CLK Int 133 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE L4_PER2 L4_PER2_CLK Int 133 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE L4_PER3 L4_PER3_CLK Int 133 L4PER3_L3_GICLK CORE_X2_CLK DPLL_CORE L4_WKUP L4_WKUP_CLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE MAILBOX1 MAILBOX1_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX2 MAILBOX2_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX3 MAILBOX3_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX4 MAILBOX4_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX5 MAILBOX5_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX6 MAILBOX6_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX7 MAILBOX7_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX8 MAILBOX8_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX9 MAILBOX9_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX10 MAILBOX10_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX11 MAILBOX11_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX12 MAILBOX12_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE MAILBOX13 MAILBOX13_FLCK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 153 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name MCASP1 MCASP1_AHCLKR Func 100 MCASP1_AHCLKR MCASP1_AHCLKX MCASP1_FCLK MCASP1_ICLK 154 Specifications Func Func Int 100 192 266 MCASP1_AHCLKX MCASP1_AUX_GFCLK IPU_L3_GICLK PLL / OSC / Source Clock Name PLL / OSC / Source Name DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATLCLK0 Module ATL ATLCLK1 Module ATL ATLCLK2 Module ATL ATLCLK3 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATLCLK0 Module ATL ATLCLK1 Module ATL ATLCLK2 Module ATL ATLCLK3 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name MCASP2 MCASP2_AHCLKR Func 100 MCASP2_AHCLKR MCASP2_AHCLKX MCASP2_FCLK MCASP2_ICLK Func Func Int 100 192 266 MCASP2_AHCLKX MCASP2_AUX_GFCLK L4PER2_L3_GICLK PLL / OSC / Source Clock Name DPLL_ABE_X2_CL K PLL / OSC / Source Name DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 155 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name MCASP3 MCASP3_AHCLKX Func 100 MCASP3_AHCLKX MCASP3_FCLK MCASP4 MCASP3_AUX_GFCLK DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE MCASP4_AHCLKX Func 100 MCASP4_AHCLKX DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MCASP4_ICLK Specifications 192 PLL / OSC / Source Name MCASP3_ICLK MCASP4_FCLK 156 Func PLL / OSC / Source Clock Name Func Int 192 266 MCASP4_AUX_GFCLK L4PER2_L3_GICLK MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name MCASP5 MCASP5_AHCLKX Func 100 MCASP5_AHCLKX MCASP5_FCLK MCASP6 Func 192 MCASP5_AUX_GFCLK PLL / OSC / Source Clock Name DPLL_ABE_X2_CL K PLL / OSC / Source Name DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI MCASP5_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE MCASP6_AHCLKX Func 100 MCASP6_AHCLKX DPLL_ABE_X2_CL K DPLL_ABE FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL MCASP6_FCLK MCASP6_ICLK Func Int 192 266 MCASP6_AUX_GFCLK L4PER2_L3_GICLK ATL_CLK0 Module ATL MLB_CLK Module MLB MLBP_CLK Module MLB SYS_CLK1 OSC1 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 157 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name MCASP7 MCASP7_AHCLKX Func 100 MCASP7_AHCLKX MCASP7_FCLK MCASP8 Specifications MCASP7_AUX_GFCLK DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE MCASP8_AHCLKX Func 100 MCASP8_AHCLKX DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_96M_AON_ CLK DPLL_PER ATL_CLK3 Module ATL ATL_CLK2 Module ATL ATL_CLK1 Module ATL ATL_CLK0 Module ATL SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 MCASP8_ICLK 158 192 PLL / OSC / Source Name MCASP7_ICLK MCASP8_FCLK MCSPI1 Func PLL / OSC / Source Clock Name Func 192 Int 266 SPI1_ICLK Int 266 SPI1_FCLK Func 48 MCASP8_AUX_GFCLK MLB_CLK Module MLB MLBP_CLK Module MLB PER_ABE_X1_GF CLK DPLL_ABE VIDEO1_CLK DPLL_ABE VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE PER_48M_GFCLK PER_48M_GFCLK DPLL_PER L4PER2_L3_GICLK Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name MCSPI2 SPI2_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE SPI2_FCLK Func 48 PER_48M_GFCLK PER_48M_GFCLK DPLL_PER SPI3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE MCSPI3 SPI3_FCLK Func 48 PER_48M_GFCLK PER_48M_GFCLK DPLL_PER MCSPI4 SPI4_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE SPI4_FCLK Func 48 PER_48M_GFCLK PER_48M_GFCLK DPLL_PER MLB_SS MLB_L3_ICLK Int 266 MLB_SHB_L3_GICLK CORE_X2_CLK DPLL_CORE MLB_L4_ICLK Int 133 MLB_SPB_L4_GICLK CORE_X2_CLK DPLL_CORE DPLL_CORE MMC1 MLB_FCLK Func 266 MLB_SYS_L3_GFCLK CORE_X2_CLK MMC1_CLK_32K Func 0.032 L3INIT_32K_GFCLK FUNC_32K_CLK OSC1 MMC1_FCLK Func 192 MMC1_GFCLK FUNC_192M_CLK DPLL_PER MMC1_ICLK1 Int 128 MMC2 266 L3INIT_L3_GICLK DPLL_PER CORE_X2_CLK DPLL_CORE MMC1_ICLK2 Int 133 L3INIT_L4_GICLK CORE_X2_CLK DPLL_CORE MMC2_CLK_32K Func 0.032 L3INIT_32K_GFCLK FUNC_32K_CLK OSC1 MMC2_FCLK Func 192 MMC2_GFCLK FUNC_192M_CLK DPLL_PER 128 MMC3 FUNC_256M_CLK FUNC_256M_CLK DPLL_PER L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE MMC2_ICLK1 Int 266 MMC2_ICLK2 Int 133 L3INIT_L4_GICLK CORE_X2_CLK DPLL_CORE MMC3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE MMC3_CLK_32K Func 0.032 L4PER_32K_GFCLK FUNC_32K_CLK OSC1 MMC3_FCLK Func 48 MMC3_GFCLK FUNC_192M_CLK DPLL_PER 192 MMC4 MMC4_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE MMC4_CLK_32K Func 0.032 L4PER_32K_GFCLK FUNC_32K_CLK OSC1 MMC4_FCLK Func 48 MMC4_GFCLK FUNC_192M_CLK DPLL_PER 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE 192 MMU_EDMA MMU1_CLK Int MMU_PCIESS MMU2_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE MPU MPU_CLK Int & Func MPU_CLK MPU_GCLK MPU_GCLK DPLL_MPU MPU_EMU_DBG FCLK Int 38.4 EMU_SYS_CLK SYS_CLK1 OSC1 MPU_GCLK DPLL_MPU OCMC_RAM1 OCMC1_L3_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE OCMC_RAM2 OCMC2_L3_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE OCMC_RAM3 OCMC3_L3_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE OCMC_ROM OCMC_L3_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE OCP_WP_NOC PICLKOCPL3 Int 266 L3INSTR_L3_GICLK CORE_X2_CLK DPLL_CORE OCP2SCP1 L4CFG1_ADAPTE R_CLKIN Int 133 L3INIT_L4_GICLK CORE_X2_CLK DPLL_CORE OCP2SCP2 L4CFG2_ADAPTE R_CLKIN Int 133 L4CFG_L4_GICLK CORE_X2_CLK DPLL_CORE OCP2SCP3 L4CFG3_ADAPTE R_CLKIN Int 133 L3INIT_L4_GICLK CORE_X2_CLK DPLL_CORE Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 159 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Instance Name Input Clock Name PCIESS1 PCIE1_PHY_WKU P_CLK PCIESS2 PRCM_MPU Clock Sources Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name Func 0.032 PCIE_32K_GFCLK FUNC_32K_CLK RTC Oscillator PCIe_SS1_FICLK Int 266 PCIE_L3_GICLK CORE_X2_CLK DPLL_CORE PCIEPHY_CLK Func 2500 PCIE_PHY_GCLK PCIE_PHY_GCLK APLL_PCIE PCIEPHY_CLK_DI V Func 1250 PCIE_PHY_DIV_GCLK PCIE_PHY_DIV_G CLK APLL_PCIE PCIE1_REF_CLKI N Func 34.3 PCIE_REF_GFCLK CORE_USB_OTG_ SS_LFPS_TX_CLK DPLL_CORE PCIE1_PWR_CLK Func 38.4 PCIE_SYS_GFCLK SYS_CLK1 OSC1 PCIE2_PHY_WKU P_CLK Func 0.032 PCIE_32K_GFCLK FUNC_32K_CLK RTC Oscillator PCIe_SS2_FICLK Func 266 PCIE_L3_GICLK CORE_X2_CLK DPLL_CORE PCIEPHY_CLK Func 2500 PCIE_PHY_GCLK PCIE_PHY_GCLK APLL_PCIE PCIEPHY_CLK_DI V Func 1250 PCIE_PHY_DIV_GCLK PCIE_PHY_DIV_G CLK APLL_PCIE PCIE2_REF_CLKI N Func 34.3 PCIE_REF_GFCLK CORE_USB_OTG_ SS_LFPS_TX_CLK DPLL_CORE PCIE2_PWR_CLK Func 38.4 PCIE_SYS_GFCLK SYS_CLK1 OSC1 32K_CLK Func 0.032 FUNC_32K_CLK SYS_32K RTC Oscillator SYS_CLK Func 38.4 WKUPAON_ICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE PWMSS1 PWMSS1_GICLK Int & Func 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE PWMSS2 PWMSS2_GICLK Int & Func 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE PWMSS3 PWMSS3_GICLK Int & Func 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE QSPI QSPI_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE QSPI_FCLK Func 128 QSPI_GFCLK FUNC_256M_CLK DPLL_PER PER_QSPI_CLK DPLL_PER RNG RNG_ICLK Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE RTC_SS RTC_ICLK Int 133 RTC_L4_GICLK CORE_X2_CLK DPLL_CORE RTC_FCLK Func RTC_FCLK RTC_AUX_CLK FUNC_32K_CLK RTC Oscillator SAR_ROM PRCM_ROM_CLO CK Int 266 L4CFG_L3_GICLK CORE_X2_CLK DPLL_CORE SATA SATA_FICLK Int 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE SATA_PMALIVE_F CLK Func 48 L3INIT_48M_GFCLK FUNC_192M_CLK DPLL_PER REF_CLK Func 38 SATA_REF_GFCLK SYS_CLK1 OSC1 SDMA SDMA_FCLK Int & Func 266 DMA_L3_GICLK CORE_X2_CLK DPLL_CORE SHA2MD51 SHAM_1_CLK Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE SHA2MD52 SHAM_2_CLK Int 266 L4SEC_L3_GICLK CORE_X2_CLK DPLL_CORE SL2 IVA_GCLK Int IVA_GCLK IVA_GCLK IVA_GFCLK DPLL_IVA SMARTREFLEX_C ORE MCLK Int 133 COREAON_L4_GICLK CORE_X2_CLK DPLL_CORE SYSCLK Func 38.4 WKUPAON_ICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE 160 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name SMARTREFLEX_D SPEVE MCLK Int 133 COREAON_L4_GICLK CORE_X2_CLK DPLL_CORE SYSCLK Func 38.4 WKUPAON_ICLK SMARTREFLEX_G PU SMARTREFLEX_IV AHD SMARTREFLEX_M PU MCLK Int 133 COREAON_L4_GICLK SYSCLK Func 38.4 WKUPAON_ICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE CORE_X2_CLK DPLL_CORE SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE DPLL_CORE MCLK Int 133 COREAON_L4_GICLK CORE_X2_CLK SYSCLK Func 38.4 WKUPAON_ICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE DPLL_CORE MCLK Int 133 COREAON_L4_GICLK CORE_X2_CLK SYSCLK Func 38.4 WKUPAON_ICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE DPLL_CORE SPINLOCK SPINLOCK_ICLK Int 266 L4CFG_L3_GICLK CORE_X2_CLK TIMER1 TIMER1_ICLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 TIMER1_FCLK Func 100 TIMER1_GFCLK RTC Oscillator TIMER2 TIMER2_ICLK Int 266 L4PER_L3_GICLK TIMER2_FCLK Func 100 TIMER2_GFCLK SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 161 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name TIMER3 TIMER3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER3_FCLK Func 100 TIMER3_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER4 TIMER4_ICLK Int 266 L4PER_L3_GICLK TIMER4_FCLK Func 100 TIMER4_GFCLK SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER5 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI TIMER5_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER5_FCLK Func 100 TIMER5_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator 162 Specifications SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CLKOUTMUX[0] CLKOUTMUX[0] Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name TIMER6 TIMER6_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER6_FCLK Func 100 TIMER6_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER7 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CLKOUTMUX[0] CLKOUTMUX[0] TIMER7_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER7_FCLK Func 100 TIMER7_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER8 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CLKOUTMUX[0] CLKOUTMUX[0] TIMER8_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER8_FCLK Func 100 TIMER8_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CLKOUTMUX[0] CLKOUTMUX[0] Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 163 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name TIMER9 TIMER9_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER9_FCLK Func 100 TIMER9_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER10 TIMER10_ICLK Int 266 L4PER_L3_GICLK TIMER10_FCLK Func 100 TIMER10_GFCLK SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER11 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI TIMER11_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER11_FCLK Func 100 TIMER11_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER12 TIMER12_ICLK TIMER12_FCLK 164 Specifications Int Func 38.4 0.032 WKUPAON_GICLK OSC_32K_CLK SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE RC_CLK RC oscillator Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name TIMER13 TIMER13_ICLK Int 266 L4PER3_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER13_FCLK Func 100 TIMER13_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER14 TIMER14_ICLK Int 266 L4PER3_L3_GICLK TIMER14_FCLK Func 100 TIMER14_GFCLK SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI CORE_X2_CLK DPLL_CORE SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator TIMER15 SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI TIMER15_ICLK Int 266 L4PER3_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER15_FCLK Func 100 TIMER15_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator SYS_CLK2 OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 165 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name TIMER16 TIMER16_ICLK Int 266 L4PER3_L3_GICLK CORE_X2_CLK DPLL_CORE TIMER16_FCLK Func 100 TIMER16_GFCLK SYS_CLK1 OSC1 FUNC_32K_CLK OSC1 RTC Oscillator OSC2 XREF_CLK0 XREF_CLK0 XREF_CLK1 XREF_CLK1 XREF_CLK2 XREF_CLK2 XREF_CLK3 XREF_CLK3 DPLL_ABE_X2_CL K DPLL_ABE VIDEO1_CLK DPLL_VIDEO1 VIDEO2_CLK DPLL_VIDEO2 HDMI_CLK DPLL_HDMI TPCC TPCC_GCLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE TPTC1 TPTC0_GCLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE TPTC2 TPTC1_GCLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE UART1 UART1_FCLK Func 48 UART1_GFCLK FUNC_192M_CLK DPLL_PER UART1_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE UART2 UART2_FCLK Func 48 UART2_GFCLK FUNC_192M_CLK DPLL_PER UART2_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE UART3 UART3_FCLK Func 48 UART3_GFCLK FUNC_192M_CLK DPLL_PER UART3_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE UART4 UART4_FCLK Func 48 UART4_GFCLK FUNC_192M_CLK DPLL_PER UART4_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE UART5_FCLK Func 48 UART5_GFCLK FUNC_192M_CLK DPLL_PER UART5_ICLK Int 266 L4PER_L3_GICLK CORE_X2_CLK DPLL_CORE UART6 UART6_FCLK Func 48 UART6_GFCLK FUNC_192M_CLK DPLL_PER UART6_ICLK Int 266 IPU_L3_GICLK CORE_X2_CLK DPLL_CORE UART7 UART7_FCLK Func 48 UART7_GFCLK FUNC_192M_CLK DPLL_PER UART7_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE UART8 UART8_FCLK Func 48 UART8_GFCLK FUNC_192M_CLK DPLL_PER UART8_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE UART9 UART9_FCLK Func 48 UART9_GFCLK FUNC_192M_CLK DPLL_PER UART9_ICLK Int 266 L4PER2_L3_GICLK CORE_X2_CLK DPLL_CORE UART10_FCLK Func 48 UART10_GFCLK FUNC_192M_CLK DPLL_PER UART10_ICLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE UART5 UART10 USB1 166 SYS_CLK2 Specifications USB1_MICLK Int 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE USB3PHY_REF_C LK Func 34.3 USB_LFPS_TX_GFCL K CORE_USB_OTG_ SS_LFPS_TX_CLK DPLL_CORE USB2PHY1_TREF _CLK Func 38.4 USB_OTG_SS_REF_C LK SYS_CLK1 OSC1 USB2PHY1_REF_ CLK Func 960 L3INIT_960M_GFCLK L3INIT_960_GFCL K DPLL_USB Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-9. Maximum Supported Frequency (continued) Module Clock Sources Instance Name Input Clock Name Clock Type Max. Clock Allowed (MHz) PRCM Clock Name PLL / OSC / Source Clock Name PLL / OSC / Source Name USB2 USB2_MICLK Int 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE USB2PHY2_TREF _CLK Func 38.4 USB_OTG_SS_REF_C LK SYS_CLK1 OSC1 USB2PHY2_REF_ CLK Func 960 L3INIT_960M_GFCLK L3INIT_960_GFCL K DPLL_USB USB3 USB3_MICLK Int 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE USB3PHY_PWRS_ CLK Func 38.4 USB_OTG_SS_REF_C LK SYS_CLK1 OSC1 USB4_MICLK Int 266 L3INIT_L3_GICLK CORE_X2_CLK DPLL_CORE DPLL_USBSS_RE F_CLK Func 38.4 USB_OTG_SS_REF_C LK SYS_CLK1 OSC1 USB_PHY1_CORE USB2PHY1_WKUP _CLK Func 0.032 COREAON_32K_GFCL K SYS_32K RTC Oscillator USB_PHY2_CORE USB2PHY2_WKUP _CLK Func 0.032 COREAON_32K_GFCL K SYS_32K RTC Oscillator USB_PHY3_CORE USB3PHY_WKUP_ CLK Func 0.032 COREAON_32K_GFCL K SYS_32K RTC Oscillator USB4 VCP1 VCP1_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE VCP2 VCP2_CLK Int 266 L3MAIN1_L3_GICLK CORE_X2_CLK DPLL_CORE VIP1 L3_CLK_PROC_CL K Int & Func 266 VIP1_GCLK L3_CLK_PROC_CL K Int & Func 266 L3_CLK_PROC_CL K Int & Func 266 VPE L3_CLK_PROC_CL K Int & Func 300 VPE_GCLK WD_TIMER1 PIOCPCLK Int 38.4 WKUPAON_GICLK VIP2 VIP3 WD_TIMER2 VIP3_GCLK DPLL_CORE DPLL_CORE CORE_X2_CLK DPLL_CORE CORE_ISS_MAIN_ CLK DPLL_CORE CORE_X2_CLK DPLL_CORE CORE_ISS_MAIN_ CLK DPLL_CORE CORE_ISS_MAIN_ CLK DPLL_CORE VIDEO1_CLKOUT4 DPLL_VIDEO1 SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE RC oscillator PITIMERCLK Func 0.032 OSC_32K_CLK RC_CLK WD_TIMER2_ICLK Int 38.4 WKUPAON_GICLK SYS_CLK1 OSC1 DPLL_ABE_X2_CL K DPLL_ABE WKUPAON_32K_G FCLK RTC Oscillator WD_TIMER2_FCL K 5.6 VIP2_GCLK CORE_X2_CLK CORE_ISS_MAIN_ CLK Func 0.032 WKUPAON_SYS_GFC LK Power Consumption Summary NOTE Maximum power consumption for this SoC depends on the specific use conditions for the end system. Contact your TI representative for assistance in estimating maximum power consumption for the end system use case. 5.7 Electrical Characteristics Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 167 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com NOTE The data specified in Section 5.7.1 through Section 5.7.14 are subject to change. NOTE The interfaces or signals described in Section 5.7.1 through Section 5.7.14 correspond to the interfaces or signals available in multiplexing mode 0 (Function 1). All interfaces or signals multiplexed on the balls described in these tables have the same DC electrical characteristics, unless multiplexing involves a PHY/GPIO combination in which case different DC electrical characteristics are specified for the different multiplexing modes (Functions). 5.7.1 LVCMOS DDR DC Electrical Characteristics Table 5-10 summarizes the DC electrical characteristics for LVCMOS DDR Buffers. NOTE For more information on the I/O cell configurations (i[2:0], sr[1:0]), see the Chapter Control Module of the Device TRM. 168 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-10. LVCMOS DDR DC Electrical Characteristics PARAMETER MIN NOM MAX UNIT Signal Names in MUXMODE 0 (Single-Ended Signals): ddr1_d[31:0], ddr1_a[15:0], ddr1_dqm[3:0], ddr1_ba[2:0], ddr1_csn[0], ddr1_cke, ddr1_odt[0], ddr1_casn, ddr1_rasn, ddr1_wen, ddr1_rst, ddr1_ecc_d[7:0], ddr1_dqm_ecc, ddr2_d[31:0], ddr2_a[15:0], ddr2_dqm[3:0], ddr2_ba[2:0], ddr2_csn[0], ddr2_cke, ddr2_odt[0], ddr2_casn, ddr2_rasn, ddr2_wen, ddr2_rst; Balls: AA28 / AA25 / AA26 / Y24 / AA24 / Y23 / Y22 / AA23 / Y20 / AB27 / Y19 / AC27 / AC28 / AB28 / W20 / V20 / AD25 / AC24 / AC25 / AE26 / AF28 / AG27 / AF27 / AC23 / AE23 / AF23 / AE24 / AF24 / AH26 / AG26 / AF26 / AF25 / AD18 / AE17 / AF18 / AC21 / AD22 / AD21 / AE22 / AF22 / AE21 / AE21 / AH22 / AF21 / AB19 / AC20 / AC19 / AD20 / AA27 / AC26 / AB23 / AD23 / AB18 / AE18 / AF17 / AH23 / AG22 / AE20 / AC18 / AF20 / AH21 / AG21 / Y26 / V25 / V24 / Y25 / W23 / W19 / V23 / W22 / V26 / M26 / M25 / M24 / M23 / L28 / L25 / L26 / L27 / J20 / K22 / J23 / L24 / L23 / K21 / K20 / L22 / J24 / J26 / J25 / G26 / H26 / H24 / H25 / H23 / E28 / E27 / F27 / F26 / F24 / F25 / G25 / E26 / U22 / R22 / T22 / N28 / P26 / N23 / N27 / P27 / N20 / P25 / P22 / P23 / R27 / R28 / R26 / R25 / M22 / K23 / G24 / F28 / U26 / U27 / U23 / P24 / U24 / R23 / U28 / T23 / U25 / R24; Driver Mode VOH High-level output threshold (IOH = 0.1 mA) VOL Low-level output threshold (IOL = 0.1 mA) CPAD Pad capacitance (including package capacitance) ZO Output impedance (drive strength) 0.9*VDDS V l[2:0] = 000 (Imp80) 80 l[2:0] = 001 (Imp60) 60 l[2:0] = 010 (Imp48) 48 l[2:0] = 011 (Imp40) 40 l[2:0] = 100 (Imp34) 34 0.1*VDDS V 3 pF Ω Single-Ended Receiver Mode VIH High-level input threshold DDR3/DDR3L VREF+0.1 VDDS+0.2 DDR2 VREF+0.125 VDDS+0.3 DDR3/DDR3L -0.2 VREF-0.1 -0.3 VREF-0.125 VREF 10%vdds VREF+ 10%vdds V 3 pF VIL Low-level input threshold VCM Input common-mode voltage CPAD Pad capacitance (including package capacitance) DDR2 V V Signal Names in MUXMODE 0 (Differential Signals): ddr1_dqs[3:0], ddr1_dqsn[3:0], ddr1_ck, ddr1_nck, ddr2_dqs[3:0], ddr2_dqsn[3:0], ddr2_ck, ddr2_nck, ddr1_dqs_ecc, ddr1_dqsn_ecc Bottom Balls: Y28 / AD27 / AE27 / AH25 / Y27 / AD28 / AE28 / AG25 / AG24 / AH24 / M28 / K27 / H27 / G28 / M27 / K28 / H28 / G27 / T28 / T27 / V27 / V28 Driver Mode VOH High-level output threshold (IOH = 0.1 mA) VOL Low-level output threshold (IOL = 0.1 mA) CPAD Pad capacitance (including package capacitance) ZO Output impedance (drive strength) 0.9*VDDS V l[2:0] = 000 (Imp80) 80 l[2:0] = 001 (Imp60) 60 l[2:0] = 010 (Imp48) 48 l[2:0] = 011 (Imp40) 40 l[2:0] = 100 (Imp34) 34 0.1*VDDS V 3 pF Ω Single-Ended Receiver Mode VIH High-level input threshold DDR3/DDR3L VREF+0.1 VDDS+0.2 DDR2 VREF+0.125 VDDS+0.3 V Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 169 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-10. LVCMOS DDR DC Electrical Characteristics (continued) PARAMETER MIN VIL Low-level input threshold DDR3/DDR3L VCM Input common-mode voltage CPAD Pad capacitance (including package capacitance) DDR2 MAX UNIT -0.2 NOM VREF-0.1 V -0.3 VREF-0.125 VREF 10%vdds VREF+ 10%vdds V 3 pF V Differential Receiver Mode VSWING Input voltage swing DDR3/DDR3L 0.2 vdds+0.4 DDR2 0.25 vdds+0.6 VREF 10%vdds VREF+ 10%vdds VCM Input common-mode voltage CPAD Pad capacitance (including package capacitance) 3 pF 1. VDDS in this table stands for corresponding power supply (i.e. vdds_ddr1 or vdds_ddr2). For more information on the power supply name and the corresponding ball, see Table 4-2, POWER [11] column. 2. VREF in this table stands for corresponding Reference Power Supply (i.e. ddr1_vref0 or ddr2_vref0). For more information on the power supply name and the corresponding ball, see Table 4-2, POWER [11] column. 5.7.2 HDMIPHY DC Electrical Characteristics The HDMIPHY DC Electrical Characteristics are compliant with the HDMI 1.4a specification and are not reproduced here. 5.7.3 Dual Voltage LVCMOS I2C DC Electrical Characteristics Table 5-11 summarizes the DC electrical characteristics for Dual Voltage LVCMOS I2C Buffers. NOTE For more information on the I/O cell configurations, see the Control Module section of the Device TRM. Table 5-11. Dual Voltage LVCMOS I2C DC Electrical Characteristics PARAMETER MIN NOM MAX UNIT Signal Names in MUXMODE 0: i2c2_scl; i2c1_scl; i2c1_sda; i2c2_sda; Balls: F17 / C20 / C21 / C25 I2C Standard Mode – 1.8 V 170 VIH Input high-level threshold VIL Input low-level threshold Vhys Hysteresis 0.7*VDDS V 0.3*VDDS V 0.1*VDDS V IIN Input current at each I/O pin with an input voltage between 0.1*VDDS to 0.9*VDDS 12 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 12 µA CIN Input capacitance 10 pF 0.2*VDDS V VOL3 Output low-level threshold open-drain at 3-mA sink current IOLmin Low-level output current @VOL=0.2*VDDS Specifications 3 mA Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-11. Dual Voltage LVCMOS I2C DC Electrical Characteristics (continued) PARAMETER tOF MIN Output fall time from VIHmin to VILmax with a bus capacitance CB from 5 pF to 400 pF NOM MAX UNIT 250 ns I2C Fast Mode – 1.8 V VIH Input high-level threshold VIL Input low-level threshold Vhys Hysteresis 0.7*VDDS V 0.3*VDDS V 0.1*VDDS V IIN Input current at each I/O pin with an input voltage between 0.1*VDDS to 0.9*VDDS 12 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 12 µA CIN Input capacitance 10 pF 0.2*VDDS V VOL3 Output low-level threshold open-drain at 3-mA sink current IOLmin Low-level output current @VOL=0.2*VDDS tOF Output fall time from VIHmin to VILmax with a bus capacitance CB from 10 pF to 400 pF 3 20+0.1*Cb mA 250 ns I2C Standard Mode – 3.3 V VIH Input high-level threshold VIL Input low-level threshold Vhys Hysteresis 0.7*VDDS V 0.3*VDDS V 0.05*VDDS V IIN Input current at each I/O pin with an input voltage between 0.1*VDDS to 0.9*VDDS 31 80 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 31 80 µA CIN Input capacitance 10 pF VOL3 Output low-level threshold open-drain at 3-mA sink current 0.4 V IOLmin Low-level output current @VOL=0.4V 3 mA IOLmin Low-level output current @VOL=0.6V for full drive load (400pF/400KHz) 6 mA tOF Output fall time from VIHmin to VILmax with a bus capacitance CB from 5 pF to 400 pF 250 ns I2C Fast Mode – 3.3 V VIH Input high-level threshold VIL Input low-level threshold Vhys Hysteresis 0.7*VDDS V 0.3*VDDS V 0.05*VDDS V IIN Input current at each I/O pin with an input voltage between 0.1*VDDS to 0.9*VDDSS 31 80 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 31 80 µA CIN Input capacitance 10 pF VOL3 Output low-level threshold open-drain at 3-mA sink current 0.4 V IOLmin Low-level output current @VOL=0.4V 3 mA IOLmin Low-level output current @VOL=0.6V for full drive load (400pF/400KHz) 6 mA Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 171 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-11. Dual Voltage LVCMOS I2C DC Electrical Characteristics (continued) PARAMETER tOF MAX UNIT Output fall time from VIHmin to VILmax with a bus capacitance CB from 10 pF to 200 pF (Proper External Resistor Value should be used as per I2C spec) 20+0.1*Cb MIN NOM 250 ns Output fall time from VIHmin to VILmax with a bus capacitance CB from 300 pF to 400 pF (Proper External Resistor Value should be used as per I2C spec) 40 290 1. VDDS in this table stands for corresponding power supply (i.e. vddshv3). For more information on the power supply name and the corresponding ball, see Table 4-2, POWER [11] column. 5.7.4 IQ1833 Buffers DC Electrical Characteristics Table 5-12 summarizes the DC electrical characteristics for IQ1833 Buffers. Table 5-12. IQ1833 Buffers DC Electrical Characteristics PARAMETER MIN NOM MAX UNIT Signal Names in MUXMODE 0: tclk; Balls: E20; 1.8-V Mode VIH Input high-level threshold (Does not meet JEDEC VIH) VIL Input low-level threshold (Does not meet JEDEC VIL) VHYS Input hysteresis voltage IIN Input current at each I/O pin CPAD Pad capacitance (including package capacitance) 0.75 * VDDS V 0.25 * VDDS 100 V mV 2 11 µA 1 pF 3.3-V Mode VIH Input high-level threshold (Does not meet JEDEC VIH) VIL Input low-level threshold (Does not meet JEDEC VIL) VHYS Input hysteresis voltage IIN Input current at each I/O pin CPAD Pad capacitance (including package capacitance) 5.7.5 2.0 V 0.6 400 V mV 5 11 µA 1 pF MAX UNIT IHHV1833 Buffers DC Electrical Characteristics Table 5-13 summarizes the DC electrical characteristics for IHHV1833 Buffers. Table 5-13. IHHV1833 Buffers DC Electrical Characteristics PARAMETER MIN NOM Signal Names in MUXMODE 0: porz / rtc_iso / rtc_porz / wakeup [3:0]; Balls: F22 / AF14 / AB17 / AD17 / AC17 / AB16 / AC16; 1.8-V Mode VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage IIN Input current at each I/O pin CPAD Pad capacitance (including package capacitance) 1.2 V 0.4 40 0.02 V mV 1 µA 1 pF 3.3-V Mode 172 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 5-13. IHHV1833 Buffers DC Electrical Characteristics (continued) PARAMETER MIN VIH Input high-level threshold 1.2 VIL Input low-level threshold VHYS Input hysteresis voltage 40 IIN Input current at each I/O pin 5 CPAD Pad capacitance (including package capacitance) 5.7.6 NOM MAX UNIT V 0.4 V mV 8 µA 1 pF MAX UNIT LVCMOS OSC Buffers DC Electrical Characteristics Table 5-14 summarizes the DC electrical characteristics for LVCMOS OSC Buffers. Table 5-14. LVCMOS OSC Buffers DC Electrical Characteristics PARAMETER MIN NOM Signal Names in MUXMODE 0: rtc_osc_xi_clkin32 / rtc_osc_xo; Balls: AE14 / AD14; 1.8-V Mode 5.7.7 VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage CPAD Pad capacitance (including package capacitance) 0.65 * VDDS V 0.35 * VDDS V 150 mV 3 pF MAX UNIT ILVDS18 Buffers DC Electrical Characteristics Table 5-15 summarizes the DC electrical characteristics for ILVDS18 Buffers. Table 5-15. ILVDS18 Buffers DC Electrical Characteristics PARAMETER MIN NOM Signal Names in MUXMODE 0: mlbp_clk_n / mlbp_clk_p; Balls: AB2 / AB1; 1.8-V Mode VIN (DC) single ended input voltage Input voltage VIH/VIL (DC) Input high-level threshold VHYS Input hysteresis voltage CPAD Pad capacitance (including package capacitance) 5.7.8 0.5 VDDSVSWING VCM ± 50mV V NONE mV 4 pF MAX UNIT BMLB18 Buffers DC Electrical Characteristics Table 5-16 summarizes the DC electrical characteristics for BMLB18 Buffers. Table 5-16. BMLB18 Buffers DC Electrical Characteristics PARAMETER MIN NOM Signal Names in MUXMODE 0: mlbp_dat_n / mlbp_dat_p / mlbp_sig_n / mlbp_sig_p; Balls: AA2 / AA1 / AC2 / AC1; 1.8-V Mode Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 173 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-16. BMLB18 Buffers DC Electrical Characteristics (continued) PARAMETER MIN VIH/VIL Input high-level threshold VHYS Input hysteresis voltage VOD Differential output voltage (measured with 50ohm resistor between PAD and PADN) VCM Common mode output voltage CPAD Pad capacitance (including package capacitance) 5.7.9 NOM MAX VCM ± 50mV UNIT V NONE mV 300 500 mV 1 1.5 V 4 pF MAX UNIT BC1833IHHV Buffers DC Electrical Characteristics Table 5-17 summarizes the DC electrical characteristics for BC1833IHHV Buffers. Table 5-17. BC1833IHHV Buffers DC Electrical Characteristics PARAMETER MIN NOM Signal Names in MUXMODE 0: on_off; Balls: Y11; 1.8-V Mode VOH Output high-level threshold (IOH = 2 mA) VDDS0.45 V VOL Output low-level threshold (IOL = 2 mA) IDRIVE Pin Drive strength at PAD Voltage = 0.45V or VDDS-0.45V 6 IIN Input current at each I/O pin 6 12 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 6 µA CPAD Pad capacitance (including package capacitance) 4 pF 0.45 V mA 3.3-V Mode VOH Output high-level threshold (IOH =100µA) VOL Output low-level threshold (IOL = 100µA) VDDS-0.2 V IDRIVE Pin Drive strength at PAD Voltage = 0.45V or VDDS-0.45V IIN Input current at each I/O pin 60 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 60 µA CPAD Pad capacitance (including package capacitance) 4 pF 0.2 6 V mA 5.7.10 USBPHY DC Electrical Characteristics NOTE USB1 instance is compliant with the USB3.0 SuperSpeed Transmitter and Receiver Normative Electrical Parameters as defined in the USB3.0 Specification Rev 1.0 dated Jun 6, 2011. NOTE USB1 and USB2 Electrical Characteristics are compliant with USB2.0 Specification Rev 2.0 dated April 27, 2000 including ECNs and Errata as applicable. 174 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 5.7.11 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Dual Voltage SDIO1833 DC Electrical Characteristics Table 5-18 summarizes the DC electrical characteristics for Dual Voltage SDIO1833 Buffers. Table 5-18. Dual Voltage SDIO1833 DC Electrical Characteristics PARAMETER MIN NOM MAX UNIT Signal Names in Mode 0: mmc1_clk, mmc1_cmd, mmc1_data[3:0] Bottom Balls: W6 / Y6 / AA6 / Y4 / AA5 / Y3 1.8-V Mode VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage IIN Input current at each I/O pin 30 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 30 µA IIN with Input current at each I/O pin with weak pulldown enabled measured when PAD = VDDS 50 120 210 µA Input current at each I/O pin with weak pullup enabled measured when PAD = 0 60 120 200 µA 5 pF pulldown enabled IIN with pullup enabled CPAD Pad capacitance (including package capacitance) VOH Output high-level threshold (IOH = 2 mA) VOL Output low-level threshold (IOL = 2 mA) 1.27 V 0.58 50 V mV (2) 1.4 V 0.45 V 3.3-V Mode VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage IIN Input current at each I/O pin 110 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 110 µA IIN with Input current at each I/O pin with weak pulldown enabled measured when PAD = VDDS 40 100 290 µA Input current at each I/O pin with weak pullup enabled measured when PAD = 0 10 100 290 µA 5 pF pulldown enabled IIN with pullup enabled CPAD Pad capacitance (including package capacitance) VOH Output high-level threshold (IOH = 2 mA) VOL Output low-level threshold (IOL = 2 mA) 0.625 × VDDS V 0.25 × VDDS 40(2) V mV 0.75 × VDDS V 0.125 × VDDS V (1) VDDS in this table stands for corresponding power supply. For more information on the power supply name and the corresponding ball, see Table 4-2, POWER [11] column. (2) Hysteresis is enabled/disabled with CTRL_CORE_CONTROL_HYST_1.SDCARD_HYST register. 5.7.12 Dual Voltage LVCMOS DC Electrical Characteristics Table 5-19 summarizes the DC electrical characteristics for Dual Voltage LVCMOS Buffers. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 175 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 5-19. Dual Voltage LVCMOS DC Electrical Characteristics PARAMETER MIN NOM MAX UNIT 1.8-V Mode VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage VOH Output high-level threshold (IOH = 2 mA) VOL Output low-level threshold (IOL = 2 mA) IDRIVE Pin Drive strength at PAD Voltage = 0.45V or VDDS-0.45V IIN Input current at each I/O pin 16 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 16 µA IIN with pulldown Input current at each I/O pin with weak pulldown enabled measured when PAD = VDDS 50 120 210 µA Input current at each I/O pin with weak pullup enabled measured when PAD = 0 60 120 200 µA enabled CPAD Pad capacitance (including package capacitance) 4 pF ZO Output impedance (drive strength) enabled IIN with pullup 0.65*VDDS V 0.35*VDDS 100 V mV VDDS-0.45 V 0.45 6 V mA Ω 40 3.3-V Mode VIH Input high-level threshold VIL Input low-level threshold VHYS Input hysteresis voltage VOH Output high-level threshold (IOH =100 µA) VOL Output low-level threshold (IOL = 100 µA) IDRIVE Pin Drive strength at PAD Voltage = 0.45V or VDDS-0.45V IIN Input current at each I/O pin 65 µA IOZ IOZ(IPAD Current) for BIDI cell. This current is contributed by the tristated driver leakage + input current of the Rx + weak pullup/pulldown leakage. PAD is swept from 0 to VDDS and the Max(I(PAD)) is measured and is reported as IOZ 65 µA IIN with pulldown Input current at each I/O pin with weak pulldown enabled measured when PAD = VDDS 40 100 200 µA Input current at each I/O pin with weak pullup enabled measured when PAD = 0 10 100 290 µA enabled CPAD Pad capacitance (including package capacitance) 4 pF ZO Output impedance (drive strength) enabled IIN with pullup 2 V 0.8 200 V mV VDDS-0.2 V 0.2 6 V mA 40 Ω 1. VDDS in this table stands for corresponding power supply. For more information on the power supply name and the corresponding ball, see Table 4-2, POWER [11] column. 5.7.13 SATAPHY DC Electrical Characteristics NOTE The SATA module is compliant with the electrical parameters specified in the SATA-IO SATA Specification, Revision 3.2, August 7, 2013. 176 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 5.7.14 PCIEPHY DC Electrical Characteristics NOTE The PCIe interfaces are compliant with the electrical parameters specified in PCI Express® Base Specification Revision 2.0. 5.8 Thermal Resistance Characteristics For reliability and operability concerns, the maximum junction temperature of the Device has to be at or below the TJ value identified in Table 5-4, Recommended Operating Conditions. A BCI compact thermal model for this Device is available and recommended for use when modeling thermal performance in a system. Therefore, it is recommended to perform thermal simulations at the system level with the worst case device power consumption. 5.8.1 Package Thermal Characteristics Table 5-20 provides the thermal resistance characteristics for the package used on this device. NOTE Power dissipation of 1.5 W and an ambient temperature of 85ºC is assumed for ABC package. Table 5-20. Thermal Resistance Characteristics PARAMET ER DESCRIPTION °C/W(1) AIR FLOW (m/s)(2) T1 RΘJC Junction-to-case 0.82 N/A T2 RΘJB Junction-to-board 3.78 N/A Junction-to-free air 11.1 0 8.8 1 8.0 2 T6 7.5 3 T7 0.62 0 T8 0.66 1 NO. T3 T4 T5 T9 RΘJA ΨJT Junction-to-moving air Junction-to-package top 0.66 2 T10 0.66 3 T11 3.43 0 3.22 1 3.12 2 3.04 3 T12 T13 ΨJB Junction-to-board T14 (1) These values are based on a JEDEC defined 2S2P system (with the exception of the Theta JC [RΘJC] value, which is based on a JEDEC defined 1S0P system) and will change based on environment as well as application. For more information, see these EIA/JEDEC standards: – JESD51-2, Integrated Circuits Thermal Test Method Environment Conditions - Natural Convection (Still Air) – JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages – JESD51-6, Integrated Circuit Thermal Test Method Environmental Conditions - Forced Convection (Moving Air) – JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages – JESD51-9, Test Boards for Area Array Surface Mount Packages (2) m/s = meters per second Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 177 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 5.9 www.ti.com Power Supply Sequences This section describes the power-up and power-down sequence required to ensure proper device operation. The power supply names described in this section comprise a superset of a family of compatible devices. Some members of this family will not include a subset of these power supplies and their associated device modules. Refer to the Section 4.2, Ball Characteristics of the Section 4, Terminal Configuration and Functions to determine which power supplies are applicable. Figure 5-1 and Figure 5-2, describes the device Power Sequencing when RTC-mode is used. 178 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Note 4 vdda_rtc Note 5 (3) vdds18v, vdds_mlbp, vdds18v_ddr1, ) vdds18v_ddr2 vdda_abe_per, vdda_ddr, vdda_debug, vdda_dsp_eve, vdda_gmac_core, vdda_gpu, vdda_iva, vdda_video, vdda_mpu, vdda_osc vdd_rtc (3) vdds_ddr2, vdds_ddr1, ddr1_vref0, ddr2_vref0 VD_CORE BOOT voltage vdd VD_MPU BOOT voltage vdd_mpu VD_IVA BOOT voltage vdd_iva VD_GPU BOOT voltage vdd_gpu VD_DSPEVE BOOT voltage vdd_dspeve vdda_usb1, vdda_usb2, vdda_hdmi, vdda_pcie, vdda_pcie0, vdda_pcie1, vdda_sata, vdda_usb3 vddshv5 (3) Note 6 vddshv1, vddshv2, vddshv3, vddshv4, vddshv6, vddshv7, vddshv9, vddshv10, vddshv11 vdda33v_usb1, vdda33v_usb2 Note 7 vddshv8 xi_osc0 Note 9 rtc_porz Note 11 resetn/porz Note 12 sysboot[15:0] Note 13 Valid Config Note 14 rstoutn SPRS85v_ELCH_01 Figure 5-1. Power-Up Sequencing (1) Grey shaded areas are windows where it is valid to ramp the voltage rail. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 179 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (2) Blue dashed lines are not valid windows but show alternate ramp possibilities based on the associated note. (3) If RTC-mode is used then vdda_rtc, vdd_rtc and vddshv5 must be individually powered with separate power supplies and cannot be combined with other rails. (4) vdd must ramp before or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (5) vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva can be ramped at the same time or can be staggered. (6) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18v. (7) vddshv8 is separated out to show support for dual voltage. If single voltage is used then vddshv8 can be combined with other vddshvn rails but vddshv8 must ramp after vdd. (8) vdds and vdda rails must not be combined together. (9) Pulse duration: rtc_porz must remain low 1ms after vdda_rtc, vddshv5, and vdd_rtc are ramped and stable. (10) The SYS_32K source must be stable and at a valid frequency 1ms prior to de-asserting rtc_porz high. (11) Pulse duration: resetn/porz must remain low a minimum of 12P(15) after xi_osc0 is stable and at a valid frequency. (12) Setup time: sysboot[15:0] pins must be valid 2P(15) before porz is de-asserted high. (13) Hold time: sysboot[15:0] pins must be valid 15P(15) after porz is de-asserted high. (14) resetn to rstoutn delay is 2ms. (15) P = 1/(SYS_CLK1/610) frequency in ns. 180 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Note 5 Note 6 porz Note 8 vddshv8 vdda33v_usb1, vdda33v_usb2 Note 7 vddshv1, vddshv2, vddshv3, vddshv4, vddshv6, vddshv7, vddshv9, vddshv10, vddshv11 vdda_usb1, vdda_usb2, vdda_hdmi, vdda_pcie, vdda_pcie0, vdda_pcie1, vdda_sata, vdda_usb3 vddshv5 (4) vdd_dspeve vdd_gpu vdd_iva vdd_mpu vdd vdds_ddr2, vdds_ddr1, ddr1_vref0, ddr2_vref0 vdda_abe_per, vdda_ddr, vdda_debug, vdda_dsp_eve, vdda_gmac_core, vdda_gpu, vdda_iva, vdda_video, vdda_mpu, vdda_osc vdd_rtc (4) vdds18v, vdds_mlbp, vdds18v_ddr1, vdds18v_ddr2 vdda_rtc (4) xi_osc0 SPRS85v_ELCH_02 Figure 5-2. Power-Down Sequencing (1) xi_osc0 can be turned off anytime after porz assertion and must be turned off before vdda_osc voltage rail is shutdown. (2) Grey shaded areas are windows where it is valid to ramp the voltage rail. (3) Blue dashed lines are not valid windows but show alternate ramp possibilities based on the associated note. (4) If RTC-mode is supported then vdda_rtc, vdd_rtc and vddshv5 must be individually powered with separate power supplies and cannot be combined with other rails. (5) vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva can be ramped at the same time or can be staggered. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 181 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (6) vdd must ramp after or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (7) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18v. vddshv[1-7,9-11] is allowed to ramp down at either of the two points shown in the timing diagram in either 1.8V mode or in 3.3V mode. If vddshv[1-7,9-11] ramps down at the later time in the diagram then the board design must guarantee that the vddshv[1-7,9-11] rail is never higher than 2.0 V above the vdds18v rail. (8) vddshv8 is separated out to show support for dual voltage. If a dedicated LDO/supply source is used for vddshv8, then vddshv8 ramp down should occur at one of the two earliest points in the timing diagram. If vddshv8 is powered by the same supply source as the other vddshvn rails, then it is allowed to ramp down at either of the last two points in the timing diagram. 182 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Figure 5-3 describes the RTC-mode Power Sequencing. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 183 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Figure 5-3. RTC Mode Sequencing (1) Grey shaded areas are windows where it is valid to ramp the voltage rail. (2) Blue dashed lines are not valid windows but show alternate ramp possibilities based on the associated note. 184 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (3) vdd must ramp down after or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (4) vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva can be ramped at the same time or can be staggered. (5) vdd must ramp up before or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (6) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18v. (7) vddshv8 is separated out to show support for dual voltage. If single voltage is used then vddshv8 can be combined with other vddshvn rails but vddshv8 must ramp down before vdd and must ramp up after vdd. (8) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18v. vddshv[1-7,9-11] is allowed to ramp down at either of the two points shown in the timing diagram in either 1.8V mode or in 3.3V mode. If vddshv[1-7,9-11] ramps down at the later time in the diagram then the board design must guarantee that the vddshvn rail is never higher than 2.0 V above the vdds18v rail. (9) vddshv8 is separated out to show support for dual voltage. If a dedicated LDO/supply source is used for vddshv8, then vddshv8 ramp down should occur at one of the two earliest points in the timing diagram. If vddshv8 is powered by the same supply source as the other vddshvn rails, then it is allowed to ramp down at either of the last two points in the timing diagram. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 185 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Figure 5-4 and Figure 5-5, describe the device Power Sequencing when RTC-mode is NOT used. Note 4 Note 5 vdds18v, vdds_mlbp, vdds18v_ddr1, (3) vdds18v_ddr2, vdda_rtc vdda_abe_per, vdda_ddr, vdda_debug, vdda_dsp_eve, vdda_gmac_core, vdda_gpu, vdda_iva, vdda_video, vdda_mpu, vdda_osc vdds_ddr2, vdds_ddr1, ddr1_vref0, ddr2_vref0 VD_CORE BOOT voltage vdd, vdd_rtc (3) VD_MPU BOOT voltage vdd_mpu VD_IVA BOOT voltage vdd_iva VD_GPU BOOT voltage vdd_gpu VD_DSPEVE BOOT voltage vdd_dspeve vdda_usb1, vdda_usb2, vdda_hdmi, vdda_pcie, vdda_pcie0, vdda_pcie1, vdda_sata, vdda_usb3 vddshv1, vddshv2, vddshv3, vddshv4, (3) vddshv5 , vddshv6, vddshv7, vddshv9, vddshv10, vddshv11 Note 6 vdda33v_usb1, vdda33v_usb2 Note 7 vddshv8 xi_osc0 Note 9 rtc_porz Note 11 resetn/porz Note 12 sysboot[15:0] Note 13 Valid Config Note 14 rstoutn SPRS85v_ELCH_04 Figure 5-4. Power-Up Sequencing (1) Grey shaded areas are windows where it is valid to ramp the voltage rail. (2) Blue dashed lines are not valid windows but show alternate ramp possibilities based on the associated note. (3) If RTC-mode is not supported then the following combinations are approved: - vdda_rtc can be combined with vdds18v - vdd_rtc can be combined with vdd 186 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 - vddshv5 can be combined with other 1.8V or 3.3V vddshvn rails. If combinations listed above are not followed then sequencing for these 3 voltage rails should follow the RTC mode timing requirements. (4) vdd must ramp before or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (5) vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva can be ramped at the same time or can be staggered. (6) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18v. (7) vddshv8 is separated out to show support for dual voltage. If single voltage is used then vddshv8 can be combined with other vddshvn rails but vddshv8 must ramp after vdd. (8) vdds and vdda rails must not be combined together, with the one exception of vdda_rtc when RTC-mode is not supported. (9) Pulse duration: rtc_porz must remain low 1ms after vdda_rtc, vddshv5, and vdd_rtc are ramped and stable. (10) The SYS_32K source must be stable and at a valid frequency 1ms prior to de-asserting rtc_porz high. (11) Pulse duration: resetn/porz must remain low a minimum of 12P(15) after xi_osc0 is stable and at a valid frequency. (12) Setup time: sysboot[15:0] pins must be valid 2P(15) before porz is de-asserted high. (13) Hold time: sysboot[15:0] pins must be valid 15P(15) after porz is de-asserted high. (14) resetn to rstoutn delay is 2ms. (15) P = 1/(SYS_CLK1/610) frequency in ns. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 187 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Note 5 Note 6 porz Note 8 vddshv8 vdda33v_usb1, vdda33v_usb2 Note 7 vdda_usb1, vdda_usb2, vdda_hdmi, vdda_pcie, vdda_pcie0, vdda_pcie1, vdda_sata, vdda_usb3 vdd_dspeve vdd_gpu vdd_iva vdd_mpu vdd, vdd_rtc (4) vdds_ddr2, vdds_ddr1, ddr1_vref0, ddr2_vref0 vdda_abe_per, vdda_ddr, vdda_debug, vdda_dsp_eve, vdda_gmac_core, vdda_gpu, vdda_iva, vdda_video, vdda_mpu, vdda_osc xi_osc0 SPRS85v_ELCH_05 Figure 5-5. Power-Down Sequencing (1) Grey shaded areas are windows where it is valid to ramp the voltage rail. (2) Blue dashed lines are not valid windows but show alternate ramp possibilities based on the associated note. (3) xi_osc0 can be turned off anytime after porz assertion and must be turned off before vdda_osc voltage rail is shutdown. (4) If RTC-mode is not used then the following combinations are approved: - vdda_rtc can be combined with vdds18v - vdd_rtc can be combined with vdd - vddshv5 can be combined with other 1.8V or 3.3V vddshvn rails If combinations listed above are not followed then sequencing for these 3 voltage rails should follow the RTC mode timing requirements. (5) vdd_mpu, vdd_gpu, vdd_dspeve, vdd_iva can be ramped at the same time or can be staggered. (6) vdd must ramp after or at the same time as vdd_mpu, vdd_gpu, vdd_dspeve and vdd_iva. (7) If any of the vddshv[1-7,9-11] rails (not including vddshv8) are used as 1.8V only, then these rails can be combined with vdds18h. vddshv[1-7,9-11] is allowed to ramp down at either of the two points shown in the timing diagram in either 1.8V mode or in 3.3V mode. If vddshv[1-7,9-11] ramps down at the later time in the diagram then the board design must guarantee that the vddshv[1-7,9-11] rail is never higher than 2.0 V above the vdds18v rail. (8) vddshv8 is separated out to show support for dual voltage. If a dedicated LDO/supply source is used for vddshv8, then vddshv8 ramp down should occur at one of the two earliest points in the timing diagram. If vddshv8 is powered by the same supply source as the other 188 Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 vddshv[1-7,9-11] rails, then it is allowed to ramp down at either of the last two points in the timing diagram. Figure 5-6 describes vddshv[1-7,9-11] Supplies Falling Before vdds18v Supplies Delta. Figure 5-6. vddshv* Supplies Falling After vdds18v Supplies Delta (1) Vdelta MAX = 2V (2) If vddshv8 is powered by the same supply source as the other vddshv[1-7,9-11] rails. Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 189 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 6 Clock Specifications NOTE For more information, see Power, Reset, and Clock Management / PRCM Environment / External Clock Signal and Power Reset / PRCM Functional Description / PRCM Clock Manager Functional Description section of the Device TRM. NOTE Audio Back End (ABE) module is not supported for this family of devices, but “ABE” name is still present in some clock or DPLL names. The device operation requires the following clocks: • The 32 kHz frequency is used for low frequency operation. It supplies the wake-up domain for operation in lowest power mode. This is an optional clock and will be supplied by on chip divider + mux (FUNC_32K_CLK) incase it is not available on external pin. • The system clocks, SYS_CLKIN1(Mandatory) and SYS_CLKIN2(Optional) are the main clock sources of the device. They supply the reference clock to the DPLLs as well as functional clock to several modules. The Device also embeds an internal free-running 32-kHz oscillator that is always active as long as the the wake-up (WKUP) domain is supplied. Figure 6-1 shows the external input clock sources and the output clocks to peripherals. 190 Clock Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DEVICE rtc_osc_xi_clkin32 rtc_osc_xo From quartz (32 kHz) or from CMOS square clock source (32 kHz). To quartz (from oscillator output). rstoutn Warm reset output. resetn Device reset input. porz xi_osc0 Power ON Reset. From quartz (19.2, 20 or 27 MHz) or from CMOS square clock source (19.2, 20 or 27MHz). xo_osc0 To quartz (from oscillator output). xi_osc1 From quartz (range from 19.2 to 32 MHz) or from CMOS square clock source(range from 12 to 38.4 MHz). xo_osc1 To quartz (from oscillator output). clkout1 clkout2 Output clkout[3:1] clocks come from: • Either the input system clock and alternate clock (xi_osc0 or xi_osc1) • Or a CORE clock (from CORE output) • Or a 192-MHz clock (from PER DPLL output). clkout3 xref_clk0 xref_clk1 External Reference Clock [3:0]. For Audio and other Peripherals xref_clk2 xref_clk3 sysboot[15:0] Boot Mode Configuration Figure 6-1. Clock Interface 6.1 Input Clock Specifications 6.1.1 Input Clock Requirements • • • The source of the internal system clock (SYS_CLK1) could be either: – A CMOS clock that enters on the xi_osc0 ball (with xo_osc0 left unconnected on the CMOS clock case). – A crystal oscillator clock managed by xi_osc0 and xo_osc0. The source of the internal system clock (SYS_CLK2) could be either: – A CMOS clock that enters on the xi_osc1 ball (with xo_osc1 left unconnected on the CMOS clock case). – A crystal oscillator clock managed by xi_osc1 and xo_osc1. The source of the internal system clock (SYS_32K) could be either: – A CMOS clock that enters on the rtc_osc_xi_clkin32 ball and supports external LVCMOS clock generators – A crystal oscillator clock managed by rtc_osc_xi_clkin32 and rtc_osc_xo. Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 191 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 6.1.2 www.ti.com System Oscillator OSC0 Input Clock SYS_CLKIN1 is received directly from oscillator OSC0. For more information about SYS_CLKIN1 see Device TRM, Chapter: Power, Reset, and Clock Management. 6.1.2.1 OSC0 External Crystal An external crystal is connected to the device pins. Figure 6-2 describes the crystal implementation. Device xo_osc0 xi_osc0 vssa_osc0 Rd (Optional) Crystal Cf2 Cf1 Figure 6-2. Crystal Implementation NOTE The load capacitors, Cf1 and Cf2 in Figure 6-2, should be chosen such that the below equation is satisfied. CL in the equation is the load specified by the crystal manufacturer. All discrete components used to implement the oscillator circuit should be placed as close as possible to the associated oscillator xi_osc0, xo_osc0, and vssa_osc0 pins. CL= Cf1Cf2 (Cf1+Cf2) Figure 6-3. Load Capacitance Equation The crystal must be in the fundamental mode of operation and parallel resonant. Table 6-1 summarizes the required electrical constraints. Table 6-1. OSC0 Crystal Electrical Characteristics NAME fp DESCRIPTION Parallel resonance crystal frequency TYP MAX 19.2, 20, 27 UNIT MHz Cf1 Cf1 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 pF Cf2 Cf2 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 pF 100 Ω 19.2 MHz, 20 MHz, 27 MHz 7 pF 19.2 MHz, 20 MHz 7 pF 27 MHz 5 pF 19.2 MHz, 20 MHz 7 pF 5 pF 3 pF ESR(Cf1,Cf2) Crystal ESR ESR = 30 Ω ESR = 40 Ω ESR = 50 Ω CO Crystal shunt capacitance ESR = 60 Ω ESR = 80 Ω ESR = 100 Ω 192 MIN Clock Specifications 27 MHz Not Supported 19.2 MHz, 20 MHz 27 MHz Not Supported 19.2 MHz, 20 MHz 27 MHz - Not Supported - Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 6-1. OSC0 Crystal Electrical Characteristics (continued) NAME DESCRIPTION LM Crystal motional inductance for fp = 20 MHz CM Crystal motional capacitance tj(xiosc0) MIN TYP MAX UNIT 10.16 mH 3.42 (1) Frequency accuracy , xi_osc0 fF Ethernet and MLB not used ±200 Ethernet RGMII and RMII using derived clock ±50 Ethernet MII using derived clock ±100 MLB using derived clock ±50 ppm (1) Crystal characteristics should account for tolerance+stability+aging. When selecting a crystal, the system design must take into account the temperature and aging characteristics of a crystal versus the user environment and expected lifetime of the system. Table 6-2 details the switching characteristics of the oscillator and the requirements of the input clock. Table 6-2. Oscillator Switching Characteristics—Crystal Mode NAME DESCRIPTION fp Oscillation frequency tsX Start-up time 6.1.2.2 MIN TYP MAX 19.2, 20, 27 MHz UNIT MHz 4 ms OSC0 Input Clock A 1.8-V LVCMOS-Compatible Clock Input can be used instead of the internal oscillator to provide the SYS_CLKIN1 clock input to the system. The external connections to support this are shown in Figure 6-4. The xi_osc0 pin is connected to the 1.8-V LVCMOS-Compatible clock source. The xi_osc0 pin is left unconnected. The vssa_osc0 pin is connected to board ground (VSS). Device xi_osc0 xo_osc0 vssa_osc0 NC SPRS85v_CLK_09 Figure 6-4. 1.8-V LVCMOS-Compatible Clock Input Table 6-3 summarizes the OSC0 input clock electrical characteristics. Table 6-3. OSC0 Input Clock Electrical Characteristics—Bypass Mode NAME f DESCRIPTION MIN Frequency CIN Input capacitance IIN Input current (3.3V mode) TYP MAX 19.2, 20, 27 UNIT MHz 2.184 2.384 2.584 pF 4 6 10 µA Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 193 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 6-4 details the OSC0 input clock timing requirements. Table 6-4. OSC0 Input Clock Timing Requirements NAME DESCRIPTION 1/ CK0 tc(xiosc0) CK1 Frequency, xi_osc0 TYP MAX 19.2, 20, 27 UNIT MHz 0.55 * tc(xiosc0) ns 0.01 × tc(xiosc0) ns Rise time, xi_osc0 5 ns Fall time, xi_osc0 5 ns tw(xiosc0) Pulse duration, xi_osc0 low or high tj(xiosc0) Period jitter(1), xi_osc0 tR(xiosc0) tF(xiosc0) tj(xiosc0) MIN Frequency accuracy(2), xi_osc0 0.45 * tc(xiosc0) Ethernet and MLB not used ±200 Ethernet RGMII and RMII using derived clock ±50 Ethernet MII using derived clock ±100 MLB using derived clock ±50 ppm (1) Period jitter is meant here as follows: – The maximum value is the difference between the longest measured clock period and the expected clock period – The minimum value is the difference between the shortest measured clock period and the expected clock period (2) Crystal characteristics should account for tolerance+stability+aging. CK0 CK1 CK1 xi_osc0 Figure 6-5. xi_osc0 Input Clock 6.1.3 Auxiliary Oscillator OSC1 Input Clock SYS_CLKIN2 is received directly from oscillator OSC1. For more information about SYS_CLKIN2 see Device TRM, Chapter: Power, Reset, and Clock Management. 6.1.3.1 OSC1 External Crystal An external crystal is connected to the device pins. Figure 6-6 describes the crystal implementation. Device xo_osc1 xi_osc1 Rd (Optional) Crystal Cf1 vssa_osc1 Cf2 Figure 6-6. Crystal Implementation 194 Clock Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE The load capacitors, Cf1 and Cf2 in Figure 6-6, should be chosen such that the below equation is satisfied. CL in the equation is the load specified by the crystal manufacturer. All discrete components used to implement the oscillator circuit should be placed as close as possible to the associated oscillator xi_osc1, xo_osc1, and vssa_osc1 pins. CL= Cf1Cf2 (Cf1+Cf2) Figure 6-7. Load Capacitance Equation The crystal must be in the fundamental mode of operation and parallel resonant. Table 6-5 summarizes the required electrical constraints. Table 6-5. OSC1 Crystal Electrical Characteristics NAME fp DESCRIPTION MIN Parallel resonance crystal frequency TYP MAX Range from 19.2 to 32 UNIT MHz Cf1 Cf1 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 pF Cf2 Cf2 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 pF 100 Ω ESR(Cf1,Cf2) Crystal ESR ESR = 30 Ω 19.2 MHz≤fp≤32 MHz 7 pF ESR = 40 Ω 19.2 MHz≤fp≤32 MHz 5 pF 19.2 MHz≤fp≤25 MHz 7 pF 5 pF 7 pF 5 pF 19.2 MHz≤fp≤23 MHz 5 pF 23 MHz≤fp≤25 MHz 3 pF 3 pF ESR = 50 Ω 25 MHz<fp≤27 MHz 27 MHz<fp≤32 MHz Not Supported 19.2 MHz≤fp≤23 MHz CO Crystal shunt capacitance ESR = 60 Ω 23 MHz<fp≤25 MHz 25 MHz<fp≤32 MHz ESR = 80 Ω 25 MHz<fp≤32 MHz ESR = 100 Ω Not Supported - Not Supported 19.2 MHz≤fp≤20 MHz 20 MHz<fp≤32 MHz - - Not Supported - LM Crystal motional inductance for fp = 20 MHz 10.16 mH CM Crystal motional capacitance 3.42 fF tj(xiosc1) Frequency accuracy(1), xi_osc1 Ethernet and MLB not used ±200 Ethernet RGMII and RMII using derived clock ±50 Ethernet MII using derived clock ±100 MLB using derived clock ±50 ppm (1) Crystal characteristics should account for tolerance+stability+aging. When selecting a crystal, the system design must take into account the temperature and aging characteristics of a crystal versus the user environment and expected lifetime of the system. Table 6-6 details the switching characteristics of the oscillator and the requirements of the input clock. Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 195 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 6-6. Oscillator Switching Characteristics—Crystal Mode NAME DESCRIPTION fp Oscillation frequency tsX Start-up time 6.1.3.2 MIN TYP MAX UNIT Range from 19.2 to 32 MHz 4 ms OSC1 Input Clock A 1.8-V LVCMOS-Compatible Clock Input can be used instead of the internal oscillator to provide the SYS_CLKIN2 clock input to the system. The external connections to support this are shown in, Figure 6-8. The xi_osc1 pin is connected to the 1.8-V LVCMOS-Compatible clock sources. The xo_osc1 pin is left unconnected. The vssa_osc1 pin is connected to board ground (vss). Device xi_osc1 xo_osc1 vssa_osc1 NC SPRS85v_CLK_10 Figure 6-8. 1.8-V LVCMOS-Compatible Clock Input Table 6-7 summarizes the OSC1 input clock electrical characteristics. Table 6-7. OSC1 Input Clock Electrical Characteristics—Bypass Mode NAME f DESCRIPTION MIN Frequency MAX UNIT Range from 12 to 38.4 CI Input capacitance II Input current (3.3V mode) tsX TYP Start-up time(1) MHz 2.819 3.019 3.219 pF 4 6 10 µA See(2) ms (1) To switch from bypass mode to crystal or from crystal mode to bypass mode, there is a waiting time about 100 μs; however, if the chip comes from bypass mode to crystal mode the crystal will start-up after time mentioned in Table 6-6, tsX parameter. (2) Before the processor boots up and the oscillator is set to bypass mode, there is a waiting time when the internal oscillator is in application mode and receives a wave. The switching time in this case is about 100 μs. Table 6-8 details the OSC1 input clock timing requirements. Table 6-8. OSC1 Input Clock Timing Requirements NAME DESCRIPTION CK0 1/ tc(xiosc1) Frequency, xi_osc1 CK1 tw(xiosc1) Pulse duration, xi_osc1 low or high tj(xiosc1) Period jitter(1), xi_osc1 tR(xiosc1) tF(xiosc1) 196 MIN TYP MAX Range from 12 to 38.4 MHz 0.55 * tc(xiosc1) ns 0.01 × tc(xiosc1) ns Rise time, xi_osc1 5 ns Fall time, xi_osc1 5 ns Clock Specifications 0.45 * tc(xiosc1) UNIT (3) Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 6-8. OSC1 Input Clock Timing Requirements (continued) NAME DESCRIPTION tj(xiosc1) MIN (2) Frequency accuracy , xi_osc1 TYP MAX Ethernet and MLB not used ±200 Ethernet RGMII and RMII using derived clock ±50 Ethernet MII using derived clock ±100 MLB using derived clock ±50 UNIT ppm (1) Period jitter is meant here as follows: – The maximum value is the difference between the longest measured clock period and the expected clock period – The minimum value is the difference between the shortest measured clock period and the expected clock period (2) Crystal characteristics should account for tolerance+stability+aging. (3) The Period jitter requirement for osc1 can be relaxed to 0.02*tc(xiosc1) under the following constraints: a.The osc1/SYS_CLK2 clock bypasses all device PLLs b.The osc1/SYS_CLK2 clock is only used to source the DSS pixel clock outputs CK0 CK1 CK1 xi_osc1 Figure 6-9. xi_osc1 Input Clock 6.1.4 RTC Oscillator Input Clock SYS_32K is received directly from RTC Oscillator. For more information about SYS_32K see Device TRM, Chapter: Power, Reset, and Clock Management. 6.1.4.1 RTC Oscillator External Crystal An external crystal is connected to the device pins. Figure 6-2 describes the crystal implementation. Device rtc_osc_xo rtc_osc_xi_clkin32 Rd (Optional) Crystal Cf2 Cf1 Figure 6-10. Crystal Implementation NOTE The load capacitors, Cf1 and Cf2 in Figure 6-10, should be chosen such that the below equation is satisfied. CL in the equation is the load specified by the crystal manufacturer. All discrete components used to implement the oscillator circuit should be placed as close as possible to the associated oscillator rtc_osc_xi_clkin32 and rtc_osc_xo pins. Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 197 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com CL= Cf1Cf2 (Cf1+Cf2) Figure 6-11. Load Capacitance Equation The crystal must be in the fundamental mode of operation and parallel resonant. Table 6-9 summarizes the required electrical constraints. Table 6-9. RTC Crystal Electrical Characteristics NAME DESCRIPTION fp MIN TYP Parallel resonance crystal frequency MAX 32.768 UNIT kHz Cf1 Cf1 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 Cf2 Cf2 load capacitance for crystal parallel resonance with Cf1 = Cf2 12 24 pF 80 kΩ ESR(Cf1,Cf2) Crystal ESR CO Crystal shunt capacitance LM Crystal motional inductance for fp = 32,768 kHz 10.7 CM Crystal motional capacitance 2.2 tj(rtc_osc_xi_clkin32) 5 pF pF mH fF Frequency accuracy, rtc_osc_xi_clkin32 ±200 ppm When selecting a crystal, the system design must take into account the temperature and aging characteristics of a crystal versus the user environment and expected lifetime of the system. Table 6-10 details the switching characteristics of the oscillator and the requirements of the input clock. Table 6-10. Oscillator Switching Characteristics—Crystal Mode NAME DESCRIPTION fp Oscillation frequency tsX Start-up time 6.1.4.2 MIN TYP MAX 32.768 UNIT kHz 4 ms RTC Oscillator Input Clock A 1.8-V LVCMOS-Compatible Clock Input can be used instead of the internal oscillator to provide the SYS_32K clock input to the system. The external connections to support this are shown in Figure 6-12. The rtc_osc_xi_clkin32 pin is connected to the 1.8-V LVCMOS-Compatible clock sources. The rtc_osc_xo pin is left unconnected. Device rtc_osc_xi_clkin32 rtc_osc_xo NC SPRS85v_CLK_11 Figure 6-12. LVCMOS-Compatible Clock Input Table 6-11 summarizes the RTC Oscillator input clock electrical characteristics. 198 Clock Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 6-11. RTC Oscillator Input Clock Electrical Characteristics—Bypass Mode NAME CK0 CK1 DESCRIPTION 1/tc(rtc_osc_xi_clkin32) tw(rtc_osc_xi_clkin32) MIN Frequency, rtc_osc_xi_clkin32 Pulse duration, rtc_osc_xi_clkin32 low or high CIN Input capacitance IIN Input current (3.3V mode) tsX Start-up time TYP MAX UNIT 32.768 kHz 0.45 * 0.55 * tc(rtc_osc_xi_clkin32) tc(rtc_osc_xi_clkin32) ns 2.178 2.378 2.578 pF 4 6 10 µA See (1) ms (1) Before the processor boots up and the oscillator is set to bypass mode, there is a waiting time when the internal oscillator is inapplication mode and receives a wave. The switching time in this case is about 100 μs. CK0 CK1 CK1 rtc_osc_xi_clkin32 Figure 6-13. rtc_osc_xi_clkin32 Input Clock 6.2 DPLLs, DLLs Specifications NOTE For more information, see: • Power, Reset and Clock Management / Clock Management Functional / Internal Clock Sources / Generators / Generic DPLL Overview Section and • Display Subsystem / Display Subsystem Overview section of the Device TRM. To generate high-frequency clocks, the device supports multiple on-chip DPLLs controlled directly by the PRCM module. They are of two types: type A and type B DPLLs. • They have their own independent power domain (each one embeds its own switch and can be controlled as an independent functional power domain) • They are fed with ALWAYS ON system clock, with independent control per DPLL. The different DPLLs managed by the PRCM are listed below: • DPLL_MPU: It supplies the MPU subsystem clocking internally. • DPLL_IVA: It feeds the IVA subsystem clocking. • DPLL_CORE: It supplies all interface clocks and also few module functional clocks. • DPLL_PER: It supplies several clock sources: a 192-MHz clock for the display functional clock, a 96-MHz functional clock to subsystems and peripherals. • DPLL_ABE: It provides clocks to various modules within the device. • DPLL_USB: It provides 960M clock for USB modules (USB1/2/3/4). • DPLL_GMAC: It supplies several clocks for the Gigabit Ethernet Switch (GMAC_SW). • DPLL_EVE: It provides the Embedded Vision Engine Subsystem (EVE1/2/3/4) clocking. • DPLL_DSP: It feeds the DSP Subsystem clocking. • DPLL_GPU: It supplies clock for the GPU Subsystem. • DPLL_DDR: It generates clocks for the two External Memory Interface (EMIF) controllers and their associated EMIF PHYs. • DPLL_PCIE_REF: It provides reference clock for the APLL_PCIE in PCIE Subsystem. • APLL_PCIE: It feeds clocks for the device Peripheral Component Interconnect Express (PCIe) controllers. Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 199 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com NOTE The following DPLLs are controlled by the clock manager located in the always-on Core power domain (CM_CORE_AON): • DPLL_MPU, DPLL_IVA, DPLL_CORE, DPLL_ABE, DPLL_DDR, DPLL_GMAC, DPLL_PCIE_REF, DPLL_PER, DPLL_USB, DPLL_EVE, DPLL_DSP, DPLL_GPU, APLL_PCIE_REF. For more information on CM_CORE_AON and CM_CORE or PRCM DPLLs, see the Power, Reset, and Clock Management (PRCM) chapter of the Device TRM. The following DPLLs are not managed by the PRCM: • • • • • • DPLL_VIDEO1; (It is controlled from DSS) DPLL_VIDEO2; (It is controlled from DSS) DPLL_HDMI; (It is controlled from DSS) DPLL_SATA; (It is controlled from SATA) DPLL_DEBUG; (It is controlled from DEBUGSS) DPLL_USB_OTG_SS; (It is controlled from OCP2SCP1) NOTE For more information for not controlled from PRCM DPLL’s see the related chapters in TRM. 6.2.1 DPLL Characteristics The DPLL has three relevant input clocks. One of them is the reference clock (CLKINP) used to generated the synthesized clock but can also be used as the bypass clock whenever the DPLL enters a bypass mode. It is therefore mandatory. The second one is a fast bypass clock (CLKINPULOW) used when selected as the bypass clock and is optional. The third clock (CLKINPHIF) is explained in the next paragraph. The DPLL has three output clocks (namely CLKOUT, CLKOUTX2, and CLKOUTHIF). CLKOUT and CLKOUTX2 run at the bypass frequency whenever the DPLL enters a bypass mode. Both of them are generated from the lock frequency divided by a post-divider (namely M2 post-divider). The third clock, CLKOUTHIF, has no automatic bypass capability. It is an output of a post-divider (M3 post-divider) with the input clock selectable between the internal lock clock (Fdpll) and CLKINPHIF input of the PLL through an asynchronous multplexing. For more information, see the Power Reset Controller Management chapter of the Device TRM. Table 6-12 summarizes DPLL type described in Section 6.2, DPLLs, DLLs Specifications introduction. Table 6-12. DPLL Control Type 200 DPLL NAME TYPE CONTROLLED BY PRCM DPLL_ABE Table 6-13 (Type A) Yes(1) DPLL_CORE Table 6-13 (Type A) Yes(1) DPLL_DEBUGSS Table 6-13 (Type A) No(2) DPLL_DSP Table 6-13 (Type A) Yes(1) DPLL_EVE Table 6-13 (Type A) Yes(1) DPLL_GMAC Table 6-13 (Type A) Yes(1) DPLL_HDMI Table 6-14 (Type B) No(2) DPLL_IVA Table 6-13 (Type A) Yes(1) DPLL_MPU Table 6-13 (Type A) Yes(1) DPLL_PER Table 6-13 (Type A) Yes(1) Clock Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 6-12. DPLL Control Type (continued) DPLL NAME TYPE CONTROLLED BY PRCM APLL_PCIE Table 6-13 (Type A) Yes(1) DPLL_PCIE_REF Table 6-14 (Type B) Yes(1) DPLL_SATA Table 6-14 (Type B) No(2) DPLL_USB Table 6-14 (Type B) Yes(1) DPLL_USB_OTG_SS Table 6-14 (Type B) No(2) DPLL_VIDEO1 Table 6-13 (Type A) No(2) DPLL_VIDEO2 Table 6-13 (Type A) No(2) DPLL_DDR Table 6-13 (Type A) Yes(1) DPLL_GPU Table 6-13 (Type A) Yes(1) (1) DPLL is in the always-on domain. (2) DPLL is not controlled by the PRCM. Table 6-13 and Table 6-14 summarize the DPLL characteristics and assume testing over recommended operating conditions. Table 6-13. DPLL Type A Characteristics NAME DESCRIPTION finput MIN MAX UNIT 52 MHz FINP 0.15 52 MHz REFCLK 10 1400 MHz FINPHIF 0.001 600 MHz Bypass mode: fCLKOUT = fCLKINPULOW / (M1 + 1) if ulowclken = 1(6) CLKOUT output frequency 20(1) 1400(2) MHz [M / (N + 1)] × FINP × [1 / M2] (in locked condition) CLKOUTx2 output frequency 40(1) 2200(2) MHz 2 × [M / (N + 1)] × FINP × [1 / M2] (in locked condition) 20(3) 1400(4) MHz FINPHIF / M3 if clkinphifsel = 1 40(3) 2200(4) MHz 2 × [M / (N + 1)] × FINP × [1 / M3] if clkinphifsel = 0 40 2800 MHz 2 × [M / (N + 1)] × FINP (in locked condition) CLKINP input frequency 0.032 finternal Internal reference frequency fCLKINPHIF CLKINPHIF input frequency fCLKINPULOW fCLKOUT fCLKOUTx2 CLKINPULOW input frequency TYP COMMENTS fCLKOUTHIF CLKOUTHIF output frequency fCLKDCOLDO DCOCLKLDO output frequency tlock Frequency lock time 6 + 350 × REFCLK µs plock Phase lock time 6 + 500 × REFCLK µs trelock-L Relock time—Frequency lock(5) (LP relock time from bypass) 6 + 70 × REFCLK µs DPLL in LP relock time: lowcurrstdby = 1 prelock-L Relock time—Phase lock(5) (LP relock time from bypass) 6 + 120 × REFCLK µs DPLL in LP relock time: lowcurrstdby = 1 trelock-F Relock time—Frequency lock(5) (fast relock time from bypass) 3.55 + 70 × REFCLK µs DPLL in fast relock time: lowcurrstdby = 0 prelock-F Relock time—Phase lock(5) (fast relock time from bypass) 3.55 + 120 × REFCLK µs DPLL in fast relock time: lowcurrstdby = 0 (1) The minimum frequencies on CLKOUT and CLKOUTX2 are assuming M2 = 1. For M2 > 1, the minimum frequency on these clocks will further scale down by factor of M2. (2) The maximum frequencies on CLKOUT and CLKOUTX2 are assuming M2 = 1. (3) The minimum frequency on CLKOUTHIF is assuming M3 = 1. For M3 > 1, the minimum frequency on this clock will further scale down by factor of M3. (4) The maximum frequency on CLKOUTHIF is assuming M3 = 1. (5) Relock time assumes typical operating conditions, 10°C maximum temperature drift. Clock Specifications Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 201 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (6) Bypass mode: fCLKOUT = FINP if ulowclken = 0. For more information, see the Device TRM. Table 6-14. DPLL Type B Characteristics NAME MAX UNIT CLKINP input clock frequency DESCRIPTION 0.62 60 MHz FINP finternal REFCLK internal reference clock frequency 0.62 2.5 MHz [1 / (N + 1)] × FINP fCLKINPULOW CLKINPULOW bypass input clock frequency 0.001 600 MHz Bypass mode: fCLKOUT = fCLKINPULOW / (M1 + 1) If ulowclken = 1(4) fCLKLDOOUT CLKOUTLDO output clock frequency 20(1)(5) 2500(2)(5) MHz M / (N + 1)] × FINP × [1 / M2] (in locked condition) CLKOUT output clock frequency 20(1)(5) 1450(2)(5) MHz [M / (N + 1)] × FINP × [1 / M2] (in locked condition) 750(5) 1500(5) MHz 1250(5) 2500(5) MHz –2.5% 2.5% finput fCLKOUT fCLKDCOLDO MIN Internal oscillator (DCO) output clock frequency TYP COMMENTS [M / (N + 1)] × FINP (in locked condition) CLKOUTLDO period jitter tJ CLKOUT period jitter The period jitter at the output clocks is ± 2.5% peak to peak CLKDCOLDO period jitter tlock Frequency lock time 350 × REFCLKs µs plock Phase lock time 500 × REFCLKs µs Relock time—Frequency lock(3) (LP relock time from bypass) 9 + 30 × REFCLKs µs 9 + 125 × REFCLKs µs trelock-L (3) prelock-L Relock time—Phase lock relock time from bypass) (LP (1) The minimum frequency on CLKOUT is assuming M2 = 1. For M2 > 1, the minimum frequency on this clock will further scale down by factor of M2. (2) The maximum frequency on CLKOUT is assuming M2 = 1. (3) Relock time assumes typical operating conditions, 10°C maximum temperature drift. (4) Bypass mode: fCLKOUT = FINP if ULOWCLKEN = 0. For more information, see the Device TRM. (5) For output clocks, there are two frequency ranges according to the SELFREQDCO setting. For more information, see the Device TRM. 6.2.2 DLL Characteristics Table 6-15 summarizes the DLL characteristics and assumes testing over recommended operating conditions. Table 6-15. DLL Characteristics NAME DESCRIPTION MIN TYP MAX UNIT finput Input clock frequency (EMIF_DLL_FCLK) 266 MHz tlock Lock time 50k cycles Relock time (a change of the DLL frequency implies that DLL must relock) 50k cycles trelock 6.2.3 DPLL and DLL Noise Isolation NOTE For more information on DPLL and DLL decoupling capacitor requirements, see the External Capacitors / Voltage Decoupling Capacitors / I/O and Analog Voltage Decoupling / VDDA Power Domain section. 202 Clock Specifications Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 7 Timing Requirements and Switching Characteristics 7.1 Timing Test Conditions All timing requirements and switching characteristics are valid over the recommended operating conditions unless otherwise specified. 7.2 7.2.1 Interface Clock Specifications Interface Clock Terminology The interface clock is used at the system level to sequence the data and/or to control transfers accordingly with the interface protocol. 7.2.2 Interface Clock Frequency The two interface clock characteristics are: • The maximum clock frequency • The maximum operating frequency The interface clock frequency documented in this document is the maximum clock frequency, which corresponds to the maximum frequency programmable on this output clock. This frequency defines the maximum limit supported by the Device IC and does not take into account any system consideration (PCB, peripherals). The system designer will have to consider these system considerations and the Device IC timing characteristics as well to define properly the maximum operating frequency that corresponds to the maximum frequency supported to transfer the data on this interface. 7.3 Timing Parameters and Information The timing parameter symbols used in the timing requirement and switching characteristic tables are created in accordance with JEDEC Standard 100. To shorten the symbols, some of pin names and other related terminologies have been abbreviated as follows: Table 7-1. Timing Parameters SUBSCRIPTS SYMBOL PARAMETER c Cycle time (period) d Delay time dis Disable time en Enable time h Hold time su Setup time START Start bit t Transition time v Valid time w Pulse duration (width) X Unknown, changing, or don't care level F Fall time H High L Low R Rise time V Valid IV Invalid Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 203 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-1. Timing Parameters (continued) SUBSCRIPTS 7.3.1 SYMBOL PARAMETER AE Active Edge FE First Edge LE Last Edge Z High impedance Parameter Information Tester Pin Electronics 42 Ω 3.5 nH Transmission Line Z0 = 50 Ω (see Note) 4.0 pF 1.85 pF Data Sheet Timing Reference Point Output Under Test Device Pin (see Note) NOTE: The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and its transmission line effects must be taken into account. A transmission line with a delay of 2 ns can be used to produce the desired transmission line effect. The transmission line is intended as a load only. It is not necessary to add or subtract the transmission line delay (2 ns) from the data sheet timings. Input requirements in this data sheet are tested with an input slew rate of < 4 Volts per nanosecond (4 V/ns) at the device pin. pm_tstcirc_prs403 Figure 7-1. Test Load Circuit for AC Timing Measurements The load capacitance value stated is only for characterization and measurement of AC timing signals. This load capacitance value does not indicate the maximum load the device is capable of driving. 7.3.1.1 1.8V and 3.3V Signal Transition Levels All input and output timing parameters are referenced to Vref for both "0" and "1" logic levels. Vref = (VDD I/O)/2. Vref pm_io_volt_prs403 Figure 7-2. Input and Output Voltage Reference Levels for AC Timing Measurements All rise and fall transition timing parameters are referenced to VIL MAX and VIH MIN for input clocks, VOL MAX and VOH MIN for output clocks. 204 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Vref = VIH MIN (or VOH MIN) Vref = VIL MAX (or VOL MAX) pm_transvolt_prs403 Figure 7-3. Rise and Fall Transition Time Voltage Reference Levels 7.3.1.2 1.8V and 3.3V Signal Transition Rates The default SLEWCONTROL settings in each pad configuration register must be used to guarantee timings, unless specific instructions otherwise are given in the individual timing sub-sections of the datasheet. All timings are tested with an input edge rate of 4 volts per nanosecond (4 V/ns). 7.3.1.3 Timing Parameters and Board Routing Analysis The timing parameter values specified in this data manual do not include delays by board routes. As a good board design practice, such delays must always be taken into account. Timing values may be adjusted by increasing/decreasing such delays. TI recommends using the available I/O buffer information specification (IBIS) models to analyze the timing characteristics correctly. To properly use IBIS models to attain accurate timing analysis for a given system, see the Using IBIS Models for timing Analysis application report (literature number SPRA839). If needed, external logic hardware such as buffers may be used to compensate any timing differences. 7.4 Recommended Clock and Control Signal Transition Behavior All clocks and control signals must transition between VIH and VIL (or between VIL and VIH) in a monotonic manner. Monotonic transitions are more easily guaranteed with faster switching signals. Slower input transitions are more susceptible to glitches due to noise and special care should be taken for slow input clocks. 7.5 Virtual and Manual I/O Timing Modes Some of the timings described in the following sections require the use of Virtual or Manual I/O Timing Modes. Table 7-2 provides a summary of the Virtual and Manual I/O Timing Modes across all device interfaces. The individual interface timing sections found later in this document provide the full description of each applicable Virtual and Manual I/O Timing Mode. Refer to the "Pad Configuration" section of the TRM for the procedure on implementing the Virtual and Manual Timing Modes in a system. Table 7-2. Modes Summary Virtual or Manual IO Mode Name Data Manual Timing Mode VIP VIP1_MANUAL1 VIN1A/1B/2A Rise-Edge Capture Mode Timings VIP1_2B_MANUAL1 VIN2B Rise-Edge Capture Mode Timings VIP1_MANUAL2 VIN1A/1B/2A Fall-Edge Capture Mode Timings VIP1_2B_MANUAL2 VIN2B Fall-Edge Capture Mode Timings VIP2_MANUAL1 VIN3A and VIN3B IOSET1 Rise-Edge Capture Mode Timings VIP2_4A_MANUAL1 VIN4A IOSET1/2 Rise-Edge Capture Mode Timings VIP2_4A_IOSET3_MANUAL1 VIN4A IOSET3 Rise-Edge Capture Mode Timings VIP2_4B_MANUAL1 VIN4B Rise-Edge Capture Mode Timings VIP2_3B_IOSET2_MANUAL1 VIN3B IOSET2 Rise-Edge Capture Mode Timings VIP2_3B_IOSET2_MANUAL2 VIN3B IOSET2 Fall-Edge Capture Mode Timings VIP2_MANUAL2 VIN3A, VIN3B IOSET1, VIN4A IOSET1/2 Fall-Edge Capture Mode Timings VIP2_4A_MANUAL2 VIN4A IOSET1/2 Fall-Edge Capture Mode Timings Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 205 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-2. Modes Summary (continued) Virtual or Manual IO Mode Name Data Manual Timing Mode VIP2_4A_IOSET3_MANUAL2 VIN4A IOSET3 Fall-Edge Capture Mode Timings VIP2_4B_MANUAL2 VIN4B Fall-Edge Capture Mode Timings VIP3_MANUAL1 VIN5A and VIN6A Rise-Edge Capture Mode Timings VIP3_MANUAL2 VIN5A and VIN6A Fall-Edge Capture Mode Timings DPI Video Output VOUT1_MANUAL1 DPI1 Video Output Alternate Timings VOUT1_MANUAL2 DPI1 Video Output Default Timings - Rising-edge Clock Reference VOUT1_MANUAL3 DPI1 Video Output Default Timings - Falling-edge Clock Reference VOUT2_IOSET1_MANUAL1 DPI2 Video Output IOSET1 Alternate Timings VOUT2_IOSET1_MANUAL2 DPI2 Video Output IOSET1 Default Timings - Rising-edge Clock Reference VOUT2_IOSET1_MANUAL3 DPI2 Video Output IOSET1 Default Timings - Falling-edge Clock Reference VOUT2_IOSET2_MANUAL1 DPI2 Video Output IOSET2 Alternate Timings VOUT2_IOSET2_MANUAL2 DPI2 Video Output IOSET2 Default Timings - Rising-edge Clock Reference VOUT2_IOSET2_MANUAL3 DPI2 Video Output IOSET2 Default Timings - Falling-edge Clock Reference VOUT3_MANUAL1 DPI3 Video Output Alternate Timings VOUT3_MANUAL2 DPI3 Video Output Default Timings - Rising-edge Clock Reference VOUT3_MANUAL3 DPI3 Video Output Default Timings - Falling-edge Clock Reference HDMI, EMIF, Timers, I2C, HDQ/1-Wire, UART, McSPI, USB, SATA, PCIe, DCAN, GPIO, KBD, PWM, ATL, JTAG, TPIU, RTC, SDMA, INTC No Virtual or Manual IO Timing Mode Required All Modes GPMC No Virtual or Manual IO Timing Mode Required GPMC Asyncronous Mode (1/5 Load) Timings and Synchronous Mode - (1 Load) Timings GPMC_VIRTUAL1 GPMC Synchronous Mode - (5 Load) Timings QSPI No Virtual or Manual IO Timing Mode Required QSPI Mode 3 Default Timing Mode QSPI_MODE0_MANUAL1 QSPI Mode 0 Default Timing Mode McASP No Virtual or Manual IO Timing Mode Required McASP1 Synchronous Transmit Timings MCASP1_VIRTUAL1_ASYNC_TX See Table 7-53 MCASP1_VIRTUAL2_SYNC_RX See Table 7-53 MCASP1_VIRTUAL3_ASYNC_RX See Table 7-53 No Virtual or Manual IO Timing Mode Required McASP2 Synchronous Transmit Timings MCASP2_VIRTUAL1_ASYNC_RX_ 80M See Table 7-54 MCASP2_VIRTUAL2_ASYNC_RX See Table 7-54 MCASP2_VIRTUAL3_ASYNC_TX See Table 7-54 MCASP2_VIRTUAL4_SYNC_RX See Table 7-54 MCASP2_VIRTUAL5_SYNC_RX_8 0M See Table 7-54 No Virtual or Manual IO Timing Mode Required McASP3 Synchronous Transmit Timings MCASP3_VIRTUAL2_SYNC_RX See Table 7-55 No Virtual or Manual IO Timing Mode Required McASP4 Synchronous Transmit Timings MCASP4_VIRTUAL1_SYNC_RX See Table 7-56 206 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-2. Modes Summary (continued) Virtual or Manual IO Mode Name Data Manual Timing Mode No Virtual or Manual IO Timing Mode Required McASP5 Synchronous Transmit Timings MCASP5_VIRTUAL1_SYNC_RX See Table 7-57 No Virtual or Manual IO Timing Mode Required McASP6 Synchronous Transmit Timings MCASP6_VIRTUAL1_SYNC_RX See Table 7-58 No Virtual or Manual IO Timing Mode Required McASP7 Synchronous Transmit Timings MCASP7_VIRTUAL2_SYNC_RX See Table 7-59 No Virtual or Manual IO Timing Mode Required McASP8 Synchronous Transmit Timings MCASP8_VIRTUAL1_SYNC_RX See Table 7-60 GMAC No Virtual or Manual IO Timing Mode Required GMAC MII1/2 Timings GMAC_RMII0_MANUAL1 GMAC RMII0 Timings GMAC_RMII1_MANUAL1 GMAC RMII1 Timings GMAC_RGMII0_MANUAL1 GMAC RGMII0 Internal Delay Enabled Timings Mode GMAC_RGMII1_MANUAL1 GMAC RGMII1 Internal Delay Enabled Timings Mode MLB MLB_MANUAL1 MLB 3-Pin and 6-Pin Timings eMMC/SD/SDIO No Virtual or Manual IO Timing Mode Required MMC1 DS (Pad Loopback) and SDR12 (Pad Loopback) Timings MMC1_VIRTUAL1 MMC1 HS (Internal Loopback and Pad Loopback), SDR12 (Internal Loopback), SDR25 Timings (Internal Loopback and Pad Loopback) MMC1_VIRTUAL2 SDR50 (Pad Loopback) Timings MMC1_VIRTUAL5 MMC1 DS (Internal Loopback) Timings MMC1_VIRTUAL6 MMC1 SDR50 (Internal Loopback) Timings MMC1_VIRTUAL7 MMC1 DDR50 (Internal Loopback) Timings MMC1_DDR_MANUAL1 MMC1 DDR50 (Pad Loopback) Timings MMC1_SDR104_MANUAL1 MMC1 SDR104 Timings No Virtual or Manual IO Timing Mode Required MMC2 Standard (Pad Loopback) and High Speed (Pad Loopback) Timings MMC2_DDR_LB_MANUAL1 MMC2 DDR (Internal Loopback) Timings MMC2_DDR_MANUAL1 MMC2 DDR (Pad Loopback) 1.8V and 3.3V Mode Timings MMC2_HS200_MANUAL1 MMC2 HS200 Timings MMC2_STD_HS_LB_MANUAL1 MMC2 Standard (Internal Loopback), High Speed (Internal Loopback) Timings MMC3_MANUAL1 MMC3 DS, SDR12, HS, SDR25 Timings, SDR50 Timings MMC4_MANUAL1 MMC4 SDR12, HS, SDR25 Timings MMC4_DS_MANUAL1 MMC4 DS Timings Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 207 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 7.6 www.ti.com Video Input Ports (VIP) The Device includes 3 Video Input Ports (VIP). Table 7-3, Figure 7-4 and Figure 7-5 present timings and switching characteristics of the VIPs. CAUTION The IO timings provided in this section are applicable for all combinations of signals for vin1, vin5 and vin6. However, the timings are only valid for vin2, vin3, and vin4 if signals within a single IOSET are used. The IOSETs are defined in the Table 7-4, Table 7-5 and Table 7-6. Table 7-3. Timing Requirements for VIP (1)(2) NO. PARAMETER DESCRIPTION V1 tc(CLK) Cycle time, vinx_clki (3) (5) MODE V2 tw(CLKH) Pulse duration, vinx_clki high (3) (5) 0.45*P (2) ns V3 tw(CLKL) Pulse duration, vinx_clki low (3) (5) 0.45*P (2) ns V4 tsu(CTL/DATA-CLK) Input setup time, Control (vinx_dei, vinx_vsynci, vinx_fldi, vinx_hsynci) and Data (vinx_dn) valid to vinx_clki transition (3) (4) (5) V5 th(CLK-CTL/DATA) MIN 6.06 Input hold time, Control (vinx_dei, vinx_vsynci, vinx_fldi, vinx_hsynci) and Data (vinx_dn) valid from vinx_clki transition MAX (1) UNIT ns vin1x, vin2x 2.93 ns vin5x, vin6x 3.11 ns vin3x, vin4x 3.11 ns -0.05 ns (3) (4) (5) (1) For maximum frequency of 165 MHZ. (2) P = vinx_clki period. (3) x in vinx = 1a, 1b, 2a, 2b, 3a, 3b, 4a, 4b, 5a and 6a. (4) n in dn = 0 to 7 when x = 1b, 2b, 3b and 4b; n = 0 to 15 when x = 5a and 6a; n = 0 to 23 when x = 1a, 2a, 3a and 4a; (5) i in clki, dei, vsynci, hsynci and fldi = 0 or 1. V3 V2 V1 vinx_clki SPRS8xx_VIP_01 Figure 7-4. Video Input Ports clock signal 208 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 vinx_clki (positive-edge clocking) vinx_clki (negative-edge clocking) V5 V4 vinx_d[23:0]/sig SPRS8xx_VIP_02 Figure 7-5. Video Input Ports timings In Table 7-4, Table 7-5 and Table 7-6 are presented the specific groupings of signals (IOSET) for use with vin2, vin3, and vin4. Table 7-4. VIN2 IOSETs Signals IOSET1 BALL IOSET2 MUX IOSET3 BALL MUX BALL MUX F2 0 U4 4 vin2a vin2a_d0 F2 0 vin2a_d1 F3 0 F3 0 V2 4 vin2a_d2 D1 0 D1 0 Y1 4 vin2a_d3 E2 0 E2 0 W9 4 vin2a_d4 D2 0 D2 0 V9 4 vin2a_d5 F4 0 F4 0 U5 4 vin2a_d6 C1 0 C1 0 V5 4 vin2a_d7 E4 0 E4 0 V4 4 vin2a_d8 F5 0 F5 0 V3 4 vin2a_d9 E6 0 E6 0 Y2 4 vin2a_d10 D3 0 D3 0 U6 4 vin2a_d11 F6 0 F6 0 U3 4 vin2a_d12 D5 0 D5 0 - - vin2a_d13 C2 0 C2 0 - - vin2a_d14 C3 0 C3 0 - - vin2a_d15 C4 0 C4 0 - - vin2a_d16 B2 0 B2 0 - - vin2a_d17 D6 0 D6 0 - - vin2a_d18 C5 0 C5 0 - - vin2a_d19 A3 0 A3 0 - - vin2a_d20 B3 0 B3 0 - - vin2a_d21 B4 0 B4 0 - - vin2a_d22 B5 0 B5 0 - - vin2a_d23 A4 0 A4 0 - - vin2a_hsync0 G1 0 G1 0 U7 4 vin2a_vsync0 G6 0 G6 0 V6 4 vin2a_de0 G2 0 - - V7 4 vin2a_fld0 H7 0 G2 1 W2 4 vin2a_clk0 E1 0 E1 0 V1 4 vin2b Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 209 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-4. VIN2 IOSETs (continued) Signals IOSET1 IOSET2 BALL MUX vin2b_clk1 H7 vin2b_de1 - vin2b_fld1 IOSET3 BALL MUX BALL MUX 2 H7 2 AB5 4 - G2 3 AB8 4 G2 2 - - - - vin2b_d0 A4 2 A4 2 AD6 4 vin2b_d1 B5 2 B5 2 AC8 4 vin2b_d2 B4 2 B4 2 AC3 4 vin2b_d3 B3 2 B3 2 AC9 4 vin2b_d4 A3 2 A3 2 AC6 4 vin2b_d5 C5 2 C5 2 AC7 4 vin2b_d6 D6 2 D6 2 AC4 4 vin2b_d7 B2 2 B2 2 AD4 4 vin2b_hsync1 G1 3 G1 3 AC5 4 vin2b_vsync1 G6 3 G6 3 AB4 4 Table 7-5. VIN3 IOSETs Signals IOSET1 BALL IOSET2 MUX BALL IOSET3 MUX IOSET4 BALL MUX BALL MUX vin3a 210 vin3a_d0 M6 2 AF1 6 AF1 6 B7 4 vin3a_d1 M2 2 AE3 6 AE3 6 B8 4 vin3a_d2 L5 2 AE5 6 AE5 6 A7 4 vin3a_d3 M1 2 AE1 6 AE1 6 A8 4 vin3a_d4 L6 2 AE2 6 AE2 6 C9 4 vin3a_d5 L4 2 AE6 6 AE6 6 A9 4 vin3a_d6 L3 2 AD2 6 AD2 6 B9 4 vin3a_d7 L2 2 AD3 6 AD3 6 A10 4 vin3a_d8 L1 2 B2 6 B2 6 E8 4 vin3a_d9 K2 2 D6 6 D6 6 D9 4 vin3a_d10 J1 2 C5 6 C5 6 D7 4 vin3a_d11 J2 2 A3 6 A3 6 D8 4 vin3a_d12 H1 2 B3 6 - - A5 4 vin3a_d13 J3 2 B4 6 - - C6 4 vin3a_d14 H2 2 B5 6 - - C8 4 vin3a_d15 H3 2 A4 6 - - C7 4 vin3a_d16 R6 2 - - - - F11 4 vin3a_d17 T9 2 - - - - G10 4 vin3a_d18 T6 2 - - - - F10 4 vin3a_d19 T7 2 - - - - G11 4 vin3a_d20 P6 2 - - - - E9 4 vin3a_d21 R9 2 - - - - F9 4 vin3a_d22 R5 2 - - - - F8 4 vin3a_d23 P5 2 - - - - E7 4 vin3a_hsync0 N7 2 N7 2 B5 5 C11 4 vin3a_vsync0 R4 2 R4 2 A4 5 E11 4 vin3a_de0 N9 2 N9 2 B3 5 B10 4 vin3a_fld0 P9 2 P9 2 B4 5 D11 4 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-5. VIN3 IOSETs (continued) Signals vin3a_clk0 IOSET1 IOSET2 BALL MUX BALL P1 2 AH7 IOSET3 IOSET4 MUX BALL MUX BALL MUX 6 AH7 6 B11 4 vin3b vin3b_clk1 P7 6 M4 4 - - - - vin3b_de1 N6 6 N6 6 - - - - vin3b_fld1 M4 6 - - - - - - vin3b_d0 K7 6 K7 6 - - - - vin3b_d1 M7 6 M7 6 - - - - vin3b_d2 J5 6 J5 6 - - - - vin3b_d3 K6 6 K6 6 - - - - vin3b_d4 J7 6 J7 6 - - - - vin3b_d5 J4 6 J4 6 - - - - vin3b_d6 J6 6 J6 6 - - - - vin3b_d7 H4 6 H4 6 - - - - vin3b_hsync1 H5 6 H5 6 - - - - vin3b_vsync1 H6 6 H6 6 - - - - Table 7-6. VIN4 IOSETs Signals IOSET1 BALL IOSET2 MUX IOSET3 BALL MUX BALL MUX vin4a vin4a_d0 R6 4 B7 3 B14 8 vin4a_d1 T9 4 B8 3 J14 8 vin4a_d2 T6 4 A7 3 G13 8 vin4a_d3 T7 4 A8 3 J11 8 vin4a_d4 P6 4 C9 3 E12 8 vin4a_d5 R9 4 A9 3 F13 8 vin4a_d6 R5 4 B9 3 C12 8 vin4a_d7 P5 4 A10 3 D12 8 vin4a_d8 U2 4 E8 3 E15 8 vin4a_d9 U1 4 D9 3 A20 8 vin4a_d10 P3 4 D7 3 B15 8 vin4a_d11 R2 4 D8 3 A15 8 vin4a_d12 K7 4 A5 3 D15 8 vin4a_d13 M7 4 C6 3 B16 8 vin4a_d14 J5 4 C8 3 B17 8 vin4a_d15 K6 4 C7 3 A17 8 vin4a_d16 - - F11 3 C18 8 vin4a_d17 - - G10 3 A21 8 vin4a_d18 - - F10 3 G16 8 vin4a_d19 - - G11 3 D17 8 vin4a_d20 - - E9 3 AA3 8 vin4a_d21 - - F9 3 AB9 8 vin4a_d22 - - F8 3 AB3 8 vin4a_d23 - - E7 3 AA4 8 vin4a_hsync0 R3/ P7 4/4 C11 3 E21 8 vin4a_vsync0 T2/ N1 4/4 E11 3 F20 8 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 211 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-6. VIN4 IOSETs (continued) Signals IOSET1 IOSET2 BALL MUX vin4a_de0 H6/ P7 vin4a_fld0 P9/ J7 vin4a_clk0 IOSET3 BALL MUX BALL MUX 4/5 B10 3 C23 8 4/4 D11 3 F21 8 P4 4 B11 3 B26 8 vin4b_clk1 N9 6 V1 5 - - vin4b_de1 P9 6 V7 5 - - vin4b_fld1 P4 6 W2 5 - - vin4b_d0 R6 6 U4 5 - - vin4b_d1 T9 6 V2 5 - - vin4b_d2 T6 6 Y1 5 - - vin4b_d3 T7 6 W9 5 - - vin4b_d4 P6 6 V9 5 - - vin4b_d5 R9 6 U5 5 - - vin4b_d6 R5 6 V5 5 - - vin4b_d7 P5 6 V4 5 - - vin4b_hsync1 N7 6 U7 5 - - vin4b_vsync1 R4 6 V6 5 - - vin4b NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-7 Manual Functions Mapping for VIP1 for a definition of the Manual modes. Table 7-7 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. 212 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-7. Manual Functions Mapping for VIP1 BALL BALL NAME VIP1_MANUAL1 VIP1_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 0 1 2 3 4 U3 RMII_MHZ_5 0_CLK 1621 614 2018 279 CFG_RMII_MHZ_50_CLK _IN - - - - vin2a_d11 N6 gpmc_ben0 1756 1019 2235 494 CFG_GPMC_BEN0_IN - - - vin1b_hsync1 - M4 gpmc_ben1 1684 1107 2198 568 CFG_GPMC_BEN1_IN - - - vin1b_de1 - U4 mdio_d 1594 417 2007 36 CFG_MDIO_D_IN - - - - vin2a_d0 V1 mdio_mclk 0 0 0 0 CFG_MDIO_MCLK_IN - - - - vin2a_clk0 U5 rgmii0_rxc 1005 935 1932 0 CFG_RGMII0_RXC_IN - - - - vin2a_d5 V5 rgmii0_rxctl 1579 836 1982 485 CFG_RGMII0_RXCTL_IN - - - - vin2a_d6 W2 rgmii0_rxd0 1032 1033 1995 0 CFG_RGMII0_RXD0_IN - - - - vin2a_fld0 Y2 rgmii0_rxd1 950 1625 1993 673 CFG_RGMII0_RXD1_IN - - - - vin2a_d9 V3 rgmii0_rxd2 1578 832 1973 535 CFG_RGMII0_RXD2_IN - - - - vin2a_d8 V4 rgmii0_rxd3 1022 1648 2017 740 CFG_RGMII0_RXD3_IN - - - - vin2a_d7 W9 rgmii0_txc 1604 769 2020 393 CFG_RGMII0_TXC_IN - - - - vin2a_d3 V9 rgmii0_txctl 1060 1389 2074 396 CFG_RGMII0_TXCTL_IN - - - - vin2a_d4 U6 rgmii0_txd0 938 1242 2021 194 CFG_RGMII0_TXD0_IN - - - - vin2a_d10 V6 rgmii0_txd1 1013 1679 2036 730 CFG_RGMII0_TXD1_IN - - - - vin2a_vsync0 U7 rgmii0_txd2 1524 886 1933 526 CFG_RGMII0_TXD2_IN - - - - vin2a_hsync0 V7 rgmii0_txd3 1079 1504 2090 490 CFG_RGMII0_TXD3_IN - - - - vin2a_de0 V2 uart3_rxd 1530 125 1586 0 CFG_UART3_RXD_IN - - - - vin2a_d1 Y1 uart3_txd 1572 487 1980 16 CFG_UART3_TXD_IN - - - - vin2a_d2 AG8 vin1a_clk0 0 0 0 0 CFG_VIN1A_CLK0_IN vin1a_clk0 - - - - AE8 vin1a_d0 1697 1087 2105 619 CFG_VIN1A_D0_IN vin1a_d0 - - - - AD8 vin1a_d1 1589 1164 2017 757 CFG_VIN1A_D1_IN vin1a_d1 - - - - AG3 vin1a_d10 1733 1119 2107 739 CFG_VIN1A_D10_IN vin1a_d10 vin1b_d5 - - - AG5 vin1a_d11 1563 1210 2005 788 CFG_VIN1A_D11_IN vin1a_d11 vin1b_d4 - - - AF2 vin1a_d12 1705 1647 2059 1297 CFG_VIN1A_D12_IN vin1a_d12 vin1b_d3 - - - AF6 vin1a_d13 1624 1525 2027 1141 CFG_VIN1A_D13_IN vin1a_d13 vin1b_d2 - - - AF3 vin1a_d14 1730 1655 2071 1332 CFG_VIN1A_D14_IN vin1a_d14 vin1b_d1 - - - AF4 vin1a_d15 1681 2004 1995 1764 CFG_VIN1A_D15_IN vin1a_d15 vin1b_d0 - - - AF1 vin1a_d16 1659 1813 1999 1542 CFG_VIN1A_D16_IN vin1a_d16 vin1b_d7 - - - AE3 vin1a_d17 1715 1887 2072 1540 CFG_VIN1A_D17_IN vin1a_d17 vin1b_d6 - - - AE5 vin1a_d18 1728 1898 2034 1629 CFG_VIN1A_D18_IN vin1a_d18 vin1b_d5 - - - Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 213 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-7. Manual Functions Mapping for VIP1 (continued) BALL BALL NAME VIP1_MANUAL1 VIP1_MANUAL2 CFG REGISTER A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) vin1a_d19 1707 2006 2026 1761 AG7 vin1a_d2 1557 1414 1996 962 CFG_VIN1A_D2_IN AE2 vin1a_d20 1695 1814 2037 1469 CFG_VIN1A_D20_IN AE6 vin1a_d21 1757 1682 2077 1349 CFG_VIN1A_D21_IN AD2 vin1a_d22 1683 1813 2022 1545 AD3 vin1a_d23 1833 1187 2168 AH6 vin1a_d3 1588 1289 1993 AH3 vin1a_d4 1687 949 AE1 MUXMODE 0 1 2 3 4 vin1a_d19 vin1b_d4 - - - vin1a_d2 - - - - vin1a_d20 vin1b_d3 - - - vin1a_d21 vin1b_d2 - - - CFG_VIN1A_D22_IN vin1a_d22 vin1b_d1 - - - 784 CFG_VIN1A_D23_IN vin1a_d23 vin1b_d0 - - - 901 CFG_VIN1A_D3_IN vin1a_d3 - - - - 2098 499 CFG_VIN1A_D4_IN vin1a_d4 - - - - CFG_VIN1A_D19_IN AH5 vin1a_d5 1616 1257 2038 844 CFG_VIN1A_D5_IN vin1a_d5 - - - - AG6 vin1a_d6 1582 1265 2002 863 CFG_VIN1A_D6_IN vin1a_d6 - - - - AH4 vin1a_d7 1659 1255 2063 873 CFG_VIN1A_D7_IN vin1a_d7 - - - - AG4 vin1a_d8 1681 1205 2088 759 CFG_VIN1A_D8_IN vin1a_d8 vin1b_d7 - - - AG2 vin1a_d9 1778 1168 2152 701 CFG_VIN1A_D9_IN vin1a_d9 vin1b_d6 - - - AD9 vin1a_de0 1468 1290 1926 728 CFG_VIN1A_DE0_IN vin1a_de0 vin1b_hsync1 - - - AF9 vin1a_fld0 1633 1425 2043 937 CFG_VIN1A_FLD0_IN vin1a_fld0 vin1b_vsync1 - - - AE9 vin1a_hsync0 1561 1424 1978 909 CFG_VIN1A_HSYNC0_IN vin1a_hsync0 vin1b_fld1 - - - AF8 vin1a_vsync0 1470 1369 1926 987 CFG_VIN1A_VSYNC0_IN vin1a_vsync0 vin1b_de1 - - - AH7 vin1b_clk1 69 150 242 0 CFG_VIN1B_CLK1_IN vin1b_clk1 - - - - E1 vin2a_clk0 0 0 0 0 CFG_VIN2A_CLK0_IN vin2a_clk0 - - - - F2 vin2a_d0 1597 561 2009 147 CFG_VIN2A_D0_IN vin2a_d0 - - - - F3 vin2a_d1 1598 801 2015 561 CFG_VIN2A_D1_IN vin2a_d1 - - - - D3 vin2a_d10 1576 655 2021 377 CFG_VIN2A_D10_IN vin2a_d10 - - - - F6 vin2a_d11 1488 340 1940 19 CFG_VIN2A_D11_IN vin2a_d11 - - - - D5 vin2a_d12 1399 612 1895 181 CFG_VIN2A_D12_IN vin2a_d12 - - - - C2 vin2a_d13 1595 439 2063 15 CFG_VIN2A_D13_IN vin2a_d13 - - - - C3 vin2a_d14 1480 243 1709 0 CFG_VIN2A_D14_IN vin2a_d14 - - - - C4 vin2a_d15 1415 755 1899 369 CFG_VIN2A_D15_IN vin2a_d15 - - - - B2 vin2a_d16 1341 653 1821 317 CFG_VIN2A_D16_IN vin2a_d16 - vin2b_d7 - - D6 vin2a_d17 1396 724 1880 349 CFG_VIN2A_D17_IN vin2a_d17 - vin2b_d6 - - C5 vin2a_d18 1582 364 1963 0 CFG_VIN2A_D18_IN vin2a_d18 - vin2b_d5 - - A3 vin2a_d19 1308 289 1681 0 CFG_VIN2A_D19_IN vin2a_d19 - vin2b_d4 - - D1 vin2a_d2 1600 323 2021 0 CFG_VIN2A_D2_IN vin2a_d2 - - - - 214 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-7. Manual Functions Mapping for VIP1 (continued) BALL BALL NAME VIP1_MANUAL1 VIP1_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 0 1 2 3 4 B3 vin2a_d20 1307 586 1772 299 CFG_VIN2A_D20_IN vin2a_d20 - vin2b_d3 - - B4 vin2a_d21 1301 640 1787 282 CFG_VIN2A_D21_IN vin2a_d21 - vin2b_d2 - - B5 vin2a_d22 1316 534 1789 223 CFG_VIN2A_D22_IN vin2a_d22 - vin2b_d1 - - A4 vin2a_d23 1311 613 1788 286 CFG_VIN2A_D23_IN vin2a_d23 - vin2b_d0 - - E2 vin2a_d3 1765 720 2142 492 CFG_VIN2A_D3_IN vin2a_d3 - - - - D2 vin2a_d4 1680 282 2071 0 CFG_VIN2A_D4_IN vin2a_d4 - - - - F4 vin2a_d5 1791 696 2155 461 CFG_VIN2A_D5_IN vin2a_d5 - - - - C1 vin2a_d6 1538 175 1849 0 CFG_VIN2A_D6_IN vin2a_d6 - - - - E4 vin2a_d7 1546 451 1977 192 CFG_VIN2A_D7_IN vin2a_d7 - - - - F5 vin2a_d8 1522 650 1966 391 CFG_VIN2A_D8_IN vin2a_d8 - - - - E6 vin2a_d9 1546 578 1996 270 CFG_VIN2A_D9_IN vin2a_d9 - - - - G2 vin2a_de0 1548 623 2036 213 CFG_VIN2A_DE0_IN vin2a_de0 vin2a_fld0 vin2b_fld1 vin2b_de1 - H7 vin2a_fld0 1771 815 2162 566 CFG_VIN2A_FLD0_IN vin2a_fld0 - vin2b_clk1 - - G1 vin2a_hsync0 1703 587 2071 225 CFG_VIN2A_HSYNC0_IN vin2a_hsync0 - - vin2b_hsync1 - G6 vin2a_vsync0 1486 464 1895 53 CFG_VIN2A_VSYNC0_IN vin2a_vsync0 - - vin2b_vsync1 - Manual IO Timings Modes must be used to guarantee some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-8 Manual Functions Mapping for VIP1 2B for a definition of the Manual modes. Table 7-8 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-8. Manual Functions Mapping for VIP1 2B BALL BALL NAME VIP1_2B_MANUAL1 VIP1_2B_MANUAL2 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 2 3 4 AC5 gpio6_10 1830 911 2136 593 CFG_GPIO6_10_IN - - vin2b_hsync1 AB4 gpio6_11 1797 1159 2088 926 CFG_GPIO6_11_IN - - vin2b_vsync1 AC4 mmc3_cmd 1769 980 2092 650 CFG_MMC3_CMD_IN - - vin2b_d6 AC7 mmc3_dat0 1678 984 2027 691 CFG_MMC3_DAT0_IN - - vin2b_d5 AC6 mmc3_dat1 1664 883 2031 491 CFG_MMC3_DAT1_IN - - vin2b_d4 AC9 mmc3_dat2 1672 439 2065 0 CFG_MMC3_DAT2_IN - - vin2b_d3 AC3 mmc3_dat3 1762 1078 2089 799 CFG_MMC3_DAT3_IN - - vin2b_d2 AC8 mmc3_dat4 1766 583 2125 135 CFG_MMC3_DAT4_IN - - vin2b_d1 AD6 mmc3_dat5 1777 577 2072 362 CFG_MMC3_DAT5_IN - - vin2b_d0 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 215 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-8. Manual Functions Mapping for VIP1 2B (continued) BALL BALL NAME VIP1_2B_MANUAL1 VIP1_2B_MANUAL2 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 2 3 4 AB8 mmc3_dat6 1675 808 2035 431 CFG_MMC3_DAT6_IN - - vin2b_de1 AB5 mmc3_dat7 0 0 0 0 CFG_MMC3_DAT7_IN - - vin2b_clk1 B2 vin2a_d16 1181 0 1424 0 CFG_VIN2A_D16_IN vin2b_d7 - - D6 vin2a_d17 1317 0 1545 0 CFG_VIN2A_D17_IN vin2b_d6 - - C5 vin2a_d18 1132 0 1240 0 CFG_VIN2A_D18_IN vin2b_d5 - - A3 vin2a_d19 749 0 919 0 CFG_VIN2A_D19_IN vin2b_d4 - - B3 vin2a_d20 1078 0 1320 0 CFG_VIN2A_D20_IN vin2b_d3 - - B4 vin2a_d21 1119 0 1357 0 CFG_VIN2A_D21_IN vin2b_d2 - - B5 vin2a_d22 1089 0 1306 0 CFG_VIN2A_D22_IN vin2b_d1 - - A4 vin2a_d23 1118 0 1362 0 CFG_VIN2A_D23_IN vin2b_d0 - - G2 vin2a_de0 1371 420 1813 86 CFG_VIN2A_DE0_IN vin2b_fld1 vin2b_de1 - H7 vin2a_fld0 0 0 0 0 CFG_VIN2A_FLD0_IN vin2b_clk1 - - G1 vin2a_hsync0 1605 0 1674 0 CFG_VIN2A_HSYNC0_IN - vin2b_hsync1 - G6 vin2a_vsync0 1231 0 1300 0 CFG_VIN2A_VSYNC0_IN - vin2b_vsync1 - Manual IO Timings Modes must be used to guarantee some IO timings for VIP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-9 Manual Functions Mapping for VIP2 for a definition of the Manual modes. Table 7-9 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-9. Manual Functions Mapping for VIP2 BALL BALL NAME VIP2_MANUAL 1 A_DELAY (ps) VIP2_MANUAL2 G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 2 3 4 5 6 R6 gpmc_a0 2216 947 2519 702 CFG_GPMC_A0_IN vin3a_d16 - vin4a_d0 - - T9 gpmc_a1 2078 1022 2384 778 CFG_GPMC_A1_IN vin3a_d17 - vin4a_d1 - - N9 gpmc_a10 2108 823 2435 411 CFG_GPMC_A10_IN vin3a_de0 - - - - P9 gpmc_a11 2068 977 2379 755 CFG_GPMC_A11_IN vin3a_fld0 - vin4a_fld0 - - K7 gpmc_a19 1740 123 1743 0 CFG_GPMC_A19_IN - - vin4a_d12 - vin3b_d0 T6 gpmc_a2 2280 1298 2499 1127 CFG_GPMC_A2_IN vin3a_d18 - vin4a_d2 - - M7 gpmc_a20 1628 30 1529 0 CFG_GPMC_A20_IN - - vin4a_d13 - vin3b_d1 J5 gpmc_a21 1687 217 1779 0 CFG_GPMC_A21_IN - - vin4a_d14 - vin3b_d2 K6 gpmc_a22 1595 151 1620 0 CFG_GPMC_A22_IN - - vin4a_d15 - vin3b_d3 216 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-9. Manual Functions Mapping for VIP2 (continued) BALL BALL NAME VIP2_MANUAL 1 VIP2_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 2 3 4 5 6 J7 gpmc_a23 1366 0 1363 0 CFG_GPMC_A23_IN - - vin4a_fld0 - vin3b_d4 J4 gpmc_a24 1554 343 1765 0 CFG_GPMC_A24_IN - - vin4a_d8 - vin3b_d5 J6 gpmc_a25 1652 268 1808 0 CFG_GPMC_A25_IN - - vin4a_d9 - vin3b_d6 H4 gpmc_a26 1546 281 1669 0 CFG_GPMC_A26_IN - - vin4a_d10 - vin3b_d7 H5 gpmc_a27 1534 198 1611 0 CFG_GPMC_A27_IN - - vin4a_d11 - vin3b_hsync 1 T7 gpmc_a3 2246 1318 2455 1181 CFG_GPMC_A3_IN vin3a_d19 - vin4a_d3 - - P6 gpmc_a4 2266 1216 2486 1039 CFG_GPMC_A4_IN vin3a_d20 - vin4a_d4 - - R9 gpmc_a5 2185 1122 2456 938 CFG_GPMC_A5_IN vin3a_d21 - vin4a_d5 - - R5 gpmc_a6 2206 782 2463 573 CFG_GPMC_A6_IN vin3a_d22 - vin4a_d6 - - P5 gpmc_a7 2369 1025 2608 783 CFG_GPMC_A7_IN vin3a_d23 - vin4a_d7 - - N7 gpmc_a8 2154 978 2430 656 CFG_GPMC_A8_IN vin3a_hsync 0 - - - - R4 gpmc_a9 2185 1152 2465 850 CFG_GPMC_A9_IN vin3a_vsync0 - - - - M6 gpmc_ad0 1908 620 2316 301 CFG_GPMC_AD0_IN vin3a_d0 - - - - M2 gpmc_ad1 2117 382 2440 70 CFG_GPMC_AD1_IN vin3a_d1 - - - - J1 gpmc_ad10 1968 686 2324 406 CFG_GPMC_AD10_IN vin3a_d10 - - - - J2 gpmc_ad11 1853 689 2278 352 CFG_GPMC_AD11_IN vin3a_d11 - - - - H1 gpmc_ad12 1910 497 2297 160 CFG_GPMC_AD12_IN vin3a_d12 - - - - J3 gpmc_ad13 1869 436 2278 108 CFG_GPMC_AD13_IN vin3a_d13 - - - - H2 gpmc_ad14 1895 147 2035 0 CFG_GPMC_AD14_IN vin3a_d14 - - - - H3 gpmc_ad15 1917 655 2279 378 CFG_GPMC_AD15_IN vin3a_d15 - - - - L5 gpmc_ad2 2097 666 2404 446 CFG_GPMC_AD2_IN vin3a_d2 - - - - M1 gpmc_ad3 1954 581 2343 212 CFG_GPMC_AD3_IN vin3a_d3 - - - - L6 gpmc_ad4 2034 610 2355 322 CFG_GPMC_AD4_IN vin3a_d4 - - - - L4 gpmc_ad5 1965 484 2337 192 CFG_GPMC_AD5_IN vin3a_d5 - - - - L3 gpmc_ad6 1861 635 2270 314 CFG_GPMC_AD6_IN vin3a_d6 - - - - L2 gpmc_ad7 2004 507 2339 259 CFG_GPMC_AD7_IN vin3a_d7 - - - - L1 gpmc_ad8 1945 853 2308 577 CFG_GPMC_AD8_IN vin3a_d8 - - - K2 gpmc_ad9 1914 539 2334 166 CFG_GPMC_AD9_IN vin3a_d9 - - - - N6 gpmc_ben0 1806 0 1722 0 CFG_GPMC_BEN0_IN - - - - vin3b_de1 M4 gpmc_ben1 1879 20 1840 0 CFG_GPMC_BEN1_IN - - vin3b_clk1 - vin3b_fld1 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 217 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-9. Manual Functions Mapping for VIP2 (continued) BALL BALL NAME VIP2_MANUAL 1 VIP2_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 2 3 4 5 6 - - vin4a_hsync 0 vin4a_de0 vin3b_clk1 vin3b_vsync1 P7 gpmc_clk 0 0 0 0 CFG_GPMC_CLK_IN H6 gpmc_cs1 1505 41 1388 0 CFG_GPMC_CS1_IN - - vin4a_de0 - P1 gpmc_cs3 0 0 0 0 CFG_GPMC_CS3_IN vin3a_clk0 - - - - AF1 vin1a_d16 1803 1679 2244 1202 CFG_VIN1A_D16_IN - - - - vin3a_d0 AE3 vin1a_d17 1871 1654 2321 1116 CFG_VIN1A_D17_IN - - - - vin3a_d1 AE5 vin1a_d18 1875 1742 2280 1288 CFG_VIN1A_D18_IN - - - - vin3a_d2 AE1 vin1a_d19 1844 1759 2282 1281 CFG_VIN1A_D19_IN - - - - vin3a_d3 AE2 vin1a_d20 1845 1624 2284 1090 CFG_VIN1A_D20_IN - - - - vin3a_d4 AE6 vin1a_d21 1906 1520 2324 1000 CFG_VIN1A_D21_IN - - - - vin3a_d5 AD2 vin1a_d22 1807 1437 2278 915 CFG_VIN1A_D22_IN - - - - vin3a_d6 AD3 vin1a_d23 1996 997 2423 398 CFG_VIN1A_D23_IN - - - - vin3a_d7 AH7 vin1b_clk1 0 0 0 0 CFG_VIN1B_CLK1_IN - - - - vin3a_clk0 B2 vin2a_d16 1329 528 1779 0 CFG_VIN2A_D16_IN - - - - vin3a_d8 D6 vin2a_d17 1270 677 1844 0 CFG_VIN2A_D17_IN - - - - vin3a_d9 C5 vin2a_d18 1494 411 1767 0 CFG_VIN2A_D18_IN - - - - vin3a_d10 A3 vin2a_d19 1225 154 1254 0 CFG_VIN2A_D19_IN - - - - vin3a_d11 B3 vin2a_d20 1212 450 1597 0 CFG_VIN2A_D20_IN - - - vin3a_de0 vin3a_d12 B4 vin2a_d21 1232 494 1662 0 CFG_VIN2A_D21_IN - - - vin3a_fld0 vin3a_d13 B5 vin2a_d22 1203 503 1641 0 CFG_VIN2A_D22_IN - - - vin3a_hsync 0 vin3a_d14 A4 vin2a_d23 1214 599 1748 0 CFG_VIN2A_D23_IN - - - vin3a_vsync0 vin3a_d15 D11 vout1_clk 2047 735 2391 637 CFG_VOUT1_CLK_IN - vin4a_fld0 vin3a_fld0 - - F11 vout1_d0 2135 987 2403 965 CFG_VOUT1_D0_IN - vin4a_d16 vin3a_d16 - - G10 vout1_d1 2048 955 2368 880 CFG_VOUT1_D1_IN - vin4a_d17 vin3a_d17 - - D7 vout1_d10 1970 855 2347 724 CFG_VOUT1_D10_IN - vin4a_d10 vin3a_d10 - - D8 vout1_d11 2111 893 2389 861 CFG_VOUT1_D11_IN - vin4a_d11 vin3a_d11 - - A5 vout1_d12 2018 841 2356 748 CFG_VOUT1_D12_IN - vin4a_d12 vin3a_d12 - - C6 vout1_d13 2073 805 2382 731 CFG_VOUT1_D13_IN - vin4a_d13 vin3a_d13 - - C8 vout1_d14 2112 770 2401 703 CFG_VOUT1_D14_IN - vin4a_d14 vin3a_d14 - - C7 vout1_d15 2132 831 2434 771 CFG_VOUT1_D15_IN - vin4a_d15 vin3a_d15 - - B7 vout1_d16 1996 632 2338 536 CFG_VOUT1_D16_IN - vin4a_d0 vin3a_d0 - - 218 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-9. Manual Functions Mapping for VIP2 (continued) BALL BALL NAME VIP2_MANUAL 1 VIP2_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 2 3 4 5 6 B8 vout1_d17 2190 790 2442 775 CFG_VOUT1_D17_IN - vin4a_d1 vin3a_d1 - - A7 vout1_d18 2100 604 2385 565 CFG_VOUT1_D18_IN - vin4a_d2 vin3a_d2 - - A8 vout1_d19 2108 286 2424 168 CFG_VOUT1_D19_IN - vin4a_d3 vin3a_d3 - - F10 vout1_d2 1979 1020 2335 909 CFG_VOUT1_D2_IN - vin4a_d18 vin3a_d18 - - C9 vout1_d20 2031 967 2362 881 CFG_VOUT1_D20_IN - vin4a_d4 vin3a_d4 - - A9 vout1_d21 2039 450 2350 384 CFG_VOUT1_D21_IN - vin4a_d5 vin3a_d5 - - B9 vout1_d22 2037 583 2369 497 CFG_VOUT1_D22_IN - vin4a_d6 vin3a_d6 - - A10 vout1_d23 1768 740 2246 508 CFG_VOUT1_D23_IN - vin4a_d7 vin3a_d7 - - G11 vout1_d3 2099 881 2382 844 CFG_VOUT1_D3_IN - vin4a_d19 vin3a_d19 - - E9 vout1_d4 2120 786 2387 756 CFG_VOUT1_D4_IN - vin4a_d20 vin3a_d20 - - F9 vout1_d5 1965 857 2299 769 CFG_VOUT1_D5_IN - vin4a_d21 vin3a_d21 - - F8 vout1_d6 2139 680 2366 699 CFG_VOUT1_D6_IN - vin4a_d22 vin3a_d22 - - E7 vout1_d7 2122 912 2360 920 CFG_VOUT1_D7_IN - vin4a_d23 vin3a_d23 - - E8 vout1_d8 2073 906 2372 853 CFG_VOUT1_D8_IN - vin4a_d8 vin3a_d8 - - D9 vout1_d9 2097 934 2386 879 CFG_VOUT1_D9_IN - vin4a_d9 vin3a_d9 - - B10 vout1_de 2021 527 2366 428 CFG_VOUT1_DE_IN - vin4a_de0 vin3a_de0 - - B11 vout1_fld 0 0 0 0 CFG_VOUT1_FLD_IN - vin4a_clk0 vin3a_clk0 - - C11 vout1_hsync 1775 486 2272 164 CFG_VOUT1_HSYNC_IN - vin4a_hsync 0 vin3a_hsync 0 - - E11 vout1_vsync 1917 314 2301 0 CFG_VOUT1_VSYNC_IN - vin4a_vsync0 vin3a_vsync0 - - Manual IO Timings Modes must be used to guarantee some IO timings for VIP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-10 Manual Functions Mapping for VIP2 4A for a definition of the Manual modes. Table 7-10 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-10. Manual Functions Mapping for VIP2 4A BALL BALL NAME VIP2_4A_MANUAL1 VIP2_4A_MANUAL2 CFG REGISTER A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) R6 gpmc_a0 1801 521 2268 0 MUXMODE 3 4 5 CFG_GPMC_A0_IN - vin4a_d0 - T9 gpmc_a1 1668 488 2135 0 CFG_GPMC_A1_IN - vin4a_d1 - P9 gpmc_a11 1694 308 2026 0 CFG_GPMC_A11_IN - vin4a_fld0 - P4 gpmc_a12 0 0 0 0 CFG_GPMC_A12_IN - vin4a_clk0 - Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 219 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-10. Manual Functions Mapping for VIP2 4A (continued) BALL BALL NAME VIP2_4A_MANUAL1 VIP2_4A_MANUAL2 CFG REGISTER 3 4 5 R3 gpmc_a13 1529 570 2029 38 CFG_GPMC_A13_IN - vin4a_hsync0 - T2 gpmc_a14 1747 753 2266 261 CFG_GPMC_A14_IN - vin4a_vsync0 - U2 gpmc_a15 1536 336 1882 0 CFG_GPMC_A15_IN - vin4a_d8 - U1 gpmc_a16 1662 293 1936 0 CFG_GPMC_A16_IN - vin4a_d9 - P3 gpmc_a17 1637 247 1851 0 CFG_GPMC_A17_IN - vin4a_d10 - R2 gpmc_a18 1454 0 1369 0 CFG_GPMC_A18_IN - vin4a_d11 - K7 gpmc_a19 1577 205 1634 0 CFG_GPMC_A19_IN - vin4a_d12 - T6 gpmc_a2 1891 747 2369 238 CFG_GPMC_A2_IN - vin4a_d2 - M7 gpmc_a20 1398 220 1450 0 CFG_GPMC_A20_IN - vin4a_d13 - A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) MUXMODE J5 gpmc_a21 1521 329 1691 0 CFG_GPMC_A21_IN - vin4a_d14 - K6 gpmc_a22 1383 273 1488 0 CFG_GPMC_A22_IN - vin4a_d15 - J7 gpmc_a23 1163 0 1147 0 CFG_GPMC_A23_IN - vin4a_fld0 - T7 gpmc_a3 1820 786 2325 271 CFG_GPMC_A3_IN - vin4a_d3 - P6 gpmc_a4 1865 662 2359 126 CFG_GPMC_A4_IN - vin4a_d4 - R9 gpmc_a5 1722 629 2260 53 CFG_GPMC_A5_IN - vin4a_d5 - R5 gpmc_a6 1755 279 1990 0 CFG_GPMC_A6_IN - vin4a_d6 - P5 gpmc_a7 1979 506 2410 0 CFG_GPMC_A7_IN - vin4a_d7 - N1 gpmc_advn_ale 1793 267 2045 0 CFG_GPMC_ADVN_ALE_IN - vin4a_vsync0 - P7 gpmc_clk 1738 309 2040 0 CFG_GPMC_CLK_IN - vin4a_hsync0 vin4a_de0 H6 gpmc_cs1 1379 95 1361 0 CFG_GPMC_CS1_IN - vin4a_de0 - D11 vout1_clk 2090 401 2409 357 CFG_VOUT1_CLK_IN vin4a_fld0 - - F11 vout1_d0 2139 961 2394 981 CFG_VOUT1_D0_IN vin4a_d16 - - G10 vout1_d1 1993 878 2347 799 CFG_VOUT1_D1_IN vin4a_d17 - - D7 vout1_d10 1976 678 2346 583 CFG_VOUT1_D10_IN vin4a_d10 - - D8 vout1_d11 2135 749 2393 767 CFG_VOUT1_D11_IN vin4a_d11 - - A5 vout1_d12 2014 696 2351 634 CFG_VOUT1_D12_IN vin4a_d12 - - C6 vout1_d13 2035 590 2370 531 CFG_VOUT1_D13_IN vin4a_d13 - - C8 vout1_d14 2108 861 2385 860 CFG_VOUT1_D14_IN vin4a_d14 - - C7 vout1_d15 2074 682 2423 609 CFG_VOUT1_D15_IN vin4a_d15 - - B7 vout1_d16 1976 579 2331 500 CFG_VOUT1_D16_IN vin4a_d0 - - B8 vout1_d17 2203 505 2464 509 CFG_VOUT1_D17_IN vin4a_d1 - - A7 vout1_d18 2096 412 2394 390 CFG_VOUT1_D18_IN vin4a_d2 - - 220 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-10. Manual Functions Mapping for VIP2 4A (continued) BALL BALL NAME VIP2_4A_MANUAL1 VIP2_4A_MANUAL2 CFG REGISTER MUXMODE 3 4 5 A8 vout1_d19 2106 72 2423 21 CFG_VOUT1_D19_IN vin4a_d3 - - F10 vout1_d2 2023 648 2374 572 CFG_VOUT1_D2_IN vin4a_d18 - - C9 vout1_d20 2027 767 2370 700 CFG_VOUT1_D20_IN vin4a_d4 - - A9 vout1_d21 2026 184 2354 128 CFG_VOUT1_D21_IN vin4a_d5 - - B9 vout1_d22 2061 195 2397 135 CFG_VOUT1_D22_IN vin4a_d6 - - A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A10 vout1_d23 1764 607 2251 396 CFG_VOUT1_D23_IN vin4a_d7 - - G11 vout1_d3 2053 757 2377 707 CFG_VOUT1_D3_IN vin4a_d19 - - E9 vout1_d4 2119 617 2392 619 CFG_VOUT1_D4_IN vin4a_d20 - - F9 vout1_d5 1951 712 2305 633 CFG_VOUT1_D5_IN vin4a_d21 - - F8 vout1_d6 2119 515 2365 543 CFG_VOUT1_D6_IN vin4a_d22 - - E7 vout1_d7 2119 779 2363 810 CFG_VOUT1_D7_IN vin4a_d23 - - E8 vout1_d8 2043 807 2357 768 CFG_VOUT1_D8_IN vin4a_d8 - - D9 vout1_d9 2166 643 2412 671 CFG_VOUT1_D9_IN vin4a_d9 - - B10 vout1_de 1982 410 2353 314 CFG_VOUT1_DE_IN vin4a_de0 - - B11 vout1_fld 0 0 0 0 CFG_VOUT1_FLD_IN vin4a_clk0 - - C11 vout1_hsync 1755 305 2269 4 CFG_VOUT1_HSYNC_IN vin4a_hsync0 - - E11 vout1_vsync 1924 8 2066 0 CFG_VOUT1_VSYNC_IN vin4a_vsync0 - - Manual IO Timings Modes must be used to guarantee some IO timings for VIP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-11 Manual Functions Mapping for VIP2 4A IOSET3 for a definition of the Manual modes. Table 7-11 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-11. Manual Functions Mapping for VIP2 4A IOSET3 BALL BALL NAME VIP2_4A_IOSET3_MANUAL1 VIP2_4A_IOSET3_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 8 E21 gpio6_14 683 0 939 0 CFG_GPIO6_14_IN vin4a_hsync0 F20 gpio6_15 1065 0 1321 0 CFG_GPIO6_15_IN vin4a_vsync0 F21 gpio6_16 858 0 1114 0 CFG_GPIO6_16_IN vin4a_fld0 B14 mcasp1_aclkr 1711 23 1990 0 CFG_MCASP1_ACLKR_IN vin4a_d0 G13 mcasp1_axr2 2131 1054 2423 1073 CFG_MCASP1_AXR2_IN vin4a_d2 J11 mcasp1_axr3 2267 691 2573 696 CFG_MCASP1_AXR3_IN vin4a_d3 E12 mcasp1_axr4 2089 813 2441 773 CFG_MCASP1_AXR4_IN vin4a_d4 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 221 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-11. Manual Functions Mapping for VIP2 4A IOSET3 (continued) BALL BALL NAME VIP2_4A_IOSET3_MANUAL1 VIP2_4A_IOSET3_MANUAL2 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) F13 mcasp1_axr5 2061 858 2430 799 CFG_MCASP1_AXR5_IN vin4a_d5 C12 mcasp1_axr6 2151 595 2539 480 CFG_MCASP1_AXR6_IN vin4a_d6 D12 mcasp1_axr7 2112 J14 mcasp1_fsr 1714 931 2421 932 CFG_MCASP1_AXR7_IN vin4a_d7 323 2248 44 CFG_MCASP1_FSR_IN E15 mcasp2_aclkr vin4a_d1 1462 76 1795 0 CFG_MCASP2_ACLKR_IN vin4a_d8 B15 A15 mcasp2_axr0 1578 833 2113 554 CFG_MCASP2_AXR0_IN vin4a_d10 mcasp2_axr1 1785 396 2279 212 CFG_MCASP2_AXR1_IN vin4a_d11 D15 mcasp2_axr4 1765 485 2299 206 CFG_MCASP2_AXR4_IN vin4a_d12 B16 mcasp2_axr5 1644 509 2179 230 CFG_MCASP2_AXR5_IN vin4a_d13 B17 mcasp2_axr6 1098 0 1354 0 CFG_MCASP2_AXR6_IN vin4a_d14 A17 mcasp2_axr7 1242 521 1777 243 CFG_MCASP2_AXR7_IN vin4a_d15 A20 mcasp2_fsr 1328 130 1713 0 CFG_MCASP2_FSR_IN vin4a_d9 8 C18 mcasp4_aclkx 1033 0 1166 0 CFG_MCASP4_ACLKX_IN vin4a_d16 G16 mcasp4_axr0 2147 358 2529 221 CFG_MCASP4_AXR0_IN vin4a_d18 D17 mcasp4_axr1 2140 676 2482 645 CFG_MCASP4_AXR1_IN vin4a_d19 A21 mcasp4_fsx 2140 339 2554 165 CFG_MCASP4_FSX_IN vin4a_d17 AA3 mcasp5_aclkx 2846 2620 3059 2547 CFG_MCASP5_ACLKX_IN vin4a_d20 AB3 mcasp5_axr0 2880 3301 3040 3417 CFG_MCASP5_AXR0_IN vin4a_d22 AA4 mcasp5_axr1 2851 3586 3042 3593 CFG_MCASP5_AXR1_IN vin4a_d23 AB9 mcasp5_fsx 2847 2856 3031 2890 CFG_MCASP5_FSX_IN vin4a_d21 B26 xref_clk2 0 0 0 0 CFG_XREF_CLK2_IN vin4a_clk0 C23 xref_clk3 927 0 1183 0 CFG_XREF_CLK3_IN vin4a_de0 Manual IO Timings Modes must be used to guarantee some IO timings for VIP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-12 Manual Functions Mapping for VIP2 4B for a definition of the Manual modes. Table 7-12 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-12. Manual Functions Mapping for VIP2 4B BALL BALL NAME A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 5 6 R6 gpmc_a0 1861 901 2102 660 CFG_GPMC_A0_IN - vin4b_d0 T9 gpmc_a1 1652 891 1955 583 CFG_GPMC_A1_IN - vin4b_d1 222 VIP2_4B_MANUAL1 Timing Requirements and Switching Characteristics VIP2_4B_MANUAL2 CFG REGISTER MUXMODE Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-12. Manual Functions Mapping for VIP2 4B (continued) BALL BALL NAME VIP2_4B_MANUAL1 VIP2_4B_MANUAL2 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 5 6 N9 gpmc_a10 0 0 0 0 CFG_GPMC_A10_IN - vin4b_clk1 P9 gpmc_a11 1783 1178 1975 1021 CFG_GPMC_A11_IN - vin4b_de1 P4 gpmc_a12 1903 853 2076 664 CFG_GPMC_A12_IN - vin4b_fld1 T6 gpmc_a2 1888 1212 2065 994 CFG_GPMC_A2_IN - vin4b_d2 T7 gpmc_a3 1839 1274 2025 1075 CFG_GPMC_A3_IN - vin4b_d3 P6 gpmc_a4 1868 1113 2058 869 CFG_GPMC_A4_IN - vin4b_d4 R9 gpmc_a5 1757 1079 2028 802 CFG_GPMC_A5_IN - vin4b_d5 R5 gpmc_a6 1800 670 2032 421 CFG_GPMC_A6_IN - vin4b_d6 P5 gpmc_a7 1967 898 2179 597 CFG_GPMC_A7_IN - vin4b_d7 N7 gpmc_a8 1731 959 1993 559 CFG_GPMC_A8_IN - vin4b_hsync1 R4 gpmc_a9 1766 1150 2022 834 CFG_GPMC_A9_IN - vin4b_vsync1 U4 mdio_d 1602 506 1931 283 CFG_MDIO_D_IN vin4b_d0 - V1 mdio_mclk 0 0 0 0 CFG_MDIO_MCLK_IN vin4b_clk1 - U5 rgmii0_rxc 1678 887 1987 663 CFG_RGMII0_RXC_IN vin4b_d5 - V5 rgmii0_rxctl 1595 932 1903 748 CFG_RGMII0_RXCTL_IN vin4b_d6 - W2 rgmii0_rxd0 1707 464 2010 160 CFG_RGMII0_RXD0_IN vin4b_fld1 - V4 rgmii0_rxd3 1662 1146 1943 996 CFG_RGMII0_RXD3_IN vin4b_d7 - W9 rgmii0_txc 1639 1195 1970 1006 CFG_RGMII0_TXC_IN vin4b_d3 - V9 rgmii0_txctl 1695 1226 1952 1113 CFG_RGMII0_TXCTL_IN vin4b_d4 - V6 rgmii0_txd1 1693 1118 1951 1003 CFG_RGMII0_TXD1_IN vin4b_vsync1 - U7 rgmii0_txd2 1522 1004 1895 685 CFG_RGMII0_TXD2_IN vin4b_hsync1 - V7 rgmii0_txd3 1777 957 2018 787 CFG_RGMII0_TXD3_IN vin4b_de1 - V2 uart3_rxd 1537 236 1762 0 CFG_UART3_RXD_IN vin4b_d1 - Y1 uart3_txd 1575 645 1933 276 CFG_UART3_TXD_IN vin4b_d2 - Manual IO Timings Modes must be used to guarantee some IO timings for VIP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-13 Manual Functions Mapping for VIP2 3B IOSET2 for a definition of the Manual modes. Table 7-13 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 223 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-13. Manual Functions Mapping for VIP2 3B IOSET2 BALL BALL NAME VIP2_3B_IOSET2_MANUAL1 VIP2_3B_IOSET2_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 4 6 K7 gpmc_a19 1505 1172 1854 799 CFG_GPMC_A19_IN - vin3b_d0 M7 gpmc_a20 1394 1074 1723 716 CFG_GPMC_A20_IN - vin3b_d1 J5 gpmc_a21 1452 1266 1789 900 CFG_GPMC_A21_IN - vin3b_d2 K6 gpmc_a22 1360 1200 1684 847 CFG_GPMC_A22_IN - vin3b_d3 J7 gpmc_a23 1446 735 1831 443 CFG_GPMC_A23_IN - vin3b_d4 J4 gpmc_a24 1329 1360 1686 970 CFG_GPMC_A24_IN - vin3b_d5 J6 gpmc_a25 1417 1318 1757 962 CFG_GPMC_A25_IN - vin3b_d6 H4 gpmc_a26 1321 1298 1680 880 CFG_GPMC_A26_IN - vin3b_d7 H5 gpmc_a27 1309 1215 1669 834 CFG_GPMC_A27_IN - vin3b_hsync1 N6 gpmc_ben0 1677 944 1994 638 CFG_GPMC_BEN0_IN - vin3b_de1 M4 gpmc_ben1 0 0 0 0 CFG_GPMC_BEN1_IN vin3b_clk1 vin3b_fld1 H6 gpmc_cs1 1280 1058 1620 664 CFG_GPMC_CS1_IN - vin3b_vsync1 224 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Manual IO Timings Modes must be used to guarantee some IO timings for VIP3. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-14 Manual Functions Mapping for VIP3 for a definition of the Manual modes. Table 7-14 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-14. Manual Functions Mapping for VIP3 BAL L BALL NAME AC5 AB4 VIP3_MANUAL1 A_DELAY (ps) G_DELAY (ps) gpio6_10 774 gpio6_11 2453 C14 mcasp1_aclkx G12 VIP3_MANUAL2 A_DELAY (ps) G_DELAY (ps) 2462 765 2551 3000 2863 2719 1400 154 1698 mcasp1_axr0 2055 612 F12 mcasp1_axr1 1623 B13 mcasp1_axr10 A12 mcasp1_axr11 E14 CFG REGISTER MUXMODE 7 9 CFG_GPIO6_10_IN - vin5a_clk0 CFG_GPIO6_11_IN - vin5a_de0 0 CFG_MCASP1_ACLKX_IN vin6a_fld0 - 2459 381 CFG_MCASP1_AXR0_IN vin6a_vsyn c0 - 338 2098 0 CFG_MCASP1_AXR1_IN vin6a_hsyn c0 - 1625 92 1681 0 CFG_MCASP1_AXR10_IN vin6a_d13 - 1509 714 2048 317 CFG_MCASP1_AXR11_IN vin6a_d12 - mcasp1_axr12 1189 619 1729 222 CFG_MCASP1_AXR12_IN vin6a_d11 - A13 mcasp1_axr13 1546 265 1954 0 CFG_MCASP1_AXR13_IN vin6a_d10 - G14 mcasp1_axr14 1305 0 1448 0 CFG_MCASP1_AXR14_IN vin6a_d9 - F14 mcasp1_axr15 1342 313 1798 0 CFG_MCASP1_AXR15_IN vin6a_d8 - B12 mcasp1_axr8 1833 466 2264 0 CFG_MCASP1_AXR8_IN vin6a_d15 - A11 mcasp1_axr9 1555 777 2029 352 CFG_MCASP1_AXR9_IN vin6a_d14 - D14 mcasp1_fsx 1549 281 1972 0 CFG_MCASP1_FSX_IN vin6a_de0 - A19 mcasp2_aclkx 1063 0 1206 0 CFG_MCASP2_ACLKX_IN vin6a_d7 - C15 mcasp2_axr2 1134 0 1277 0 CFG_MCASP2_AXR2_IN vin6a_d5 - A16 mcasp2_axr3 1348 487 1888 90 CFG_MCASP2_AXR3_IN vin6a_d4 - A18 mcasp2_fsx 1030 250 1424 0 CFG_MCASP2_FSX_IN vin6a_d6 - B18 mcasp3_aclkx 0 0 0 0 CFG_MCASP3_ACLKX_IN vin6a_d3 - B19 mcasp3_axr0 888 485 1428 88 CFG_MCASP3_AXR0_IN vin6a_d1 - C17 mcasp3_axr1 861 582 1331 254 CFG_MCASP3_AXR1_IN vin6a_d0 vin5a_fld0 F15 mcasp3_fsx 1093 451 1633 54 CFG_MCASP3_FSX_IN vin6a_d2 - C18 mcasp4_aclkx 557 0 541 0 CFG_MCASP4_ACLKX_IN - vin5a_d15 G16 mcasp4_axr0 1027 989 1441 644 CFG_MCASP4_AXR0_IN - vin5a_d13 D17 mcasp4_axr1 1140 1038 1601 740 CFG_MCASP4_AXR1_IN - vin5a_d12 A21 mcasp4_fsx 1140 885 700 1377 CFG_MCASP4_FSX_IN - vin5a_d14 AA3 mcasp5_aclkx 1633 3030 1658 2999 CFG_MCASP5_ACLKX_IN - vin5a_d11 AB3 mcasp5_axr0 2392 3028 2816 2711 CFG_MCASP5_AXR0_IN - vin5a_d9 AA4 mcasp5_axr1 2435 3026 2856 2723 CFG_MCASP5_AXR1_IN - vin5a_d8 AB9 mcasp5_fsx 2285 2660 2713 2288 CFG_MCASP5_FSX_IN - vin5a_d10 AD4 mmc3_clk 2501 2822 2915 2475 CFG_MMC3_CLK_IN - vin5a_d7 AC4 mmc3_cmd 2423 2826 2832 2485 CFG_MMC3_CMD_IN - vin5a_d6 AC7 mmc3_dat0 2336 2820 2743 2526 CFG_MMC3_DAT0_IN - vin5a_d5 AC6 mmc3_dat1 2332 2710 2749 2346 CFG_MMC3_DAT1_IN - vin5a_d4 AC9 mmc3_dat2 1732 3048 1811 3012 CFG_MMC3_DAT2_IN - vin5a_d3 AC3 mmc3_dat3 2459 2969 2872 2683 CFG_MMC3_DAT3_IN - vin5a_d2 AC8 mmc3_dat4 2436 2662 2836 2271 CFG_MMC3_DAT4_IN - vin5a_d1 AD6 mmc3_dat5 2450 2431 1771 3271 CFG_MMC3_DAT5_IN - vin5a_d0 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 225 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-14. Manual Functions Mapping for VIP3 (continued) BAL L BALL NAME AB8 VIP3_MANUAL1 VIP3_MANUAL2 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) mmc3_dat6 2332 2640 2752 2255 AB5 mmc3_dat7 1799 2927 1881 D18 xref_clk0 681 0 E17 xref_clk1 21 0 7.7 CFG REGISTER MUXMODE 7 9 CFG_MMC3_DAT6_IN - vin5a_hsyn c0 2844 CFG_MMC3_DAT7_IN - vin5a_vsyn c0 824 0 CFG_XREF_CLK0_IN vin6a_d0 - 0 0 CFG_XREF_CLK1_IN vin6a_clk0 - Display Subsystem – Video Output Ports Three Display Parallel Interfaces (DPI) channels are available in DSS named DPI Video Output 1, DPI Video Output 2 and DPI Video Output 3. NOTE The DPI Video Output i (i = 1 to 3) interface is also referred to as VOUTi. Every VOUT interface consists of: • 24-bit data bus (data[23:0]) • Horizontal synchronization signal (HSYNC) • Vertical synchronization signal (VSYNC) • Data enable (DE) • Field ID (FID) • Pixel clock (CLK) NOTE For more information, see the Display Subsystem chapter of the Device TRM. CAUTION The IO timings provided in this section are only valid if signals within a single IOSET are used. The IOSETs are defined in the Table 7-17 and Table 7-18. CAUTION The IO Timings provided in this section are only valid for some DSS usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. CAUTION All pads/balls configured as vouti_* signals are recommended to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1). FAST slew setting is allowed, but results in faster edge rates on the VOUTn bus, higher power/ground noise, and higher EMI emissions compared to SLOW slew rate. 226 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-15, Table 7-16 and Figure 7-6 assume testing over the recommended operating conditions and electrical characteristic conditions. Table 7-15. DPI Video Output i (i = 1..3) Default Switching Characteristics NO. PARAMETER DESCRIPTION D1 tc(clk) Cycle time, output pixel clock vouti_clk D2 tw(clkL) Pulse duration, output pixel clock vouti_clk low D3 D5 tw(clkH) Pulse duration, output pixel clock vouti_clk high td(clk-dV) Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid MODE MIN MAX ns DPI1, DPI2 (IOSET1), DPI3 (1) P*0.5-1 ns DPI2 (IOSET2) (1) P*0.51.35 ns DPI1, DPI2 (IOSET1), DPI3 (1) P*0.5-1 ns DPI2 (IOSET2) P*0.51.35 (1) ns DPI1 -2.5 2.6 DPI2 (IOSET1) td(clk-ctlV) Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid ns ns DPI2 (IOSET2) D6 UNIT 11.76 ns DPI3 (IOSET1) -2.5 2.5 ns DPI3 (IOSET2/3) DPI1 -2.5 3 ns -2.5 2.6 ns DPI2 (IOSET1) ns DPI2 (IOSET2) ns DPI3 (IOSET1) -2.5 2.5 ns DPI3 (IOSET2/3) -2.5 3 ns (1) P = output vouti_clk period in ns. (2) All pads/balls configured as vouti_* signals are recommended to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1). FAST slew setting is allowed, but results in faster edge rates on the VOUTn bus, higher power/ground noise, and higher EMI emissions compared to SLOW slew rate. Table 7-16. DPI Video Output i (i = 1..3) Alternate Switching Characteristics NO. PARAMETER DESCRIPTION D1 tc(clk) Cycle time, output pixel clock vouti_clk D2 tw(clkL) D3 D5 MODE MIN MAX ns Pulse duration, output pixel clock vouti_clk low P*0.5-1 (1) ns tw(clkH) Pulse duration, output pixel clock vouti_clk high P*0.5-1 (1) ns td(clk-dV) Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid DPI1 1.51 4.55 td(clk-ctlV) Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid ns DPI2 (IOSET2) ns DPI1 ns 1.51 4.55 ns DPI2 (IOSET1) ns DPI2 (IOSET2) ns DPI3 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated ns DPI2 (IOSET1) DPI3 D6 UNIT 6.06 227 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output vouti_clk period in ns. (2) All pads/balls configured as vouti_* signals are recommended to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1). FAST slew setting is allowed, but results in faster edge rates on the VOUTn bus, higher power/ground noise, and higher EMI emissions compared to SLOW slew rate. D2 D1 D3 D4 Falling-edge Clock Reference vouti_clk D6 Rising-edge Clock Reference vouti_clk vouti_vsync D6 vouti_hsync D5 vouti_d[23:0] data_1 data_2 data_n D6 vouti_de D6 vouti_fld even odd SWPS049-018 (1) (2)(3) Figure 7-6. DPI Video Output (1) The configuration of assertion of the data can be programmed on the falling or rising edge of the pixel clock. (2) The polarity and the pulse width of vouti_hsync and vouti_vsync are programmable, refer to the DSS section of the device TRM. (3) The vouti_clk frequency can be configured, refer to the DSS section of the device TRM. NOTE To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register. The pad control registers are presented in Table 4-3 and described in Device TRM, Chapter 18 - Control Module. In Table 7-17 are presented the specific groupings of signals (IOSET) for use with VOUT2. Table 7-17. VOUT2 IOSETs SIGNALS IOSET2 MUX BALL MUX F2 4 AA4 6 vout2_d22 F3 4 AB3 6 vout2_d21 D1 4 AB9 6 vout2_d20 E2 4 AA3 6 vout2_d19 D2 4 D17 6 vout2_d18 F4 4 G16 6 vout2_d17 C1 4 A21 6 vout2_d16 E4 4 C18 6 vout2_d23 228 IOSET1 BALL Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-17. VOUT2 IOSETs (continued) SIGNALS IOSET1 IOSET2 BALL MUX BALL MUX vout2_d15 F5 4 A17 6 vout2_d14 E6 4 B17 6 vout2_d13 D3 4 B16 6 vout2_d12 F6 4 D15 6 vout2_d11 D5 4 A15 6 vout2_d10 C2 4 B15 6 vout2_d9 C3 4 A20 6 vout2_d8 C4 4 E15 6 vout2_d7 B2 4 D12 6 vout2_d6 D6 4 C12 6 vout2_d5 C5 4 F13 6 vout2_d4 A3 4 E12 6 vout2_d3 B3 4 J11 6 vout2_d2 B4 4 G13 6 vout2_d1 B5 4 J14 6 vout2_d0 A4 4 B14 6 vout2_vsync G6 4 F20 6 vout2_hsync G1 4 E21 6 vout2_clk H7 4 B26 6 vout2_fld E1 4 F21 6 vout2_de G2 4 C23 6 In Table 7-18 are presented the specific groupings of signals (IOSET) for use with VOUT3. Table 7-18. VOUT3 IOSETs SIGNALS IOSET2 (1) IOSET1 BALL MUX vout3_d23 P5 vout3_d22 R5 vout3_d21 IOSET3 (1) BALL MUX BALL MUX 3 AE8 4 3 AD8 4 R9 3 AG7 4 vout3_d20 P6 3 AH6 4 vout3_d19 T7 3 AH3 4 vout3_d18 T6 3 AH5 4 vout3_d17 T9 3 AG6 vout3_d16 R6 3 AH4 4 AD9 3 4 AG8 vout3_d15 H3 3 3 AG4 4 AG4 vout3_d14 H2 4 3 AG2 4 AG2 4 vout3_d13 vout3_d12 J3 3 AG3 4 AG3 4 H1 3 AG5 4 AG5 vout3_d11 4 J2 3 AF2 4 AF2 4 vout3_d10 J1 3 AF6 4 AF6 4 vout3_d9 K2 3 AF3 4 AF3 4 vout3_d8 L1 3 AF4 4 AF4 4 vout3_d7 L2 3 AF1 4 AE8 3 vout3_d6 L3 3 AE3 4 AD8 3 vout3_d5 L4 3 AE5 4 AG7 3 vout3_d4 L6 3 AE1 4 AH6 3 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 229 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-18. VOUT3 IOSETs (continued) SIGNALS IOSET2 (1) IOSET1 IOSET3 (1) BALL MUX BALL MUX BALL MUX vout3_d3 M1 3 AE2 4 AH3 3 vout3_d2 L5 3 AE6 4 AH5 3 vout3_d1 M2 3 AD2 4 AG6 3 vout3_d0 M6 3 AD3 4 AH4 3 vout3_de N9 3 AD9 4 vout3_vsync R4 3 AF8 4 AF8 4 vout3_clk P1 3 AF9 4 AF9 4 vout3_hsync N7 3 AE9 4 AE9 4 vout3_fld P9 3 AG8 4 (1) The VOUT3 interface when multiplexed onto balls mapped to the VDDSHV6 supply rail is restricted to operating in 1.8V mode only (i.e., VDDSHV6 must be supplied with 1.8V). 3.3V mode is not supported. This must be considered in the pin mux programming and VDDSHVx supply connections. NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for VOUT1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-19 Manual Functions Mapping for DSS VOUT1 for a definition of the Manual modes. Table 7-19 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. 230 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-19. Manual Functions Mapping for DSS VOUT1 BALL BALL NAME VOUT1_MANUAL1 VOUT1_MANUAL2 VOUT1_MANUAL3 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 0 D11 vout1_clk 0 706 1126 751 1067 829 CFG_VOUT1_CLK_OUT vout1_clk vout1_d0 F11 vout1_d0 2313 0 395 0 391 0 CFG_VOUT1_D0_OUT G10 vout1_d1 2439 0 521 0 517 0 CFG_VOUT1_D1_OUT vout1_d1 D7 vout1_d10 2199 0 282 0 278 0 CFG_VOUT1_D10_OUT vout1_d10 D8 vout1_d11 2266 0 348 0 345 0 CFG_VOUT1_D11_OUT vout1_d11 A5 vout1_d12 3159 0 1240 0 1236 0 CFG_VOUT1_D12_OUT vout1_d12 C6 vout1_d13 2100 0 182 0 178 0 CFG_VOUT1_D13_OUT vout1_d13 C8 vout1_d14 2229 0 311 0 308 0 CFG_VOUT1_D14_OUT vout1_d14 C7 vout1_d15 2202 0 285 0 281 0 CFG_VOUT1_D15_OUT vout1_d15 B7 vout1_d16 2084 0 166 0 0 162 CFG_VOUT1_D16_OUT vout1_d16 B8 vout1_d17 2195 0 278 0 274 0 CFG_VOUT1_D17_OUT vout1_d17 A7 vout1_d18 2342 0 425 0 421 0 CFG_VOUT1_D18_OUT vout1_d18 A8 vout1_d19 2463 0 516 0 512 0 CFG_VOUT1_D19_OUT vout1_d19 F10 vout1_d2 2200 0 282 0 279 0 CFG_VOUT1_D2_OUT vout1_d2 C9 vout1_d20 2304 0 386 0 383 0 CFG_VOUT1_D20_OUT vout1_d20 A9 vout1_d21 2103 0 111 0 107 0 CFG_VOUT1_D21_OUT vout1_d21 B9 vout1_d22 2145 0 227 0 223 0 CFG_VOUT1_D22_OUT vout1_d22 A10 vout1_d23 1932 0 0 0 0 0 CFG_VOUT1_D23_OUT vout1_d23 G11 vout1_d3 2355 0 438 0 434 0 CFG_VOUT1_D3_OUT vout1_d3 E9 vout1_d4 3215 0 1298 0 1294 0 CFG_VOUT1_D4_OUT vout1_d4 F9 vout1_d5 2314 0 397 0 393 0 CFG_VOUT1_D5_OUT vout1_d5 F8 vout1_d6 2238 0 321 0 317 0 CFG_VOUT1_D6_OUT vout1_d6 E7 vout1_d7 2381 0 155 309 135 325 CFG_VOUT1_D7_OUT vout1_d7 E8 vout1_d8 2138 0 212 0 208 0 CFG_VOUT1_D8_OUT vout1_d8 D9 vout1_d9 2383 0 466 0 462 0 CFG_VOUT1_D9_OUT vout1_d9 B10 vout1_de 1984 0 0 0 0 0 CFG_VOUT1_DE_OUT vout1_de B11 vout1_fld 2265 0 236 0 215 0 CFG_VOUT1_FLD_OUT vout1_fld C11 vout1_hsync 1947 0 0 0 0 0 CFG_VOUT1_HSYNC_OUT vout1_hsync E11 vout1_vsync 2739 0 139 701 118 701 CFG_VOUT1_VSYNC_OUT vout1_vsync Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 231 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Manual IO Timings Modes must be used to guarantee some IO timings for VOUT2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-20 Manual Functions Mapping for DSS VOUT2 for a definition of the Manual modes. Table 7-20 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-20. Manual Functions Mapping for DSS VOUT2 BALL BALL NAME VOUT2_IOSET1_MANUAL1 VOUT2_IOSET1_MANUAL2 VOUT2_IOSET1_MANUAL3 CFG REGISTER MUXMODE E1 vin2a_clk0 2718 0 473 378 819 0 CFG_VIN2A_CLK0_OUT vout2_fld F2 vin2a_d0 2680 0 435 356 485 296 CFG_VIN2A_D0_OUT vout2_d23 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 4 F3 vin2a_d1 2633 0 744 0 733 0 CFG_VIN2A_D1_OUT vout2_d22 D3 vin2a_d10 1867 0 0 0 0 0 CFG_VIN2A_D10_OUT vout2_d13 F6 vin2a_d11 2457 0 401 167 431 127 CFG_VIN2A_D11_OUT vout2_d12 D5 vin2a_d12 2683 1016 1319 491 1286 514 CFG_VIN2A_D12_OUT vout2_d11 C2 vin2a_d13 2629 985 1263 463 1229 486 CFG_VIN2A_D13_OUT vout2_d10 C3 vin2a_d14 2531 804 1159 286 1126 309 CFG_VIN2A_D14_OUT vout2_d9 C4 vin2a_d15 2624 818 1260 292 1227 315 CFG_VIN2A_D15_OUT vout2_d8 B2 vin2a_d16 2747 767 1390 233 1357 256 CFG_VIN2A_D16_OUT vout2_d7 D6 vin2a_d17 2622 841 1260 314 1226 337 CFG_VIN2A_D17_OUT vout2_d6 C5 vin2a_d18 2328 0 375 65 430 0 CFG_VIN2A_D18_OUT vout2_d5 A3 vin2a_d19 2300 0 411 0 401 0 CFG_VIN2A_D19_OUT vout2_d4 D1 vin2a_d2 2452 0 397 165 446 106 CFG_VIN2A_D2_OUT vout2_d21 B3 vin2a_d20 1998 0 109 0 98 0 CFG_VIN2A_D20_OUT vout2_d3 B4 vin2a_d21 1953 0 64 0 54 0 CFG_VIN2A_D21_OUT vout2_d2 B5 vin2a_d22 1893 0 0 0 0 0 CFG_VIN2A_D22_OUT vout2_d1 A4 vin2a_d23 1936 0 47 0 36 0 CFG_VIN2A_D23_OUT vout2_d0 E2 vin2a_d3 2494 0 605 0 595 0 CFG_VIN2A_D3_OUT vout2_d20 D2 vin2a_d4 3001 153 1265 0 1254 0 CFG_VIN2A_D4_OUT vout2_d19 F4 vin2a_d5 2463 0 476 97 563 0 CFG_VIN2A_D5_OUT vout2_d18 C1 vin2a_d6 2456 0 568 0 558 0 CFG_VIN2A_D6_OUT vout2_d17 E4 vin2a_d7 2431 0 542 0 532 0 CFG_VIN2A_D7_OUT vout2_d16 F5 vin2a_d8 2262 0 373 0 363 0 CFG_VIN2A_D8_OUT vout2_d15 E6 vin2a_d9 2145 0 256 0 246 0 CFG_VIN2A_D9_OUT vout2_d14 G2 vin2a_de0 2597 0 500 208 550 149 CFG_VIN2A_DE0_OUT vout2_de H7 vin2a_fld0 0 957 1225 948 1208 969 CFG_VIN2A_FLD0_OUT vout2_clk G1 vin2a_hsync0 2958 0 1091 0 1059 0 CFG_VIN2A_HSYNC0_OUT vout2_hsync 232 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-20. Manual Functions Mapping for DSS VOUT2 (continued) BALL BALL NAME G6 vin2a_vsync0 VOUT2_IOSET1_MANUAL1 VOUT2_IOSET1_MANUAL2 VOUT2_IOSET1_MANUAL3 CFG REGISTER MUXMODE CFG_VIN2A_VSYNC0_OUT vout2_vsync A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 2752 0 391 495 853 4 0 Manual IO Timings Modes must be used to guarantee some IO timings for VOUT2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-21 Manual Functions Mapping for DSS VOUT2 IOSET2 for a definition of the Manual modes. Table 7-21 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-21. Manual Functions Mapping for DSS VOUT2 IOSET2 BAL L BALL NAME VOUT2_IOSET2_MANUAL1 VOUT2_IOSET2_MANUAL2 VOUT2_IOSET2_MANUAL3 CFG REGISTER E21 gpio6_14 854 0 0 0 0 0 CFG_GPIO6_14_OUT vout2_hsync F20 gpio6_15 1062 0 214 0 209 0 CFG_GPIO6_15_OUT vout2_vsync F21 gpio6_16 907 0 39 0 33 0 CFG_GPIO6_16_OUT vout2_fld B14 mcasp1_aclkr 3500 0 2641 0 2636 0 CFG_MCASP1_ACLKR_OUT vout2_d0 G13 mcasp1_axr2 2579 0 1713 0 1730 0 CFG_MCASP1_AXR2_OUT vout2_d2 J11 mcasp1_axr3 2346 0 1481 0 1498 0 CFG_MCASP1_AXR3_OUT vout2_d3 E12 mcasp1_axr4 2727 0 1862 0 1879 0 CFG_MCASP1_AXR4_OUT vout2_d4 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) MUXMODE 6 F13 mcasp1_axr5 2650 0 1785 0 1802 0 CFG_MCASP1_AXR5_OUT vout2_d5 C12 mcasp1_axr6 2641 0 1776 0 1792 0 CFG_MCASP1_AXR6_OUT vout2_d6 D12 mcasp1_axr7 2566 0 1701 0 1717 0 CFG_MCASP1_AXR7_OUT vout2_d7 vout2_d1 J14 mcasp1_fsr 2315 0 1450 0 1466 0 CFG_MCASP1_FSR_OUT E15 mcasp2_aclkr 3336 0 2471 0 2488 0 CFG_MCASP2_ACLKR_OUT vout2_d8 B15 mcasp2_axr0 1870 0 1005 0 1022 0 CFG_MCASP2_AXR0_OUT vout2_d10 A15 mcasp2_axr1 2028 0 1163 0 1179 0 CFG_MCASP2_AXR1_OUT vout2_d11 D15 mcasp2_axr4 2223 0 1357 0 1374 0 CFG_MCASP2_AXR4_OUT vout2_d12 B16 mcasp2_axr5 2012 0 1148 0 1164 0 CFG_MCASP2_AXR5_OUT vout2_d13 B17 mcasp2_axr6 3176 0 2310 0 2339 0 CFG_MCASP2_AXR6_OUT vout2_d14 A17 mcasp2_axr7 1779 0 914 0 931 0 CFG_MCASP2_AXR7_OUT vout2_d15 A20 mcasp2_fsr 1564 0 698 0 715 0 CFG_MCASP2_FSR_OUT vout2_d9 C18 mcasp4_aclkx 2900 0 2034 0 2051 0 CFG_MCASP4_ACLKX_OUT vout2_d16 G16 mcasp4_axr0 1666 0 801 0 830 0 CFG_MCASP4_AXR0_OUT vout2_d18 D17 mcasp4_axr1 1341 0 0 476 505 0 CFG_MCASP4_AXR1_OUT vout2_d19 A21 mcasp4_fsx 1380 0 512 0 541 0 CFG_MCASP4_FSX_OUT vout2_d17 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 233 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-21. Manual Functions Mapping for DSS VOUT2 IOSET2 (continued) BAL L BALL NAME VOUT2_IOSET2_MANUAL1 VOUT2_IOSET2_MANUAL2 VOUT2_IOSET2_MANUAL3 CFG REGISTER MUXMODE AA3 mcasp5_aclkx 4184 2166 3497 1993 3499 1978 CFG_MCASP5_ACLKX_OUT vout2_d20 AB3 mcasp5_axr0 4189 1590 3503 1417 3505 1402 CFG_MCASP5_AXR0_OUT vout2_d22 AA4 mcasp5_axr1 4155 1213 3468 AB9 mcasp5_fsx 4131 1464 3441 1035 3457 1063 CFG_MCASP5_AXR1_OUT vout2_d23 1295 3443 1280 CFG_MCASP5_FSX_OUT B26 xref_clk2 0 873 vout2_d21 1900 1100 1900 1150 CFG_XREF_CLK2_OUT vout2_clk C23 xref_clk3 2588 0 1723 0 1752 0 CFG_XREF_CLK3_OUT vout2_de A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 6 Manual IO Timings Modes must be used to guarantee some IO timings for VOUT3. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-22 Manual Functions Mapping for DSS VOUT3 for a definition of the Manual modes. Table 7-22 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-22. Manual Functions Mapping for DSS VOUT3 BALL R6 BALL NAME VOUT3_MANUAL1 VOUT3_MANUAL2 VOUT3_MANUAL3 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) gpmc_a0 2284 0 831 0 565 267 CFG REGISTER MUXMODE 3 4 CFG_GPMC_A0_OUT vout3_d16 - T9 gpmc_a1 2102 0 649 0 650 0 CFG_GPMC_A1_OUT vout3_d17 - N9 gpmc_a10 2609 0 1156 0 1157 0 CFG_GPMC_A10_OUT vout3_de - P9 gpmc_a11 3054 35 559 1097 669 970 CFG_GPMC_A11_OUT vout3_fld - T6 gpmc_a2 2155 0 704 0 705 0 CFG_GPMC_A2_OUT vout3_d18 - T7 gpmc_a3 2973 0 1520 0 1521 0 CFG_GPMC_A3_OUT vout3_d19 - P6 gpmc_a4 3158 131 1836 0 1837 0 CFG_GPMC_A4_OUT vout3_d20 - R9 gpmc_a5 2191 0 739 0 739 0 CFG_GPMC_A5_OUT vout3_d21 - R5 gpmc_a6 2390 0 937 0 937 0 CFG_GPMC_A6_OUT vout3_d22 - P5 gpmc_a7 2396 0 943 0 944 0 CFG_GPMC_A7_OUT vout3_d23 - N7 gpmc_a8 3275 18 1859 0 1843 0 CFG_GPMC_A8_OUT vout3_hsync - R4 gpmc_a9 2448 0 1015 0 998 0 CFG_GPMC_A9_OUT vout3_vsync - M6 gpmc_ad0 2603 0 1150 0 1151 0 CFG_GPMC_AD0_OUT vout3_d0 - M2 gpmc_ad1 2407 0 955 0 956 0 CFG_GPMC_AD1_OUT vout3_d1 - J1 gpmc_ad10 2516 0 1063 0 1064 0 CFG_GPMC_AD10_OUT vout3_d10 - J2 gpmc_ad11 2262 0 810 0 809 0 CFG_GPMC_AD11_OUT vout3_d11 - H1 gpmc_ad12 2583 30 1160 0 1161 0 CFG_GPMC_AD12_OUT vout3_d12 - J3 gpmc_ad13 1976 0 523 0 524 0 CFG_GPMC_AD13_OUT vout3_d13 - 234 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-22. Manual Functions Mapping for DSS VOUT3 (continued) BALL BALL NAME VOUT3_MANUAL1 VOUT3_MANUAL2 VOUT3_MANUAL3 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 0 96 534 632 0 CFG REGISTER MUXMODE 3 4 CFG_GPMC_AD14_OUT vout3_d14 - H2 gpmc_ad14 2083 H3 gpmc_ad15 2465 0 1011 0 1012 0 CFG_GPMC_AD15_OUT vout3_d15 - L5 gpmc_ad2 2658 16 1221 0 1222 0 CFG_GPMC_AD2_OUT vout3_d2 - M1 gpmc_ad3 2328 0 224 650 875 0 CFG_GPMC_AD3_OUT vout3_d3 - L6 gpmc_ad4 2622 0 1169 0 1170 0 CFG_GPMC_AD4_OUT vout3_d4 - L4 gpmc_ad5 1837 0 290 0 358 0 CFG_GPMC_AD5_OUT vout3_d5 - L3 gpmc_ad6 2613 22 1183 0 1184 0 CFG_GPMC_AD6_OUT vout3_d6 - L2 gpmc_ad7 2359 0 907 0 908 0 CFG_GPMC_AD7_OUT vout3_d7 - L1 gpmc_ad8 1242 0 0 0 0 0 CFG_GPMC_AD8_OUT vout3_d8 - K2 gpmc_ad9 1312 0 0 0 0 0 CFG_GPMC_AD9_OUT vout3_d9 - P1 gpmc_cs3 0 1214 1472 1390 1505 1379 CFG_GPMC_CS3_OUT vout3_clk - AG8 vin1a_clk0 2730 0 1296 0 1280 0 CFG_VIN1A_CLK0_OUT vout3_d16 vout3_fld AE8 vin1a_d0 2738 0 1141 144 1286 0 CFG_VIN1A_D0_OUT vout3_d7 vout3_d23 AD8 vin1a_d1 2734 0 1281 0 1282 0 CFG_VIN1A_D1_OUT vout3_d6 vout3_d22 AG3 vin1a_d10 3160 0 1182 516 1078 622 CFG_VIN1A_D10_OUT - vout3_d13 AG5 vin1a_d11 2800 0 1338 0 1339 0 CFG_VIN1A_D11_OUT - vout3_d12 AF2 vin1a_d12 3338 16 1893 0 1894 0 CFG_VIN1A_D12_OUT - vout3_d11 AF6 vin1a_d13 2748 0 1254 32 1287 0 CFG_VIN1A_D13_OUT - vout3_d10 AF3 vin1a_d14 3337 154 2029 0 2030 0 CFG_VIN1A_D14_OUT - vout3_d9 AF4 vin1a_d15 2688 0 1226 0 1138 89 CFG_VIN1A_D15_OUT - vout3_d8 AF1 vin1a_d16 2805 0 1344 0 1345 0 CFG_VIN1A_D16_OUT - vout3_d7 AE3 vin1a_d17 2793 0 1331 0 1332 0 CFG_VIN1A_D17_OUT - vout3_d6 AE5 vin1a_d18 2790 0 1328 0 1329 0 CFG_VIN1A_D18_OUT - vout3_d5 AE1 vin1a_d19 2862 0 1400 0 1221 180 CFG_VIN1A_D19_OUT - vout3_d4 AG7 vin1a_d2 2725 0 1272 0 1273 0 CFG_VIN1A_D2_OUT vout3_d5 vout3_d21 AE2 vin1a_d20 2985 0 1523 0 1524 0 CFG_VIN1A_D20_OUT - vout3_d3 AE6 vin1a_d21 2954 0 1492 0 1493 0 CFG_VIN1A_D21_OUT - vout3_d2 AD2 vin1a_d22 2891 0 1430 0 1431 0 CFG_VIN1A_D22_OUT - vout3_d1 AD3 vin1a_d23 3008 0 1546 0 1547 0 CFG_VIN1A_D23_OUT - vout3_d0 AH6 vin1a_d3 2782 26 1356 0 1357 0 CFG_VIN1A_D3_OUT vout3_d4 vout3_d20 AH3 vin1a_d4 3149 354 2033 17 2033 19 CFG_VIN1A_D4_OUT vout3_d3 vout3_d19 AH5 vin1a_d5 2490 0 1038 0 1039 0 CFG_VIN1A_D5_OUT vout3_d2 vout3_d18 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 235 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-22. Manual Functions Mapping for DSS VOUT3 (continued) BALL BALL NAME VOUT3_MANUAL1 VOUT3_MANUAL2 VOUT3_MANUAL3 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 3 4 AG6 vin1a_d6 2682 0 1229 0 1230 0 CFG_VIN1A_D6_OUT vout3_d1 vout3_d17 AH4 vin1a_d7 2687 0 1234 0 1235 0 CFG_VIN1A_D7_OUT vout3_d0 vout3_d16 AG4 vin1a_d8 2783 0 1321 0 1322 0 CFG_VIN1A_D8_OUT - vout3_d15 AG2 vin1a_d9 2833 0 1371 0 1116 256 CFG_VIN1A_D9_OUT - vout3_d14 AD9 vin1a_de0 2946 0 1494 0 1494 0 CFG_VIN1A_DE0_OUT vout3_d17 vout3_de AF9 vin1a_fld0 178 747 1813 752 1718 869 CFG_VIN1A_FLD0_OUT - vout3_clk AE9 vin1a_hsync0 2731 0 1288 0 1272 0 CFG_VIN1A_HSYNC0_OUT - vout3_hsync AF8 vin1a_vsync0 2543 0 1100 0 995 88 CFG_VIN1A_VSYNC0_OUT - vout3_vsync 236 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 7.8 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Display Subsystem – High-Definition Multimedia Interface (HDMI) The High-Definition Multimedia Interface is provided for transmitting digital television audiovisual signals from DVD players, set-top boxes and other audiovisual sources to television sets, projectors and other video displays. The HDMI interface is aligned with the HDMI TMDS single stream standard v1.4a (720p @60Hz to 1080p @24Hz) and the HDMI v1.3 (1080p @60Hz): 3 data channels, plus 1 clock channel is supported (differential). NOTE For more information, see the High-Definition Multimedia Interface chapter of the device TRM. 7.9 External Memory Interface (EMIF) The device has a dedicated interface to DDR3 and DDR2 SDRAM. It supports JEDEC standard compliant DDR2 and DDR3 SDRAM devices with the following features: • 16-bit or 32-bit data path to external SDRAM memory • Memory device capacity: 128Mb, 256Mb, 512Mb, 1Gb, 2Gb, 4Gb and 8Gb devices (Single die only) • One interface with associated DDR2/DDR3 PHYs NOTE For more information, see the EMIF Controller section of the Device TRM. 7.10 General-Purpose Memory Controller (GPMC) The GPMC is the unified memory controller that interfaces external memory devices such as: • Asynchronous SRAM-like memories and ASIC devices • Asynchronous page mode and synchronous burst NOR flash • NAND flash NOTE For more information, see the General-Purpose Memory Controller section of the Device TRM. 7.10.1 GPMC/NOR Flash Interface Synchronous Timing CAUTION The IO Timings provided in this section are only valid for some GPMC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-23 and Table 7-24 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-7, Figure 7-8, Figure 7-9, Figure 7-10, Figure 7-11, and Figure 7-12). Table 7-23. GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - 1 Load NO. PARAMETER DESCRIPTION MIN MAX UNIT F12 tsu(dV-clkH) Setup time, read gpmc_ad[15:0] valid before gpmc_clk high 2.69 ns F13 th(clkH-dV) Hold time, read gpmc_ad[15:0] valid after gpmc_clk high 1.53 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 237 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-23. GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - 1 Load (continued) NO. PARAMETER DESCRIPTION MIN MAX UNIT F21 tsu(waitV-clkH) Setup time, gpmc_wait[1:0] valid before gpmc_clk high 2.23 ns F22 th(clkH-waitV) Hold Time, gpmc_wait[1:0] valid after gpmc_clk high 1.52 ns NOTE Wait monitoring support is limited to a WaitMonitoringTime value > 0. For a full description of wait monitoring feature, see General-Purpose Memory Controller section in the Device TRM. Table 7-24. GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 1 Load NO. PARAMETER DESCRIPTION MIN MAX UNIT F0 tc(clk) Cycle time, output clock gpmc_clk period F2 td(clkH-nCSV) Delay time, gpmc_clk rising edge to gpmc_cs[7:0] transition F-1.48(6) 11.3 F+3.84(6) ns ns F3 td(clkH-nCSIV) Delay time, gpmc_clk rising edge to gpmc_cs[7:0] invalid E-1.48(5) E +3.84(5) ns F4 td(ADDV-clk) Delay time, gpmc_a[27:0] address bus valid to gpmc_clk first edge B-1.69(2) ns F5 td(clkH-ADDIV) Delay time, gpmc_clk rising edge to gpmc_a[27:0] gpmc address bus invalid F6 td(nBEV-clk) Delay time, gpmc_ben[1:0] valid to gpmc_clk rising edge B-3.8(2) B+2.37(2) ns F7 td(clkH-nBEIV) Delay time, gpmc_clk rising edge to gpmc_ben[1:0] invalid D-0.4(4) D+1.1(4) ns F8 td(clkH-nADV) Delay time, gpmc_clk rising edge to gpmc_advn_ale transition G-1.48 G+3.84 (7) (7) ns F9 td(clkH-nADVIV) Delay time, gpmc_clk rising edge to gpmc_advn_ale invalid D-1.48 G+3.84 (7) (4) ns F10 td(clkH-nOE) Delay time, gpmc_clk rising edge to gpmc_oen_ren transition H-1.41 H+2.45 (8) (8) ns F11 td(clkH-nOEIV) Delay time, gpmc_clk rising edge to gpmc_oen_ren invalid E-1.41 (5) E+2.1 (5) ns F14 td(clkH-nWE) Delay time, gpmc_clk rising edge to gpmc_wen transition I-1.18 (9) I+3.68 (9) ns F15 td(clkH-Data) Delay time, gpmc_clk rising edge to gpmc_ad[15:0] data bus transition J-1.89 (10) J+4.89 (10) ns F17 td(clkH-nBE) Delay time, gpmc_clk rising edge to gpmc_ben[1:0] transition J-1.3 (10) J+3.8 (10) ns F18 tw(nCSV) Pulse duration, gpmc_cs[7:0] low A (1) ns F19 tw(nBEV) Pulse duration, gpmc_ben[1:0] low C (3) ns F20 tw(nADVV) Pulse duration, gpmc_advn_ale low K (11) F23 td(CLK-GPIO) Delay time, gpmc_clk transition to gpio6_16.clkout1 transition B+3.76(2) -1.69 1.2 ns ns 6.1 ns Table 7-25. GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - 5 Loads NO. PARAMETER DESCRIPTION F12 tsu(dV-clkH) Setup time, read gpmc_ad[15:0] valid before gpmc_clk high F13 th(clkH-dV) F21 tsu(waitV-clkH) F22 th(clkH-waitV) MIN MAX UNIT 3.56 ns Hold time, read gpmc_ad[15:0] valid after gpmc_clk high 1.9 ns Setup time, gpmc_wait[1:0] valid before gpmc_clk high 3.1 ns Hold Time, gpmc_wait[1:0] valid after gpmc_clk high 1.9 ns Table 7-26. GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 5 Loads NO. PARAMETER DESCRIPTION F0 tc(clk) Cycle time, output clock gpmc_clk period (12) F2 td(clkH-nCSV) Delay time, gpmc_clk rising edge to gpmc_cs[7:0] transition 238 MIN MAX 15.04 F-0.84 (6) UNIT ns F+6.73 (6) ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-26. GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - 5 Loads (continued) NO. MIN MAX F3 td(clkH-nCSIV) PARAMETER Delay time, gpmc_clk rising edge to gpmc_cs[7:0] invalid DESCRIPTION E-0.84 (5) E+6.73 (5) ns F4 td(ADDV-clk) Delay time, gpmc_a[27:0] address bus valid to gpmc_clk first edge B-1.36 (2) B+6.73 (2) ns F5 td(clkH-ADDIV) Delay time, gpmc_clk rising edge to gpmc_a[27:0] gpmc address bus invalid F6 td(nBEV-clk) Delay time, gpmc_ben[1:0] valid to gpmc_clk rising edge F7 td(clkH-nBEIV) Delay time, gpmc_clk rising edge to gpmc_ben[1:0] invalid F8 td(clkH-nADV) F9 -1.36 UNIT ns B-6.34 (2) B+0.6 (2) ns D-0.4 (4) D+4.9 (4) ns Delay time, gpmc_clk rising edge to gpmc_advn_ale transition G-0.67 (7) G+6.1 (7) ns td(clkH-nADVIV) Delay time, gpmc_clk rising edge to gpmc_advn_ale invalid D-0.67 (4) D+6.1 (4) ns F10 td(clkH-nOE) Delay time, gpmc_clk rising edge to gpmc_oen_ren transition H-0.67 (8) H+5.65 (8) ns F11 td(clkH-nOEIV) Delay time, gpmc_clk rising edge to gpmc_oen_ren invalid E-0.67 (5) E+5.65 (5) ns F14 td(clkH-nWE) Delay time, gpmc_clk rising edge to gpmc_wen transition F15 td(clkH-Data) Delay time, gpmc_clk rising edge to gpmc_ad[15:0] data bus transition F17 td(clkH-nBE) Delay time, gpmc_clk rising edge to gpmc_ben[1:0] transition F18 tw(nCSV) Pulse duration, gpmc_cs[7:0] low F19 tw(nBEV) F20 tw(nADVV) F23 td(CLK-GPIO) Delay time, gpmc_clk transition to gpio6_16.clkout1 transition I-0.6 (9) I+6.1 (9) ns J-1.76 (10) J+6.39 (10) ns J-0.6 (10) J+6.34 (10) ns A (10) ns Pulse duration, gpmc_ben[1:0] low C (3) ns Pulse duration, gpmc_advn_ale low K (11) (13) 0.96 ns 6.1 ns (1) For single read: A = (CSRdOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK period For burst read: A = (CSRdOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK period For burst write: A = (CSWrOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK period with n the page burst access number. (2) B = ClkActivationTime * GPMC_FCLK (3) For single read: C = RdCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK For burst read: C = (RdCycleTime + (n – 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For Burst write: C = (WrCycleTime + (n – 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK with n the page burst access number. (4) For single read: D = (RdCycleTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst read: D = (RdCycleTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst write: D = (WrCycleTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK (5) For single read: E = (CSRdOffTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst read: E = (CSRdOffTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst write: E = (CSWrOffTime – AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK (6) For nCS falling edge (CS activated): Case GpmcFCLKDivider = 0 : F = 0.5 * CSExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: F = 0.5 * CSExtraDelay * GPMC_FCLK if (ClkActivationTime and CSOnTime are odd) or (ClkActivationTime and CSOnTime are even) F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: F = 0.5 * CSExtraDelay * GPMC_FCLK if ((CSOnTime – ClkActivationTime) is a multiple of 3) F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime – ClkActivationTime – 1) is a multiple of 3) F = (2 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: F = 0.5 * CSExtraDelay * GPMC_FCLK if ((CSOnTime - ClkActivationTime) is a multiple of 4) F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 1) is a multiple of 4) F = (2 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 2) is a multiple of 4) F = (3 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 3) is a multiple of 4) (7) For ADV falling edge (ADV activated): Case GpmcFCLKDivider = 0 : G = 0.5 * ADVExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVOnTime are odd) or (ClkActivationTime and ADVOnTime are even) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 239 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Case GpmcFCLKDivider = 2: G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVOnTime – ClkActivationTime) is a multiple of 3) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVOnTime – ClkActivationTime – 1) is a multiple of 3) G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVOnTime – ClkActivationTime – 2) is a multiple of 3) For ADV rising edge (ADV deactivated) in Reading mode: Case GpmcFCLKDivider = 0: G = 0.5 * ADVExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVRdOffTime are odd) or (ClkActivationTime and ADVRdOffTime are even) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime) is a multiple of 3) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime – 1) is a multiple of 3) G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime) is a multiple of 4) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime – 1) is a multiple of 4) G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime – 2) is a multiple of 4) G = (3 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime – ClkActivationTime – 3) is a multiple of 4) For ADV rising edge (ADV deactivated) in Writing mode: Case GpmcFCLKDivider = 0: G = 0.5 * ADVExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVWrOffTime are odd) or (ClkActivationTime and ADVWrOffTime are even) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime) is a multiple of 3) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime – 1) is a multiple of 3) G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime) is a multiple of 4) G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime – 1) is a multiple of 4) G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime – 2) is a multiple of 4) G = (3 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime – ClkActivationTime – 3) is a multiple of 4) (8) For OE falling edge (OE activated): Case GpmcFCLKDivider = 0: - H = 0.5 * OEExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: - H = 0.5 * OEExtraDelay * GPMC_FCLK if (ClkActivationTime and OEOnTime are odd) or (ClkActivationTime and OEOnTime are even) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: - H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOnTime – ClkActivationTime) is a multiple of 3) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime – ClkActivationTime – 1) is a multiple of 3) - H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: - H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOnTime - ClkActivationTime) is a multiple of 4) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 1) is a multiple of 4) - H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 2) is a multiple of 4) - H = (3 + 0.5 * OEExtraDelay)) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 3) is a multiple of 4) For OE rising edge (OE deactivated): Case GpmcFCLKDivider = 0: - H = 0.5 * OEExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: - H = 0.5 * OEExtraDelay * GPMC_FCLK if (ClkActivationTime and OEOffTime are odd) or (ClkActivationTime and OEOffTime are even) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: - H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOffTime – ClkActivationTime) is a multiple of 3) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime – ClkActivationTime – 1) is a multiple of 3) - H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: - H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOffTime – ClkActivationTime) is a multiple of 4) - H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime – ClkActivationTime – 1) is a multiple of 4) - H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime – ClkActivationTime – 2) is a multiple of 4) - H = (3 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime – ClkActivationTime – 3) is a multiple of 4) (9) For WE falling edge (WE activated): Case GpmcFCLKDivider = 0: - I = 0.5 * WEExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: - I = 0.5 * WEExtraDelay * GPMC_FCLK if (ClkActivationTime and WEOnTime are odd) or (ClkActivationTime and WEOnTime are even) 240 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: - I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOnTime – ClkActivationTime) is a multiple of 3) - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime – ClkActivationTime – 1) is a multiple of 3) - I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: - I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOnTime - ClkActivationTime) is a multiple of 4) - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 1) is a multiple of 4) - I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 2) is a multiple of 4) - I = (3 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 3) is a multiple of 4) For WE rising edge (WE deactivated): Case GpmcFCLKDivider = 0: - I = 0.5 * WEExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1: - I = 0.5 * WEExtraDelay * GPMC_FCLK if (ClkActivationTime and WEOffTime are odd) or (ClkActivationTime and WEOffTime are even) - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK otherwise Case GpmcFCLKDivider = 2: - I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOffTime – ClkActivationTime) is a multiple of 3) - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime – ClkActivationTime – 1) is a multiple of 3) - I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime – ClkActivationTime – 2) is a multiple of 3) Case GpmcFCLKDivider = 3: - I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOffTime - ClkActivationTime) is a multiple of 4) - I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 1) is a multiple of 4) - I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 2) is a multiple of 4) - I = (3 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 3) is a multiple of 4) (10) J = GPMC_FCLK period, where GPMC_FCLK is the General Purpose Memory Controller internal functional clock (11) For read: K = (ADVRdOffTime – ADVOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK For write: K = (ADVWrOffTime – ADVOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK (12) The gpmc_clk output clock maximum and minimum frequency is programmable in the I/F module by setting the GPMC_CONFIG1_CSx configuration register bit fields GpmcFCLKDivider (13) gpio6_16 programmed to MUXMODE=9 (clkout1), CM_CLKSEL_CLKOUTMUX1 programmed to 7 (CORE_DPLL_OUT_DCLK), CM_CLKSEL_CORE_DPLL_OUT_CLK_CLKOUTMUX programmed to 1. (14) CSEXTRADELAY = 0, ADVEXTRADELAY = 0, WEEXTRADELAY = 0, OEEXTRADELAY = 0. Extra half-GPMC_FCLK cycle delay mode is not timed. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 241 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com F1 F0 F1 gpmc_clk F2 F3 F18 gpmc_csi F4 Address (MSB) gpmc_a[10:1] gpmc_a[27] F6 F7 F19 gpmc_ben1 F6 F7 F19 gpmc_ben0 F8 F8 F20 F9 gpmc_advn_ale F10 F11 gpmc_oen_ren F13 F4 gpmc_ad[15:0] F5 F12 Address (LSB) D0 F22 F21 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_01 Figure 7-7. GPMC / Multiplexed 16bits NOR Flash - Synchronous Single Read (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i = 0 to 7. (2) In gpmc_waitj, j = 0 to 1. 242 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 F1 F0 F1 gpmc_clk F2 F3 F18 gpmc_csi F4 gpmc_a[27:1] Address F6 F7 F19 gpmc_ben1 F6 F7 F19 gpmc_ben0 F8 F8 F9 F20 gpmc_advn_ale F10 F11 gpmc_oen_ren F13 F12 D0 gpmc_ad[15:0] F22 F21 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_02 Figure 7-8. GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Single Read (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i = 0 to 7. (2) In gpmc_waitj, j = 0 to 1. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 243 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com F1 F1 F0 gpmc_clk F2 F3 F18 gpmc_csi F4 gpmc_a[10:1] gpmc_a[27] Address (MSB) F7 F6 F19 Valid gpmc_ben1 F7 F6 F19 Valid gpmc_ben0 F8 F8 F9 F20 gpmc_advn_ale F10 F11 gpmc_oen_ren F12 F4 gpmc_ad[15:0] F5 F13 D0 Address (LSB) F22 D1 F12 D2 D3 F21 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_03 Figure 7-9. GPMC / Multiplexed 16bits NOR Flash - Synchronous Burst Read 4x16 bits (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i= 0 to 7. (2) In gpmc_waitj, j = 0 to 1. 244 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 F1 F1 F0 gpmc_clk F2 F3 F18 gpmc_csi F4 gpmc_a[27:1] Address F7 F6 F19 Valid gpmc_ben1 F7 F6 F19 Valid gpmc_ben0 F8 F8 F20 F9 gpmc_advn_ale F10 F11 gpmc_oen_ren F12 F13 gpmc_ad[15:0] D0 D1 F12 D2 D3 F21 F22 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_04 Figure 7-10. GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Burst Read 4x16 bits (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i = 0 to 7. (2) In gpmc_waitj, j = 0 to 1. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 245 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com F1 F1 F0 gpmc_clk F2 F3 F18 gpmc_csi F4 gpmc_a[10:1] gpmc_a[27] Address (MSB) F17 F6 F17 F6 F17 F17 gpmc_ben1 F17 F17 gpmc_ben0 F8 F8 F20 F9 gpmc_advn_ale F14 F14 gpmc_wen F15 gpmc_ad[15:0] Address (LSB) D0 F22 D1 F15 D2 F15 D3 F21 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_05 Figure 7-11. GPMC / Multiplexed 16bits NOR Flash - Synchronous Burst Write 4x16bits (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i = 0 to 7. (2) In gpmc_waitj, j = 0 to 1. 246 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 F1 F1 F0 gpmc_clk F2 F3 F18 gpmc_csi F4 Address gpmc_a[27:1] F17 F6 F17 F17 gpmc_ben1 F17 F6 F17 F17 gpmc_ben0 F8 F8 F20 F9 gpmc_advn_ale F14 F14 gpmc_wen F15 gpmc_ad[15:0] D0 D1 F15 F15 D2 D3 F21 F22 gpmc_waitj F23 F23 gpio6_16.clkout1 GPMC_06 Figure 7-12. GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Burst Write 4x16bits (GpmcFCLKDivider = 0)(1)(2) (1) In gpmc_csi, i = 1 to 7. (2) In gpmc_waitj, j = 0 to 1. 7.10.2 GPMC/NOR Flash Interface Asynchronous Timing CAUTION The IO Timings provided in this section are only valid for some GPMC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-27 and Table 7-28 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-13, Figure 7-14, Figure 7-15, Figure 7-16, Figure 7-17, and Figure 7-18). Table 7-27. GPMC/NOR Flash Interface Timing Requirements - Asynchronous Mode NO. FA5 PARAMETER tacc(DAT) DESCRIPTION Data Maximum Access Time (GPMC_FCLK cycles) MIN MAX UNIT (1) cycles H Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 247 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-27. GPMC/NOR Flash Interface Timing Requirements - Asynchronous Mode (continued) NO. PARAMETER DESCRIPTION FA20 tacc1-pgmode(DAT) Page Mode Successive Data Maximum Access Time (GPMC_FCLK cycles) FA21 tacc2-pgmode(DAT) Page Mode First Data Maximum Access Time (GPMC_FCLK cycles) - tsu(DV-OEH) Setup time, read gpmc_ad[15:0] valid before gpmc_oen_ren high - th(OEH-DV) Hold time, read gpmc_ad[15:0] valid after gpmc_oen_ren high MIN MAX UNIT P (2) cycles H (1) cycles 1.9 ns 1 ns (1) H = Access Time * (TimeParaGranularity + 1) (2) P = PageBurstAccessTime * (TimeParaGranularity + 1) Table 7-28. GPMC/NOR Flash Interface Switching Characteristics - Asynchronous Mode NO. PARAMETER DESCRIPTION MIN MAX UNIT - tr(DO) Rising time, gpmc_ad[15:0] output data 0.447 4.067 ns - tf(DO) Fallling time, gpmc_ad[15:0] output data 0.43 4.463 ns FA0 tw(nBEV) Pulse duration, gpmc_ben[1:0] valid time N (1) ns FA1 tw(nCSV) Pulse duration, gpmc_cs[7:0] low A (2) ns FA3 td(nCSV-nADVIV) Delay time, gpmc_cs[7:0] valid to gpmc_advn_ale invalid B-2 (3) B+4 (3) ns FA4 td(nCSV-nOEIV) Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren invalid (Single read) C-2 (4) C+4 (4) ns FA9 td(AV-nCSV) Delay time, address bus valid to gpmc_cs[7:0] valid J-2 (5) J+4 (5) ns FA10 td(nBEV-nCSV) Delay time, gpmc_ben[1:0] valid to gpmc_cs[7:0] valid J-2 (5) J+4 (5) ns FA12 td(nCSV-nADVV) Delay time, gpmc_cs[7:0] valid to gpmc_advn_ale valid K-2 (6) K+4 (6) ns FA13 td(nCSV-nOEV) Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren valid L-2 (7) L+4 (7) ns FA16 tw(AIV) Pulse duration, address invalid between 2 successive R/W accesses G (8) FA18 td(nCSV-nOEIV) Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren invalid (Burst read) I-2 (9) I+4 (9) FA20 tw(AV) Pulse duration, address valid : 2nd, 3rd and 4th accesses FA25 td(nCSV-nWEV) ns ns D (10) Delay time, gpmc_cs[7:0] valid to gpmc_wen valid E-2 (11) E+4 (11) ns FA27 td(nCSV-nWEIV) Delay time, gpmc_cs[7:0] valid to gpmc_wen invalid F-2 (12) F+4 (12) ns FA28 td(nWEV-DV) Delay time, gpmc_ wen valid to data bus valid 2 ns FA29 td(DV-nCSV) Delay time, data bus valid to gpmc_cs[7:0] valid (5) ns FA37 td(nOEV-AIV) Delay time, gpmc_oen_ren valid to gpmc_ad[15:0] multiplexed address bus phase end 2 ns J-2 ns (5) J+4 (1) For single read: N = RdCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK For single write: N = WrCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK For burst read: N = (RdCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst write: N = (WrCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK (2) For single read: A = (CSRdOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK For single write: A = (CSWrOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst read: A = (CSRdOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK For burst write: A = (CSWrOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK (3) For reading: B = ((ADVRdOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK For writing: B = ((ADVWrOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK (4) C = ((OEOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK (5) J = (CSOnTime * (TimeParaGranularity + 1) + 0.5 * CSExtraDelay) * GPMC_FCLK (6) K = ((ADVOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK (7) L = ((OEOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK (8) G = Cycle2CycleDelay * GPMC_FCLK * (TimeParaGranularity +1) (9) I = ((OEOffTime + (n - 1) * PageBurstAccessTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK (10) D = PageBurstAccessTime * (TimeParaGranularity + 1) * GPMC_FCLK (11) E = ((WEOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - CSExtraDelay)) * GPMC_FCLK (12) F = ((WEOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - CSExtraDelay)) * GPMC_FCLK 248 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 GPMC_FCLK gpmc_clk FA5 FA1 gpmc_csi FA9 Valid Address gpmc_a[27:1] FA0 FA10 gpmc_ben0 Valid gpmc_ben1 Valid FA0 FA10 FA3 FA12 gpmc_advn_ale FA4 FA13 gpmc_oen_ren gpmc_ad[15:0] Data IN 0 Data IN 0 gpmc_waitj FA15 FA14 DIR OUT IN OUT GPMC_07 Figure 7-13. GPMC / NOR Flash - Asynchronous Read - Single Word Timing(1)(2)(3)(4) (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. (2) FA5 parameter illustrates amount of time required to internally sample input data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value must be stored inside AccessTime register bits field. (3) GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally. (4) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 249 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com GPMC_FCLK gpmc_clk FA5 FA5 FA1 FA1 gpmc_csi FA16 FA9 FA9 gpmc_a[27:1] Address 0 Address 1 FA0 FA0 FA10 FA10 gpmc_ben0 Valid FA0 FA0 gpmc_ben1 Valid Valid Valid FA10 FA10 FA3 FA3 FA12 FA12 gpmc_advn_ale FA4 FA4 FA13 FA13 gpmc_oen_ren gpmc_ad[15:0] Data Upper gpmc_waitj FA15 FA15 FA14 DIR OUT FA14 IN OUT IN GPMC_08 (1)(2)(3)(4) Figure 7-14. GPMC / NOR Flash - Asynchronous Read - 32-bit Timing (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. (2) FA5 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value should be stored inside AccessTime register bits field. (3) GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally. (4) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. 250 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 GPMC_FCLK gpmc_clk FA21 FA20 FA20 FA20 FA1 gpmc_csi FA9 Add0 gpmc_a[27:1] Add1 Add2 Add3 D0 D1 D2 Add4 FA0 FA10 gpmc_ben0 FA0 FA10 gpmc_ben1 FA12 gpmc_advn_ale FA18 FA13 gpmc_oen_ren gpmc_ad[15:0] D3 D3 gpmc_waitj FA15 FA14 DIR OUT IN OUT SPRS91v_GPMC_09 Figure 7-15. GPMC / NOR Flash - Asynchronous Read - Page Mode 4x16-bit Timing(1)(2)(3)(4)(5) (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. (2) FA21 parameter illustrates amount of time required to internally sample first input Page Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA21 functional clock cycles, First input Page Data will be internally sampled by active functional clock edge. FA21 calculation is detailled in a separated application note and should be stored inside AccessTime register bits field. (3) FA20 parameter illustrates amount of time required to internally sample successive input Page Data. It is expressed in number of GPMC functional clock cycles. After each access to input Page Data, next input Page Data will be internally sampled by active functional clock edge after FA20 functional clock cycles. FA20 is also the duration of address phases for successive input Page Data (excluding first input Page Data). FA20 value should be stored in PageBurstAccessTime register bits field. (4) GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally. (5) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 251 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com gpmc_fclk gpmc_clk FA1 gpmc_csi FA9 Valid Address gpmc_a[27:1] FA0 FA10 gpmc_ben0 FA0 FA10 gpmc_ben1 FA3 FA12 gpmc_advn_ale FA27 FA25 gpmc_wen FA29 Data OUT gpmc_ad[15:0] gpmc_waitj DIR OUT GPMC_10 Figure 7-16. GPMC / NOR Flash - Asynchronous Write - Single Word Timing(1)(2) (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. (2) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. 252 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 GPMC_FCLK gpmc_clk FA1 FA5 gpmc_csi FA9 gpmc_a27 gpmc_a[10:1] Address (MSB) FA0 FA10 gpmc_ben0 Valid FA0 FA10 Valid gpmc_ben1 FA3 FA12 gpmc_advn_ale FA4 FA13 gpmc_oen_ren FA29 gpmc_ad[15:0] FA37 Address (LSB) Data IN Data IN FA15 FA14 DIR OUT IN OUT gpmc_waitj GPMC_11 Figure 7-17. GPMC / Multiplexed NOR Flash - Asynchronous Read - Single Word Timing(1)(2)(3)(4) (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1 (2) FA5 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value should be stored inside AccessTime register bits field. (3) GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally (4) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 253 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com gpmc_fclk gpmc_clk FA1 gpmc_csi FA9 gpmc_a27 gpmc_a[10:1] Address (MSB) FA0 FA10 gpmc_ben0 FA0 FA10 gpmc_ben1 FA3 FA12 gpmc_advn_ale FA27 FA25 gpmc_wen FA29 FA28 Valid Address (LSB) gpmc_ad[15:0] Data OUT gpmc_waitj OUT DIR GPMC_12 Figure 7-18. GPMC / Multiplexed NOR Flash - Asynchronous Write - Single Word Timing(1)(2) (1) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. (2) The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus. 7.10.3 GPMC/NAND Flash Interface Asynchronous Timing CAUTION The IO Timings provided in this section are only valid for some GPMC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-29 and Table 7-30 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-19, Figure 7-20, Figure 7-21, and Figure 7-22). Table 7-29. GPMC/NAND Flash Interface Timing Requirements NO. GNF12 254 PARAMETER DESCRIPTION tacc(DAT) Data maximum access time (GPMC_FCLK Cycles) - tsu(DV-OEH) Setup time, read gpmc_ad[15:0] valid before gpmc_oen_ren high - th(OEH-DV) Hold time, read gpmc_ad[15:0] valid after gpmc_oen_ren high MIN MAX UNIT (1) cycles J 1.9 ns 1 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) J = AccessTime * (TimeParaGranularity + 1) Table 7-30. GPMC/NAND Flash Interface Switching Characteristics NO. MIN MAX UNIT - tr(DO) PARAMETER Rising time, gpmc_ad[15:0] output data DESCRIPTION 0.447 4.067 ns - 0.43 4.463 ns A (1) ns B+4 (2) ns ns tf(DO) Fallling time, gpmc_ad[15:0] output data GNF0 tw(nWEV) Pulse duration, gpmc_wen valid time GNF1 td(nCSV-nWEV) Delay time, gpmc_cs[7:0] valid to gpmc_wen valid B-2 (2) GNF2 td(CLEH-nWEV) Delay time, gpmc_ben[1:0] high to gpmc_wen valid C-2 (3) C+4 (3) GNF3 td(nWEV-DV) Delay time, gpmc_ad[15:0] valid to gpmc_wen valid D-2 (4) D+4 (4) ns GNF4 td(nWEIV-DIV) Delay time, gpmc_wen invalid to gpmc_ad[15:0] invalid E-2 (5) E+4 (5) ns GNF5 td(nWEIV-CLEIV) Delay time, gpmc_wen invalid to gpmc_ben[1:0] invalid F-2 (6) F+4 (6) ns ns GNF6 td(nWEIV-nCSIV) Delay time, gpmc_wen invalid to gpmc_cs[7:0] invalid G-2 (7) G+4 (7) GNF7 td(ALEH-nWEV) Delay time, gpmc_advn_ale high to gpmc_wen valid C-2 (3) C+4 (3) ns GNF8 td(nWEIV-ALEIV) Delay time, gpmc_wen invalid to gpmc_advn_ale invalid F-2 (6) F+4 (6) ns H (8) ns I+4 (9) ns K (10) ns L (11) ns M+4 (12) ns GNF9 tc(nWE) Cycle time, write cycle time GNF10 td(nCSV-nOEV) Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren valid GNF13 tw(nOEV) Pulse duration, gpmc_oen_ren valid time GNF14 tc(nOE) Cycle time, read cycle time GNF15 td(nOEIV-nCSIV) Delay time, gpmc_oen_ren invalid to gpmc_cs[7:0] invalid I-2 M-2 (9) (12) (1) A = (WEOffTime – WEOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK (2) B = ((WEOnTime – CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay – CSExtraDelay)) * GPMC_FCLK (3) C = ((WEOnTime – ADVOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay – ADVExtraDelay)) * GPMC_FCLK (4) D = (WEOnTime * (TimeParaGranularity + 1) + 0.5 * WEExtraDelay ) * GPMC_FCLK (5) E = (WrCycleTime – WEOffTime * (TimeParaGranularity + 1) – 0.5 * WEExtraDelay ) * GPMC_FCLK (6) F = (ADVWrOffTime – WEOffTime * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay – WEExtraDelay) * GPMC_FCLK (7) G = (CSWrOffTime – WEOffTime * (TimeParaGranularity + 1) + 0.5 * (CSExtraDelay – WEExtraDelay) * GPMC_FCLK (8) H = WrCycleTime * (1 + TimeParaGranularity) * GPMC_FCLK (9) I = ((OEOffTime + (n – 1) * PageBurstAccessTime – CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay – CSExtraDelay)) * GPMC_FCLK (10) K = (OEOffTime – OEOnTime) * (1 + TimeParaGranularity) * GPMC_FCLK (11) L = RdCycleTime * (1 + TimeParaGranularity) * GPMC_FCLK (12) M = (CSRdOffTime – OEOffTime * (TimeParaGranularity + 1) + 0.5 * (CSExtraDelay – OEExtraDelay) * GPMC_FCLK Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 255 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com GPMC_FCLK GNF1 GNF6 GNF2 GNF5 gpmc_csi gpmc_ben0 gpmc_advn_ale gpmc_oen_ren GNF0 gpmc_wen GNF3 GNF4 Command gpmc_ad[15:0] GPMC_13 (1) Figure 7-19. GPMC / NAND Flash - Command Latch Cycle Timing (1) In gpmc_csi, i = 0 to 7. GPMC_FCLK GNF1 GNF6 GNF7 GNF8 gpmc_csi gpmc_ben0 gpmc_advn_ale gpmc_oen_ren GNF9 GNF0 gpmc_wen GNF3 gpmc_ad[15:0] GNF4 Address GPMC_14 Figure 7-20. GPMC / NAND Flash - Address Latch Cycle Timing(1) (1) In gpmc_csi, i = 0 to 7. 256 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 GPMC_FCLK GNF12 GNF10 GNF15 gpmc_csi gpmc_ben0 gpmc_advn_ale GNF14 GNF13 gpmc_oen_ren gpmc_ad[15:0] DATA gpmc_waitj GPMC_15 Figure 7-21. GPMC / NAND Flash - Data Read Cycle Timing(1)(2)(3) (1) GNF12 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after GNF12 functional clock cycles, input data will be internally sampled by active functional clock edge. GNF12 value must be stored inside AccessTime register bits field. (2) GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally. (3) In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1. GPMC_FCLK GNF1 GNF6 gpmc_csi gpmc_ben0 gpmc_advn_ale gpmc_oen_ren GNF9 GNF0 gpmc_wen GNF3 GNF4 gpmc_ad[15:0] DATA GPMC_16 (1) Figure 7-22. GPMC / NAND Flash - Data Write Cycle Timing (1) In gpmc_csi, i = 0 to 7. NOTE To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register. The pad control registers are presented in Table 4-3 and described in Device TRM, Chapter 18 - Control Module. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 257 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Virtual IO Timings Modes must be used to guarantee some IO timings for GPMC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-31 Virtual Functions Mapping for GPMC for a definition of the Virtual modes. Table 7-31 presents the values for DELAYMODE bitfield. Table 7-31. Virtual Functions Mapping for GPMC BALL BALL NAME Delay Mode Value MUXMODE[15:0] GPMC_VIRTUAL1 0 M6 gpmc_ad0 11 gpmc_ad0 M2 gpmc_ad1 11 gpmc_ad1 L5 gpmc_ad2 11 gpmc_ad2 M1 gpmc_ad3 11 gpmc_ad3 L6 gpmc_ad4 11 gpmc_ad4 L4 gpmc_ad5 11 gpmc_ad5 L3 gpmc_ad6 11 gpmc_ad6 L2 gpmc_ad7 11 gpmc_ad7 L1 gpmc_ad8 11 gpmc_ad8 K2 gpmc_ad9 11 gpmc_ad9 J1 gpmc_ad10 11 gpmc_ad10 J2 gpmc_ad11 11 gpmc_ad11 H1 gpmc_ad12 11 gpmc_ad12 J3 gpmc_ad13 11 gpmc_ad13 H2 gpmc_ad14 11 gpmc_ad14 H3 gpmc_ad15 11 gpmc_ad15 R6 gpmc_a0 11 gpmc_a0 T9 gpmc_a1 11 gpmc_a1 T6 gpmc_a2 11 gpmc_a2 T7 gpmc_a3 10 gpmc_a3 P6 gpmc_a4 10 gpmc_a4 R9 gpmc_a5 11 gpmc_a5 R5 gpmc_a6 11 gpmc_a6 P5 gpmc_a7 11 gpmc_a7 N7 gpmc_a8 12 gpmc_a8 R4 gpmc_a9 12 gpmc_a9 N9 gpmc_a10 12 gpmc_a10 P9 gpmc_a11 11 gpmc_a11 P4 gpmc_a12 13 gpmc_a12 R3 gpmc_a13 12 gpmc_a13 T2 gpmc_a14 12 gpmc_a14 U2 gpmc_a15 12 gpmc_a15 U1 gpmc_a16 12 gpmc_a16 1 2 5 6 gpmc_a0 P3 gpmc_a17 12 gpmc_a17 R2 gpmc_a18 12 gpmc_a18 K7 gpmc_a19 11 gpmc_a19 gpmc_a13 M7 gpmc_a20 11 gpmc_a20 gpmc_a14 J5 gpmc_a21 11 gpmc_a21 gpmc_a15 K6 gpmc_a22 11 gpmc_a22 gpmc_a16 J7 gpmc_a23 11 gpmc_a23 gpmc_a17 J4 gpmc_a24 11 gpmc_a24 gpmc_a18 258 3 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-31. Virtual Functions Mapping for GPMC (continued) BALL BALL NAME Delay Mode Value MUXMODE[15:0] GPMC_VIRTUAL1 0 1 2 3 J6 gpmc_a25 11 gpmc_a25 gpmc_a19 H4 gpmc_a26 11 gpmc_a26 gpmc_a20 H5 gpmc_a27 11 gpmc_a27 gpmc_a21 H6 gpmc_cs1 11 gpmc_cs1 gpmc_a22 T1 gpmc_cs0 14 gpmc_cs0 P2 gpmc_cs2 12 gpmc_cs2 P1 gpmc_cs3 10 gpmc_cs3 P7 gpmc_clk 12 gpmc_clk gpmc_cs7 gpmc_wait1 N1 gpmc_advn_ ale 13 gpmc_advn_ ale gpmc_cs6 gpmc_wait1 M5 gpmc_oen_re n 14 gpmc_oen_re n M3 gpmc_wen 14 gpmc_wen 5 6 gpmc_a1 gpmc_a2 N6 gpmc_ben0 11 gpmc_ben0 gpmc_cs4 M4 gpmc_ben1 11 gpmc_ben1 gpmc_cs5 N2 gpmc_wait0 14 gpmc_wait0 AG5 vin1a_d11 9 gpmc_a23 AF2 vin1a_d12 9 gpmc_a24 AF6 vin1a_d13 9 gpmc_a25 AF3 vin1a_d14 9 gpmc_a26 AF4 vin1a_d15 9 gpmc_a27 gpmc_a23 gpmc_a3 7.11 Timers The device has 16 general-purpose (GP) timers (TIMER1 - TIMER16), two watchdog timers, and a 32-kHz synchronized timer (COUNTER_32K) that have the following features: • Dedicated input trigger for capture mode and dedicated output trigger/pulse width modulation (PWM) signal • Interrupts generated on overflow, compare, and capture • Free-running 32-bit upward counter • Supported modes: – Compare and capture modes – Auto-reload mode – Start-stop mode • On-the-fly read/write register (while counting) The device has two system watchdog timer (WD_TIMER1 and WD_TIMER2) that have the following features: • Free-running 32-bit upward counter • On-the-fly read/write register (while counting) • Reset upon occurrence of a timer overflow condition The device includes one instance of the 32-bit watchdog timer: WD_TIMER2, also called the MPU watchdog timer. The watchdog timer is used to provide a recovery mechanism for the device in the event of a fault condition, such as a non-exiting code loop. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 259 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com NOTE For additional information on the Timer Module, see the Device TRM. 7.12 Inter-Integrated Circuit Interface (I2C) The device includes 5 inter-integrated circuit (I2C) modules which provide an interface to other devices compliant with Philips Semiconductors Inter-IC bus (I2C-bus™) specification version 2.1. External components attached to this 2-wire serial bus can transmit/receive 8-bit data to/from the device through the I2C module. NOTE Note that, on I2C1 and I2C2, due to characteristics of the open drain IO cells, HS mode is not supported NOTE Inter-integrated circuit i ( i=1 to 5) module is also referred to as I2Ci NOTE For more information, see the Multimaster High-Speed I2C Controller section of the Device TRM. Table 7-32, Table 7-33 and Figure 7-23 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-32. Timing Requirements for I2C Input Timings(1) NO. PARAMETER DESCRIPTION STANDARD MODE MIN MAX FAST MODE MIN MAX UNIT 1 tc(SCL) Cycle time, SCL 10 2.5 µs 2 tsu(SCLH-SDAL) Setup time, SCL high before SDA low (for a repeated START condition) 4.7 0.6 µs 3 th(SDAL-SCLL) Hold time, SCL low after SDA low (for a START and a repeated START condition) 4 0.6 µs 4 tw(SCLL) Pulse duration, SCL low 4.7 1.3 µs 5 tw(SCLH) Pulse duration, SCL high 4 0.6 µs 6 tsu(SDAV-SCLH) Setup time, SDA valid before SCL high 250 100(2) 7 (3) ns (4) Hold time, SDA valid after SCL low 0 8 tw(SDAH) Pulse duration, SDA high between STOP and START conditions 4.7 9 tr(SDA) Rise time, SDA 1000 20 + 0.1Cb 300(3) ns 10 tr(SCL) Rise time, SCL 1000 20 + 0.1Cb 300(3) ns 11 tf(SDA) Fall time, SDA 300 20 + 0.1Cb 300(3) ns 12 tf(SCL) Fall time, SCL 300 20 + 0.1Cb 300(3) ns 13 tsu(SCLH-SDAH) Setup time, SCL high before SDA high (for STOP condition) 14 tw(SP) Pulse duration, spike (must be suppressed) 15 (5) 260 Capacitive load for each bus line 0 (3) th(SCLL-SDAV) Cb 3.45 (4) 0.9 1.3 4 (5) (5) (5) (5) µs 0.6 0 400 µs µs 50 ns 400 pF Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) The I2C pins SDA and SCL do not feature fail-safe I/O buffers. These pins could potentially draw current when the device is powered down. (2) A Fast-mode I2C-bus™ device can be used in a Standard-mode I2C-bus system, but the requirement tsu(SDA-SCLH)≥ 250 ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line tr max + tsu(SDA-SCLH)= 1000 + 250 = 1250 ns (according to the Standard-mode I2C-Bus Specification) before the SCL line is released. (3) A device must internally provide a hold time of at least 300 ns for the SDA signal (referred to the VIHmin of the SCL signal) to bridge the undefined region of the falling edge of SCL. (4) The maximum th(SDA-SCLL) has only to be met if the device does not stretch the low period [tw(SCLL)] of the SCL signal. (5) Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed. Table 7-33. Timing Requirements for I2C HS-Mode (I2C3/4/5 Only)(1) NO. PARAMETER DESCRIPTION 1 tc(SCL) Cycle time, SCL 2 tsu(SCLH-SDAL) 3 Cb = 400 pF (2) Cb = 100 pF MAX MIN MAX MIN UNIT MAX 0.294 0.588 us Set-up time, SCL high before SDA low (for a repeated START condition) 160 160 ns th(SDAL-SCLL) Hold time, SCL low after SDA low (for a repeated START condition) 160 160 ns 4 tw(SCLL) LOW period of the SCLH clock 160 320 ns 5 tw(SCLH) HIGH period of the SCLH clock 60 120 ns 6 tsu(SDAV-SCLH) Setup time, SDA valid vefore SCL high 10 10 ns 7 th(SCLL-SDAV) Hold time, SDA valid after SCL low 0 13 tsu(SCLH-SDAH) Setup time, SCL high before SDA high (for a STOP condition) 160 14 tw(SP) Pulse duration, spike (must be suppressed) 15 Cb (2) Capacitive load for SDAH and SCLH lines 16 Cb Capacitive load for SDAH + SDA line and SCLH + SCL line (3) 70 0 (3) 150 ns 160 0 10 ns 0 10 ns 100 400 pF 400 400 pF (1) I2C HS-Mode is only supported on I2C3/4/5. I2C HS-Mode is not supported on I2C1/2. (2) For bus line loads Cb between 100 and 400 pF the timing parameters must be linearly interpolated. (3) A device must internally provide a Data hold time to bridge the undefined part between VIH and VIL of the falling edge of the SCLH signal. An input circuit with a threshold as low as possible for the falling edge of the SCLH signal minimizes this hold time. 9 11 I2Ci_SDA 6 8 14 4 13 5 10 I2Ci_SCL 1 12 3 7 2 3 Stop Start Repeated Start Stop Figure 7-23. I2C Receive Timing Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 261 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-34 and Figure 7-24 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-34. Switching Characteristics Over Recommended Operating Conditions for I2C Output Timings(2) NO. 16 PARAMETER STANDARD MODE DESCRIPTION MIN FAST MODE MAX MIN MAX UNIT tc(SCL) Cycle time, SCL 10 2.5 µs 17 tsu(SCLH-SDAL) Setup time, SCL high before SDA low (for a repeated START condition) 4.7 0.6 µs 18 th(SDAL-SCLL) Hold time, SCL low after SDA low (for a START and a repeated START condition) 4 0.6 µs 19 tw(SCLL) Pulse duration, SCL low 4.7 1.3 µs 20 tw(SCLH) Pulse duration, SCL high 4 0.6 µs 21 tsu(SDAV-SCLH) Setup time, SDA valid before SCL high 250 100 ns 22 th(SCLL-SDAV) Hold time, SDA valid after SCL low (for I2C bus devices) 23 tw(SDAH) Pulse duration, SDA high between STOP and START conditions 24 tr(SDA) Rise time, SDA 1000 20 + 0.1Cb 300(3) ns 25 tr(SCL) Rise time, SCL 1000 20 + 0.1Cb 300(3) ns 26 tf(SDA) Fall time, SDA 300 20 + 0.1Cb 300(3) ns 27 tf(SCL) Fall time, SCL 300 20 + 0.1Cb 300(3) ns 28 tsu(SCLH-SDAH) Setup time, SCL high before SDA high (for STOP condition) 29 Cp Capacitance for each I2C pin 0 3.45 0 4.7 0.9 µs 1.3 (1) (3) (1) (3) (1) (3) (1) (3) 4 µs 0.6 µs 10 10 pF (1) Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed. (2) Software must properly configure the I2C module registers to achieve the timings shown in this table. See the Device TRM for details. (3) These timings apply only to I2C1 and I2C2. I2C3, I2C4, and I2C5 use standard LVCMOS buffers to emulate open-drain buffers and their rise/fall times should be referenced in the device IBIS model. NOTE I2C emulation is achieved by configuring the LVCMOS buffers to output Hi-Z instead of driving high when transmitting logic-1. 24 26 I2Ci_SDA 21 23 19 28 20 25 I2Ci_SCL 27 16 18 22 17 18 Stop Start Repeated Start Stop Figure 7-24. I2C Transmit Timing 262 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 7.13 HDQ / 1-Wire Interface (HDQ1W) The module is intended to work with both HDQ and 1-Wire protocols. The protocols use a single wire to communicate between the master and the slave. The protocols employ an asynchronous return to one mechanism where, after any command, the line is pulled high. NOTE For more information, see the HDQ / 1-Wire section of the Device TRM. 7.13.1 HDQ / 1-Wire — HDQ Mode Table 7-35 and Table 7-36 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-25, Figure 7-26, Figure 7-27 and Figure 7-28). Table 7-35. HDQ/1-Wire Timing Requirements—HDQ Mode NO. PARAMETER DESCRIPTION MIN MAX UNIT 1 tCYCH Read bit window timing 190 250 µs 2 tHW1 Read one data valid after HDQ low 32(2) 66(2) µs 3 tHW0 Read zero data hold after HDQ low 70(2) 145(2) µs 4 tRSPS Response time from HDQ slave device(1) 190 320 µs (1) Defined by software. (2) If the HDQ slave device drives a logic-low state after tHW0 maximum, it can be interpreted as a break pulse. For more information see "HDQ / 1-Wire Switching Characteristics - HDQ Mode" and the HDQ/1-Wire chapter of the TRM. Table 7-36. HDQ / 1-Wire Switching Characteristics - HDQ Mode NO. PARAMETER DESCRIPTION MIN MAX UNIT 5 tB Break timing 190 µs 6 tBR Break recovery time 40 µs 7 tCYCD Write bit windows timing 190 µs 8 tDW1 Write one data valid after HDQ low 0.5 50 µs 9 tDW0 Write zero data hold after HDQ low 86 145 µs tB tBR HDQ Figure 7-25. HDQ Break and Break Recovery Timing — HDQ Interface Writing to Slave tCYCH tHW0 tHW1 HDQ Figure 7-26. Device HDQ Interface Bit Read Timing (Data) tCYCD tDW0 tDW1 HDQ Figure 7-27. Device HDQ Interface Bit Write Timing (Command / Address or Data) Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 263 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Command_byte_written Data_byte_received tRSPS 0_(LSB) Break 1 6 1 7_(MSB) 0_(LSB) 6 HDQ Figure 7-28. HDQ Communication Timing 7.13.2 HDQ/1-Wire—1-Wire Mode Table 7-37 and Table 7-38 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-29, Figure 7-30 and Figure 7-31). Table 7-37. HDQ / 1-Wire Timing Requirements - 1-Wire Mode NO. MIN MAX UNIT 10 tPDH PARAMETER Presence pulse delay high DESCRIPTION 15 60 µs 11 tPDL Presence pulse delay low 60 240 µs 12 tRDV Read data valid time tLOWR 15 µs 13 tREL Read data release time 0 45 µs Table 7-38. HDQ / 1-Wire Switching Characteristics - 1-Wire Mode NO. MIN MAX UNIT 14 tRSTL PARAMETER Reset time low DESCRIPTION 480 960 µs 15 tRSTH Reset time high 480 16 tSLOT Bit cycle time 60 120 µs 17 tLOW1 Write bit-one time 1 15 µs 18 tLOW0 Write bit-zero time(2) 60 120 µs 19 tREC Recovery time 1 20 tLOWR Read bit strobe time(1) 1 µs µs 15 µs (1) tLOWR (low pulse sent by the master) must be short as possible to maximize the master sampling window. (2) tLOW0 must be less than tSLOT. tRSTH tRTSL tPDH tPDL 1-WIRE Figure 7-29. 1-Wire—Break (Reset) tSLOT_and_tREC tRDV_and_tREL tLOWR 1-WIRE Figure 7-30. 1-Wire—Read Bit (Data) 264 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 tSLOT_and_tREC tLOW0 tLOW1 1-WIRE Figure 7-31. 1-Wire—Write Bit-One Timing (Command / Address or Data) 7.14 Universal Asynchronous Receiver Transmitter (UART) The UART performs serial-to-parallel conversions on data received from a peripheral device and parallelto-serial conversion on data received from the CPU. There are 10 UART modules in the device. Only one UART supports IrDA features. Each UART can be used for configuration and data exchange with a number of external peripheral devices or interprocessor communication between devices The UARTi (where i = 1 to 10) include the following features: • 16C750 compatibility • 64-byte FIFO buffer for receiver and 64-byte FIFO for transmitter • Baud generation based on programmable divisors N (where N = 1…16 384) operating from a fixed functional clock of 48 MHz or 192 MHz • Break character detection and generation • Configurable data format: – Data bit: 5, 6, 7, or 8 bits – Parity bit: Even, odd, none – Stop-bit: 1, 1.5, 2 bit(s) • Flow control: Hardware (RTS/CTS) or software (XON/XOFF) • Only UART1 module has extended modem control signals (CD, RI, DTR, DSR) • Only UART3 supports IrDA NOTE For more information, see the UART section of the Device TRM. Table 7-39, Table 7-40 and Figure 7-32 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-39. Timing Requirements for UART NO. MIN MAX UNIT 4 tw(RX) PARAMETER Pulse width, receive data bit, 15/30/100pF high or low DESCRIPTION 0.96U(1) 1.05U(1) ns 5 tw(CTS) Pulse width, receive start bit, 15/30/100pF high or low 0.96U(1) 1.05U(1) ns (2) ns ns td(RTS-TX) Delay time, transmit start bit to transmit data P td(CTS-TX) Delay time, receive start bit to transmit data P(2) (1) U = UART baud time = 1/programmed baud rate (2) P = Clock period of the reference clock (FCLK, usually 48 MHz or 192MHz). Table 7-40. Switching Characteristics Over Recommended Operating Conditions for UART NO. PARAMETER DESCRIPTION MIN 15 pF f(baud) 2 3 tw(TX) tw(RTS) Maximum programmable baud rate MAX UNIT 12 30 pF 0.23 100 pF 0.115 MHz Pulse width, transmit data bit, 15/30/100 pF high or low U - 2(1) U + 2(1) ns Pulse width, transmit start bit, 15/30/100 pF high or low (1) (1) ns U-2 U+2 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 265 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) U = UART baud time = 1/programmed baud rate 3 2 UARTi_TXD Start Bit Data Bits 5 4 UARTi_RXD Start Bit Data Bits Figure 7-32. UART Timing 7.15 Multichannel Serial Peripheral Interface (MCSPI) The MCSPI is a master/slave synchronous serial bus. There are four separate MCSPI modules (SPI1, SPI2, SPI3, and SPI4) in the device. All these four modules support up to four external devices (four chip selects) and are able to work as both master and slave. The MCSPI modules include the following main features: • Serial clock with programmable frequency, polarity, and phase for each channel • Wide selection of SPI word lengths, ranging from 4 to 32 bits • Up to four master channels, or single channel in slave mode • Master multichannel mode: – Full duplex/half duplex – Transmit-only/receive-only/transmit-and-receive modes – Flexible input/output (I/O) port controls per channel – Programmable clock granularity – SPI configuration per channel. This means, clock definition, polarity enabling and word width • Power management through wake-up capabilities • Programmable timing control between chip select and external clock generation • Built-in FIFO available for a single channel. • Each SPI module supports multiply chip select pins spim_cs[i], whete i = 1 to 4. NOTE For more information, see the Serial Communication Interface section of the device TRM. NOTE The MCSPIm module (m = 1 to 4) is also referred to as SPIm. CAUTION The IO timings provided in this section are applicable for all combinations of signals for SPI1 and SPI2. However, the timings are only valid for SPI3 and SPI4 if signals within a single IOSET are used. The IOSETS are defined in the Table 7-43. 266 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-41, Figure 7-33 and Figure 7-34 present Timing Requirements for McSPI - Master Mode. Table 7-41. Timing Requirements for SPI - Master Mode (1)(8) NO. PARAMETER DESCRIPTION SM1 tc(SPICLK) Cycle time, spi_sclk (1) (2) MODE SM2 tw(SPICLKL) Typical Pulse duration, spi_sclk low SM3 tw(SPICLKH) Typical Pulse duration, spi_sclk high SM4 tsu(MISO-SPICLK) Setup time, spi_d[x] valid before spi_sclk active edge (1) SPI1/2/3/4 (1) (1) (1) th(SPICLK-MISO) Hold time, spi_d[x] valid after spi_sclk active edge td(SPICLK-SIMO) Delay time, spi_sclk active edge to spi_d[x] transition ns ns 0.5*P-1 ns 4.4 ns 3.9 (1) SM7 td(CS-SIMO) Delay time, spi_cs[x] active edge to spi_d[x] transition SM8 td(CS-SPICLK) Delay time, spi_cs[x] active to spi_sclk first edge (1) ns SPI1 -4.27 4.27 ns SPI2 -4.32 4.32 ns SPI3 -5.37 4.23 ns SPI4 -3.81 4..41 ns 5 ns MASTER_PHA0 B-4.6 (6) ns MASTER_PHA1 A-4.6 (7) ns MASTER_PHA0 A-4.6 (7) ns MASTER_PHA1 B-4.6 (6) ns (5) (5) Delay time, spi_sclk last edge to spi_cs[x] inactive (1) UNIT 0.5*P-1 (4) SM6 td(SPICLK-CS) MAX (3) (4) SM5 SM9 MIN 20.8 (5) (5) (1) This timing applies to all configurations regardless of SPI_CLK polarity and which clock edges are used to drive output data and capture input data. (2) Related to the SPI_CLK maximum frequency. (3) 20.8ns cycle time = 48MHz, 26ns cycle time = 38.4MHz (4) P = SPICLK period. (5) SPI_CLK phase is programmable with the PHA bit of the SPI_CH(i)CONF register. (6) B = (TCS + 0.5) * TSPICLKREF * Fratio, where TCS is a bit field of the SPI_CH(i)CONF register and Fratio = Even ≥2. (7) When P = 20.8 ns, A = (TCS + 1) * TSPICLKREF, where TCS is a bit field of the SPI_CH(i)CONF register. When P > 20.8 ns, A = (TCS + 0.5) * Fratio * TSPICLKREF, where TCS is a bit field of the SPI_CH(i)CONF register. (8) The IO timings provided in this section are applicable for all combinations of signals for SPI1 and SPI2. However, the timings are only valid for SPI3 and SPI4 if signals within a single IOSET are used. The IOSETs are defined in the following tables. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 267 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com PHA=0 EPOL=1 spim_cs(OUT) SM1 SM3 SM8 spim_sclk(OUT) SM2 SM9 POL=0 SM3 SM1 SM2 POL=1 spim_sclk(OUT) SM7 SM6 Bit n-1 spim_d(OUT) SM6 Bit n-2 Bit n-3 Bit n-4 Bit 0 PHA=1 EPOL=1 spim_cs(OUT) SM2 SM1 SM8 spim_sclk(OUT) SM3 SM9 POL=0 SM1 SM2 SM3 POL=1 spim_sclk(OUT) SM6 spim_d(OUT) Bit n-1 SM6 Bit n-2 SM6 Bit n-3 SM6 Bit 1 Bit0 Figure 7-33. McSPI - Master Mode Transmit 268 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 PHA=0 EPOL=1 spim_cs(OUT) SM1 SM3 SM8 spim_sclk(OUT) SM2 SM9 POL=0 SM3 SM1 SM2 POL=1 spim_sclk(OUT) SM5 SM5 spim_d(IN) SM4 SM4 Bit n-1 Bit n-2 Bit n-3 Bit n-4 Bit 0 PHA=1 EPOL=1 spim_cs(OUT) SM2 SM1 SM8 spim_sclk(OUT) SM3 SM9 POL=0 SM1 SM2 SM3 POL=1 spim_sclk(OUT) SM5 SM4 SM4 Bit n-1 spim_d(IN) SM5 Bit n-2 Bit n-3 Bit 1 Bit 0 Figure 7-34. McSPI - Master Mode Receive Table 7-42, Figure 7-35 and Figure 7-36 present Timing Requirements for McSPI - Slave Mode. Table 7-42. Timing Requirements for SPI - Slave Mode NO. PARAMETER DESCRIPTION MODE (1) (2) (3) SS1 tc(SPICLK) Cycle time, spi_sclk SS2 tw(SPICLKL) Typical Pulse duration, spi_sclk low SS3 tw(SPICLKH) Typical Pulse duration, spi_sclk high SS4 tsu(SIMO-SPICLK) Setup time, spi_d[x] valid before spi_sclk active edge (1) (1) (1) (1) SS5 th(SPICLK-SIMO) Hold time, spi_d[x] valid after spi_sclk active edge SS6 td(SPICLK-SOMI) Delay time, spi_sclk active edge to mcspi_somi transition MIN MAX 62.5 ns 0.45*P (4) ns 0.45*P (4) ns 5 ns 5 (1) UNIT ns SPI1/2/3 2 26.1 ns SPI4 2 18 ns 20.95 ns (1) SS7 td(CS-SOMI) Delay time, spi_cs[x] active edge to mcspi_somi transition SS8 tsu(CS-SPICLK) Setup time, spi_cs[x] valid before spi_sclk first edge (1) 5 ns SS9 th(SPICLK-CS) Hold time, spi_cs[x] valid after spi_sclk last edge (1) 5 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 269 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) This timing applies to all configurations regardless of SPI_CLK polarity and which clock edges are used to drive output data and capture input data. (2) When operating the SPI interface in RX-only mode, the minimum Cycle time is 26ns (38.4MHz) (3) 62.5ns Cycle time = 16 MHz (4) P = SPICLK period. (5) PHA = 0; SPI_CLK phase is programmable with the PHA bit of the SPI_CH(i)CONF register. PHA=0 EPOL=1 spim_cs(IN) SS2 SS1 SS8 spim_sclk(IN) SS3 SS9 POL=0 SS2 SS1 SS3 POL=1 spim_sclk(IN) SS7 SS6 Bit n-1 spim_d(OUT) SS6 Bit n-2 Bit n-3 Bit n-4 Bit 0 PHA=1 EPOL=1 spim_cs(IN) SS2 SS1 SS8 spim_sclk(IN) SS3 SS9 POL=0 SS3 SS1 SS2 POL=1 spim_sclk(IN) SS6 spim_d(OUT) Bit n-1 SS6 Bit n-2 SS6 Bit n-3 SS6 Bit 1 Bit 0 Figure 7-35. McSPI - Slave Mode Transmit 270 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 PHA=0 EPOL=1 spim_cs(IN) SS2 SS1 SS8 spim_sclk(IN) SS3 SS9 POL=0 SS2 SS1 SS3 POL=1 spim_sclk(IN) SS5 SS4 SS4 SS5 Bit n-1 spim_d(IN) Bit n-2 Bit n-3 Bit n-4 Bit 0 PHA=1 EPOL=1 spim_cs(IN) SS2 SS1 SS8 spim_sclk(IN) SS3 SS9 POL=0 SS3 SS1 SS2 POL=1 spim_sclk(IN) SS4 SS5 SS4 Bit n-1 spim_d(IN) SS5 Bit n-2 Bit n-3 Bit 1 Bit0 Figure 7-36. McSPI - Slave Mode Receive In Table 7-43 are presented the specific groupings of signals (IOSET) for use with SPI3 and SPI4. Table 7-43. McSPI3/4 IOSETs Signal IOSET1 BALL IOSET2 MUX BALL IOSET3 MUX BALL IOSET4 IOSET5 IOSET6 MUX BALL MUX BALL MUX BALL MUX SPI3 spi3_sclk AD9 8 E11 8 V2 7 B12 3 C18 2 AC4 1 spi3_d1 AF9 8 B10 8 Y1 7 A11 3 A21 2 AC7 1 spi3_d0 AE9 8 C11 8 W9 7 B13 3 G16 2 AC6 1 spi3_cs0 AF8 8 D11 8 V9 7 A12 3 D17 2 AC9 1 spi3_cs1 - - B11 8 - - E14 3 - - AC3 1 spi3_cs2 - - F11 8 - - - - - - - - spi3_cs3 - - A10 8 - - - - - - - - spi4_sclk N7 8 G1 8 V7 7 AA3 2 AC8 1 - - spi4_d1 R4 8 G6 8 U7 7 AB9 2 AD6 1 - - SPI4 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 271 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-43. McSPI3/4 IOSETs (continued) Signal IOSET1 IOSET2 IOSET3 BALL MUX BALL MUX IOSET4 IOSET5 IOSET6 BALL MUX BALL MUX BALL MUX BALL MUX spi4_d0 N9 8 F2 8 V6 7 AB3 2 AB8 1 - - spi4_cs0 P9 8 F3 8 U6 7 AA4 2 AB5 1 - - spi4_cs1 P4 8 - - Y1 8 - - - - - - spi4_cs2 R3 8 - - W9 8 - - - - - - spi4_cs3 T2 8 - - V9 8 - - - - - - 7.16 Quad Serial Peripheral Interface (QSPI) The Quad SPI (QSPI) module is a type of SPI module that allows single, dual or quad read access to external SPI devices. This module has a memory mapped register interface, which provides a direct interface for accessing data from external SPI devices and thus simplifying software requirements. It works as a master only. There is one QSPI module in the device and it is primary intended for fast booting from quad-SPI flash memories. General SPI features: • Programmable clock divider • Six pin interface (DCLK, CS_N, DOUT, DIN, QDIN1, QDIN2) • 4 external chip select signals • Support for 3-, 4- or 6-pin SPI interface • Programmable CS_N to DOUT delay from 0 to 3 DCLKs • Programmable signal polarities • Programmable active clock edge • Software controllable interface allowing for any type of SPI transfer NOTE For more information, see the Quad Serial Peripheral Interface section of the Device TRM. CAUTION The IO Timings provided in this section are only valid for some QSPI usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. CAUTION The IO Timings provided in this section are only valid when all QSPI Chip Selects used in a system are configured to use the same Clock Mode (either Clock Mode 0 or Clock Mode3). Table 7-44 and Table 7-45 present Timing and Switching Characteristics for Quad SPI Interface. 272 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-44. Switching Characteristics for QSPI No PARAMETER DESCRIPTION Mode MIN Q1 tc(SCLK) Cycle time, sclk Default Timing Mode, Clock Mode 0 13.02 MAX UNIT ns Default Timing Mode, Clock Mode 3 20.8 ns Y*P-1 (1) ns Q2 tw(SCLKL) Pulse duration, sclk low Q3 tw(SCLKH) Pulse duration, sclk high Y*P-1 (1) ns Q4 td(CS-SCLK) Delay time, sclk falling edge to cs active edge, CS3:0 Default Timing Mode -M*P-2.0 -M*P+2.0 (2) (3) (2) (3) ns Q5 td(SCLK-CS) Delay time, sclk falling edge to cs inactive edge, CS3:0 Default Timing Mode N*P-2.0 (2) (3) N*P+2.0 (2) (3) ns Q6 td(SCLK-D1) Delay time, sclk falling edge to d[0] transition Default Timing Mode -2 2 ns Q7 tena(CS-D1LZ) Enable time, cs active edge to d[0] driven (lo-z) -P-3.5 -P+2.5 ns Q8 tdis(CS-D1Z) Disable time, cs active edge to d[0] tri-stated (hi-z) -P-2.5 -P+2.0 ns Q9 td(SCLK-D0) Delay time, sclk first falling edge to first d[0] transition -2.45 - P 1 .45 - P ns PHA=0 Only, Default Timing Mode (1) The Y parameter is defined as follows: If DCLK_DIV is 0 or ODD then, Y equals 0.5. If DCLK_DIV is EVEN then, Y equals (DCLK_DIV/2) / (DCLK_DIV+1). For best performance, it is recommended to use a DCLK_DIV of 0 or ODD to minimize the duty cycle distortion. The HSDIVIDER on CLKOUTX2_H13 output of DPLL_PER can be used to achieve the desired clock divider ratio. All required details about clock division factor DCLK_DIV can be found in the device TRM. (2) P = SCLK period. (3) M=QSPI_SPI_DC_REG.DDx + 1 when Clock Mode 0. M=QSPI_SPI_DC_REG.DDx when Clock Mode 3. N = 2 when Clock Mode 0. N = 3 when Clock Mode 3. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 273 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com PHA=1 cs Q5 Q1 POL=1 Q4 Q3 Q2 sclk Q15 POL=1 Q14 rtclk Q6 Q7 Q6 Command Bit n-1 d[0] Command Bit n-2 d[3:1] Q12 Q13 Read Data Read Data Bit 1 Bit 0 Q14 Q15 Q12 Q13 Read Data Read Data Bit 1 Bit 0 SPRS85v_TIMING_OSPI1_01 Figure 7-37. QSPI Read (Clock Mode 3) PHA=0 cs Q5 Q4 Q1 Q2 POL=0 Q3 sclk POL=0 rtclk Q7 d[0] Q6 Q9 Command Command Bit n-1 Bit n-2 Q12 Q13 Read Data Bit 1 Q12 Q13 d[3:1] Read Data Bit 1 Q12 Q13 Read Data Bit 0 Q12 Q13 Read Data Bit 0 SPRS85v_TIMING_OSPI1_02 Figure 7-38. QSPI Read (Clock Mode 0) 274 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 CAUTION The IO Timings provided in this section are only valid for some QSPI usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-45. Timing Requirements for QSPI No PARAMETER DESCRIPTION Mode MIN Q12 tsu(D-RTCLK) Setup time, d[3:0] valid before falling rtclk edge Default Timing Mode, Clock Mode 0 5.1 ns tsu(D-SCLK) Setup time, d[3:0] valid before falling sclk edge Default Timing Mode, Clock Mode 3 12.3 ns th(RTCLK-D) Hold time, d[3:0] valid after falling rtclk edge Default Timing Mode, Clock Mode 0 -0.1 ns th(SCLK-D) Hold time, d[3:0] valid after falling sclk edge Default Timing Mode, Clock Mode 3 0 ns Q14 tsu(D-SCLK) Setup time, final d[3:0] bit valid before final falling sclk edge Default Timing Mode, Clock Mode 3 12.3-P (1) ns Q5 th(SCLK-D) Hold time, final d[3:0] bit valid after final falling sclk edge Default Timing Mode, Clock Mode 3 0+P (1) ns Q13 MAX Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated UNIT 275 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = SCLK period. (2) Clock Modes 1 and 2 are not supported. (3) The Device captures data on the falling clock edge in Clock Mode 0 and 3, as opposed to the traditional rising clock edge. Although nonstandard, the falling-edge-based setup and hold time timings have been designed to be compatible with standard SPI devices that launch data on the falling edge in Clock Modes 0 and 3. PHA=1 cs Q5 POL=1 Q1 Q4 Q3 Q2 sclk Q7 d[0] Command Bit n-1 Write Data Bit 1 Command Bit n-2 Q8 Q6 Q6 Q6 Q6 Write Data Bit 0 d[3:1] SPRS85v_TIMING_OSPI1_03 Figure 7-39. QSPI Write (Clock Mode 3) PHA=0 cs Q5 Q4 POL=0 Q1 Q2 Q3 sclk Q7 d[0] Q9 Q6 Command Command Bit n-1 Bit n-2 Q6 Q8 Q6 Write Data Bit 1 Write Data Bit 0 d[3:1] SPRS85v_TIMING_OSPI1_04 Figure 7-40. QSPI Write (Clock Mode 0) 276 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for QSPI. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-46 Manual Functions Mapping for QSPI for a definition of the Manual modes. Table 7-46 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 277 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-46. Manual Functions Mapping for QSPI BALL T7 BALL NAME QSPI_MODE0_MANUAL1 CFG REGISTER MUXMODE 0 CFG_GPMC_A3_OUT qspi1_cs2 A_DELAY (ps) G_DELAY (ps) gpmc_a3 114 1 P6 gpmc_a4 91 0 CFG_GPMC_A4_OUT qspi1_cs3 R3 gpmc_a13 0 0 CFG_GPMC_A13_IN qspi1_rtclk T2 gpmc_a14 2575 966 CFG_GPMC_A14_IN qspi1_d3 U2 gpmc_a15 2503 889 CFG_GPMC_A15_IN qspi1_d2 U1 gpmc_a16 2528 1007 CFG_GPMC_A16_IN qspi1_d0 U1 gpmc_a16 0 0 CFG_GPMC_A16_OUT qspi1_d0 P3 gpmc_a17 2533 980 CFG_GPMC_A17_IN qspi1_d1 R2 gpmc_a18 590 0 CFG_GPMC_A18_OUT qspi1_sclk P2 gpmc_cs2 0 0 CFG_GPMC_CS2_OUT qspi1_cs0 P1 gpmc_cs3 70 0 CFG_GPMC_CS3_OUT qspi1_cs1 7.17 Multichannel Audio Serial Port (McASP) The multichannel audio serial port (McASP) functions as a general-purpose audio serial port optimized for the needs of multichannel audio applications. The McASP is useful for time-division multiplexed (TDM) stream, Inter-Integrated Sound (I2S) protocols, and inter-component digital audio interface transmission (DIT). The device have integrated 8 McASP modules (McASP1-McASP8) with: • McASP1 and McASP2 modules supporting 16 channels with independent TX/RX clock/sync domain • McASP3 through McASP8 modules supporting 4 channels with independent TX/RX clock/sync domain NOTE For more information, see the Multichannel Audio Serial Port section of the Device TRM. CAUTION The IO Timings provided in this section are only valid for some McASP usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-47, Table 7-48, Table 7-49 and Figure 7-41 present Timing Requirements for McASP1 to McASP8. 278 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-47. Timing Requirements for McASP1 (1) NO. PARAMETER DESCRIPTION 1 tc(AHCLKRX) Cycle time, AHCLKR/X 2 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 3 tc(ACLKRX) Cycle time, ACLKR/X 4 tw(ACLKRX) Pulse duration, ACLKR/X high or low 5 tsu(AFSRX-ACLK) Setup time, AFSR/X input valid before ACLKR/X 6 7 8 th(ACLK-AFSRX) tsu(AXR-ACLK) th(ACLK-AXR) Hold time, AFSR/X input valid after ACLKR/X Setup time, AXR input valid before ACLKR/X Hold time, AXR input valid after ACLKR/X MODE MIN MAX UNIT 20 ns 0.35P ns (2) 20 ns 0.5R - 3 ns ACLKR/X int 20 ns ACLKR/X ext in ACLKR/X ext out 4 ns (3) ACLKR/X int -1 ns ACLKR/X ext in ACLKR/X ext out 2.21 ns ACLKR/X int 21.9 ns ACLKR/X ext in ACLKR/X ext out 4.42 ns ACLKR/X int -1 ns ACLKR/X ext in ACLKR/X ext out 2.52 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. Table 7-48. Timing Requirements for McASP2 (1) NO. PARAMETER DESCRIPTION 1 tc(AHCLKRX) Cycle time, AHCLKR/X 2 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 3 tc(ACLKRX) Cycle time, ACLKR/X 4 5 6 7 tw(ACLKRX) tsu(AFSRX-ACLK) th(ACLK-AFSRX) tsu(AXR-ACLK) Pulse duration, ACLKR/X high or low Setup time, AFSR/X input valid before ACLKR/X Hold time, AFSR/X input valid after ACLKR/X Setup time, AXR input valid before ACLKR/X MODE MIN MAX ns 0.35P ns Any Other Conditions 20 ns ACLKX/AFSX (In Sync Mode), ACLKR/AFSR (In Async Mode), and AXR are all inputs 12.5 ns Any Other Conditions 0.5R - 3 ns ACLKX/AFSX (In Sync Mode), ACLKR/AFSR (In Async Mode), and AXR are all inputs 0.38R ns (2) (3) (3) ACLKR/X int 20.7 ns ACLKR/X ext in ACLKR/X ext out 3 ns ACLKR/X int -1 ns ACLKR/X ext in ACLKR/X ext out 3 ns ACLKR/X int 21.4 ns ACLKR/X ext in ACLKR/X ext out 3 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated UNIT 20 279 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-48. Timing Requirements for McASP2 (1) (continued) NO. 8 PARAMETER DESCRIPTION th(ACLK-AXR) Hold time, AXR input valid after ACLKR/X MODE MIN ACLKR/X int -1 MAX UNIT ns ACLKR/X ext in ACLKR/X ext out 3 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. Table 7-49. Timing Requirements for McASP3/4/5/6/7/8 NO. PARAMETER DESCRIPTION 1 tc(AHCLKRX) Cycle time, AHCLKR/X 2 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 3 tc(ACLKRX) Cycle time, ACLKR/X 4 tw(ACLKRX) Pulse duration, ACLKR/X high or low 5 tsu(AFSRX-ACLK) Setup time, AFSR/X input valid before ACLKR/X 6 th(ACLK-AFSRX) tsu(AXR-ACLK) 8 th(ACLK-AXR) Hold time, AFSR/X input valid after ACLKR/X Setup time, AXR input valid before ACLKX Hold time, AXR input valid after ACLKX (1) MODE MIN MAX UNIT 20 ns 0.35P ns (2) 20 ns 0.5R - 3 ns ACLKR/X int 20.2 ns ACLKR/X ext in ACLKR/X ext out 4.9 ns (3) ACLKR/X int -1 ns ACLKR/X ext in ACLKR/X ext out 2.26 ns ACLKX int (ASYNC=0) 20.8 ns ACLKR/X ext in ACLKR/X ext out 5.75 ns ACLKX int (ASYNC=0) -0.9 ns ACLKR/X ext in ACLKR/X ext out 2.87 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 (NOT SUPPORTED) ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. 280 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 2 1 2 AHCLKR/X (Falling Edge Polarity) AHCLKR/X (Rising Edge Polarity) 4 3 4 ACLKR/X (CLKRP = CLKXP = 0)(A) ACLKR/X (CLKRP = CLKXP = 1)(B) 6 5 AFSR/X (Bit Width, 0 Bit Delay) AFSR/X (Bit Width, 1 Bit Delay) AFSR/X (Bit Width, 2 Bit Delay) AFSR/X (Slot Width, 0 Bit Delay) AFSR/X (Slot Width, 1 Bit Delay) AFSR/X (Slot Width, 2 Bit Delay) 8 7 AXR[n] (Data In/Receive) A0 A. B. For CLKRP = CLKXP = receiver is configured for For CLKRP = CLKXP = receiver is configured for A1 A30 A31 B0 B1 B30 B31 C0 C1 C2 C3 C31 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP falling edge (to shift data in). 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP rising edge (to shift data in). Figure 7-41. McASP Input Timing CAUTION The IO Timings provided in this section are only valid for some McASP usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-50, Table 7-51, Table 7-52 and Figure 7-42 present Switching Characteristics Over Recommended Operating Conditions for McASP1 to McASP8. Table 7-50. Switching Characteristics Over Recommended Operating Conditions for McASP1 NO. PARAMETER DESCRIPTION 9 tc(AHCLKRX) Cycle time, AHCLKR/X 10 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low MODE MIN (1) MAX ns 0.5P 2.5 (2) ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated UNIT 20 281 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-50. Switching Characteristics Over Recommended Operating Conditions for McASP1 (1) (continued) NO. PARAMETER DESCRIPTION 11 tc(ACLKRX) Cycle time, ACLKR/X 12 tw(ACLKRX) Pulse duration, ACLKR/X high or low 13 td(ACLK-AFSXR) Delay time, ACLKR/X transmit edge to AFSX/R output valid 14 td(ACLK-AXR) Delay time, ACLKR/X transmit edge to AXR output valid MODE MIN MAX UNIT 20 ns 0.5P 2.5 (3) ns ACLKR/X int -0.21 6 ns ACLKR/X ext in ACLKR/X ext out 2 23.9 ns ACLKR/X int -1.8 6.9 ns ACLKR/X ext in ACLKR/X ext out 2 25.6 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. Table 7-51. Switching Characteristics Over Recommended Operating Conditions for McASP2 NO. PARAMETER DESCRIPTION 9 tc(AHCLKRX) Cycle time, AHCLKR/X 10 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 11 tc(ACLKRX) Cycle time, ACLKR/X 12 tw(ACLKRX) Pulse duration, ACLKR/X high or low 13 td(ACLK-AFSXR) Delay time, ACLKR/X transmit edge to AFSX/R output valid 14 td(ACLK-AXR) Delay time, ACLKR/X transmit edge to AXR output valid MODE MIN MAX (1) UNIT 20 ns 0.5P 2.5 (2) ns 20 ns 0.5P 2.5 (3) ns ACLKR/X int 0 6 ns ACLKR/X ext in ACLKR/X ext out 2 25.2 ns ACLKR/X int -1.29 6.11 ns ACLKR/X ext in ACLKR/X ext out 2 24.8 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. Table 7-52. Switching Characteristics Over Recommended Operating Conditions for McASP3/4/5/6/7/8 NO. PARAMETER DESCRIPTION 9 tc(AHCLKRX) Cycle time, AHCLKR/X 10 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 11 tc(ACLKRX) Cycle time, ACLKR/X 12 tw(ACLKRX) Pulse duration, ACLKR/X high or low 13 td(ACLK-AFSXR) Delay time, ACLKR/X transmit edge to AFSX/R output valid 282 MODE MIN MAX (1) UNIT 20 ns 0.5P 2.5 (2) ns 20 ns 0.5P 2.5 (3) ns ACLKR/X int -0.74 6 ns ACLKR/X ext in ACLKR/X ext out 2 26.4 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-52. Switching Characteristics Over Recommended Operating Conditions for McASP3/4/5/6/7/8 (1) (continued) NO. 14 PARAMETER DESCRIPTION td(ACLK-AXR) Delay time, ACLKR/X transmit edge to AXR output valid MODE MIN MAX UNIT ACLKR/X int -1.68 6.97 ns ACLKR/X ext in ACLKR/X ext out 1.07 25.9 ns (1) ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1 ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0 ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1 ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1 ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0 ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1 (2) P = AHCLKR/X period in ns. (3) R = ACLKR/X period in ns. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 283 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 10 10 9 AHCLKR/X (Falling Edge Polarity) AHCLKR/X (Rising Edge Polarity) 12 11 12 ACLKR/X (CLKRP = CLKXP = 1)(A) ACLKR/X (CLKRP = CLKXP = 0)(B) 13 13 13 13 AFSR/X (Bit Width, 0 Bit Delay) AFSR/X (Bit Width, 1 Bit Delay) AFSR/X (Bit Width, 2 Bit Delay) 13 13 13 AFSR/X (Slot Width, 0 Bit Delay) AFSR/X (Slot Width, 1 Bit Delay) AFSR/X (Slot Width, 2 Bit Delay) 14 15 AXR[n] (Data Out/Transmit) A0 A. B. For CLKRP = CLKXP = receiver is configured for For CLKRP = CLKXP = receiver is configured for A1 A30 A31 B0 B1 B30 B31 C0 C1 C2 C3 C31 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP rising edge (to shift data in). 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP falling edge (to shift data in). Figure 7-42. McASP Output Timing NOTE To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register. The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter. Table 7-53 through Table 7-60 explain all cases with Virtual Mode Details for McASP1/2/3/4/5/6/7/8 (see Figure 7-43 through Figure 7-50). 284 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-53. Virtual Mode Case Details for McASP1 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 COIFOI CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL1_ASYNC_TX AXR(Inputs)/CLKR/FSR MCASP1_VIRTUAL3_ASYNC_RX 2 COIFIO CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL1_ASYNC_TX AXR(Inputs)/CLKR/FSR MCASP1_VIRTUAL3_ASYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL3_ASYNC_RX AXR(Inputs)/CLKR/FSR MCASP1_VIRTUAL1_ASYNC_TX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL3_ASYNC_RX AXR(Inputs)/CLKR/FSR MCASP1_VIRTUAL1_ASYNC_TX 3 4 CIOFIO CIOFOI See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 6 CO-FOCI-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP1_VIRTUAL2_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP1_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP1_VIRTUAL2_SYNC_RX 8 CO-FI- CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Table 7-54. Virtual Mode Case Details for McASP2 No. CASE CASE Description Virtual Mode Settings Notes Signals Virtual Mode Value Virtual Mode Value when ACLKR, AFSR, and AXR are all inputs CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL3_ASYNC_TX N/A AXR(Inputs)/CLKR/FSR MCASP2_VIRTUAL2_ASYNC_RX MCASP2_VIRTUAL1_AS YNC_RX_80M IP Mode : ASYNC 1 COIFOI 2 COIFIO CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL3_ASYNC_TX N/A AXR(Inputs)/CLKR/FSR MCASP2_VIRTUAL2_ASYNC_RX N/A 3 CIOFIO CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL2_ASYNC_RX N/A AXR(Inputs)/CLKR/FSR MCASP2_VIRTUAL3_ASYNC_TX N/A 4 CIOFOI CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL2_ASYNC_RX N/A AXR(Inputs)/CLKR/FSR MCASP2_VIRTUAL3_ASYNC_TX N/A See Figure 743 See Figure 744 See Figure 745 See Figure 746 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 CO-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FS X Default (No Virtual Mode) N/A 6 CI-FO- FSX: Output CLKX: Input AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) N/A AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL4_SYNC_RX N/A AXR(Inputs)/CLKX/FSX MCASP2_VIRTUAL4_SYNC_RX N/A See Figure 747 See Figure 748 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 285 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-54. Virtual Mode Case Details for McASP2 (continued) No. 7 CASE CI-FI- 8 CO-FI- CASE Description CLKX / FSX: Input CLKX: Output FSX: Input Virtual Mode Settings Notes Signals Virtual Mode Value Virtual Mode Value when ACLKR, AFSR, and AXR are all inputs AXR(Outputs)/CLKX/FS X MCASP2_VIRTUAL4_SYNC_RX N/A AXR(Inputs)/CLKX/FSX MCASP2_VIRTUAL4_SYNC_RX MCASP2_VIRTUAL5_SY NC_RX_80M AXR(Outputs)/CLKX/FS X Default (No Virtual Mode) N/A AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) N/A See Figure 749 See Figure 750 Table 7-55. Virtual Mode Case Details for McASP3 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 2 3 4 COIFOI COIFIO CIOFIO CIOFOI CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP3_VIRTUAL2_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP3_VIRTUAL2_SYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP3_VIRTUAL2_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP3_VIRTUAL2_SYNC_RX See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 6 CO-FOCI-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP3_VIRTUAL2_SYNC_RX 8 CO-FI- CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Table 7-56. Virtual Mode Case Details for McASP4 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 2 286 COIFOI COIFIO CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP4_VIRTUAL1_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP4_VIRTUAL1_SYNC_RX See Figure 7-43 See Figure 7-44 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-56. Virtual Mode Case Details for McASP4 (continued) No. 3 4 CASE CIOFIO CIOFOI CASE Description Virtual Mode Settings Notes Signals Virtual Mode Value CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP4_VIRTUAL1_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP4_VIRTUAL1_SYNC_RX See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 CO-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) 6 CI-FO- FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP4_VIRTUAL1_SYNC_RX CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) 8 CO-FI- See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Table 7-57. Virtual Mode Case Details for McASP5 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 2 3 4 COIFOI COIFIO CIOFIO CIOFOI CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP5_VIRTUAL1_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP5_VIRTUAL1_SYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP5_VIRTUAL1_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP5_VIRTUAL1_SYNC_RX See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 6 CO-FOCI-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP5_VIRTUAL1_SYNC_RX 8 CO-FI- CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Table 7-58. Virtual Mode Case Details for McASP6 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 287 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-58. Virtual Mode Case Details for McASP6 (continued) No. 1 2 3 4 CASE COIFOI COIFIO CIOFIO CIOFOI CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP6_VIRTUAL1_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP6_VIRTUAL1_SYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP6_VIRTUAL1_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP6_VIRTUAL1_SYNC_RX See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 CO-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) 6 CI-FO- FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP6_VIRTUAL1_SYNC_RX 8 CO-FI- CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Table 7-59. Virtual Mode Case Details for McASP7 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 2 3 4 COIFOI COIFIO CIOFIO CIOFOI CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP7_VIRTUAL2_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP7_VIRTUAL2_SYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP7_VIRTUAL2_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP7_VIRTUAL2_SYNC_RX See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 CO-FO- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) 6 CI-FO- FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX 7 CI-FI- CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP7_VIRTUAL2_SYNC_RX CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) 8 288 CO-FI- See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-60. Virtual Mode Case Details for McASP8 No. CASE CASE Description Virtual Mode Settings Signals Notes Virtual Mode Value IP Mode : ASYNC 1 2 3 4 COIFOI COIFIO CIOFIO CIOFOI CLKX / FSX: Output CLKR / FSR: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP8_VIRTUAL1_SYNC_RX CLKX / FSR: Output CLKR / FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKR/FSR MCASP8_VIRTUAL1_SYNC_RX CLKR / FSR: Output CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP8_VIRTUAL1_SYNC_RX CLKR / FSX: Output CLKX / FSR: Input AXR(Outputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKR/FSR MCASP8_VIRTUAL1_SYNC_RX See Figure 7-43 See Figure 7-44 See Figure 7-45 See Figure 7-46 IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX) 5 6 7 8 CO-FOCI-FOCI-FICO-FI- CLKX / FSX: Output AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) FSX: Output CLKX: Input AXR(Outputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX CLKX / FSX: Input AXR(Outputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX AXR(Inputs)/CLKX/FSX MCASP8_VIRTUAL1_SYNC_RX CLKX: Output FSX: Input AXR(Outputs)/CLKX/FSX Default (No Virtual Mode) AXR(Inputs)/CLKX/FSX Default (No Virtual Mode) MCASP See Figure 7-47 See Figure 7-48 See Figure 7-49 See Figure 7-50 SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-43. McASP1-8 COIFOI – ASYNC Mode Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 289 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-44. McASP1-8 COIFIO – ASYNC Mode MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-45. McASP1-8 CIOFIO – ASYNC Mode 290 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-46. McASP1-8 CIOFOI – ASYNC Mode MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-47. McASP1-8 COIFOI – SYNC Mode Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 291 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-48. McASP1-8 CIOFOI – SYNC Mode MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-49. McASP1-8 CIOFIO – SYNC Mode 292 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 MCASP SoC IOs CLKX FSX TXDATA CLKR FSR RXDATA Figure 7-50. McASP1-8 COIFIO – SYNC Mode Virtual IO Timings Modes must be used to guarantee some IO timings for McASP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-61 Virtual Functions Mapping for McASP1 for a definition of the Virtual modes. Table 7-61 presents the values for DELAYMODE bitfield. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 293 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-61. Virtual Functions Mapping for McASP1 BALL BALL NAME Delay Mode Value MUXMODE[15:0] MCASP1_VIRTUAL1_A SYNC_TX MCASP1_VIRTUAL2_S YNC_RX MCASP1_VIRTUAL3_A SYNC_RX 0 1 2 3 mcasp1_ahclkx E21 gpio6_14 11 15 14 F20 gpio6_15 11 15 14 mcasp1_axr8 mcasp1_axr9 F21 gpio6_16 11 15 14 mcasp1_axr10 D18 xref_clk0 0 15 14 mcasp1_axr4 E17 xref_clk1 0 15 14 mcasp1_axr5 B26 xref_clk2 5 15 14 mcasp1_axr6 C23 xref_clk3 5 15 14 mcasp1_axr7 C14 mcasp1_aclkx 8 15 14 D14 mcasp1_fsx 12 15 14 mcasp1_fsx B14 mcasp1_aclkr 11 N/A 15 mcasp1_aclkr mcasp1_aclkx J14 mcasp1_fsr 11 N/A 15 mcasp1_fsr G12 mcasp1_axr0 8 15 14 mcasp1_axr0 F12 mcasp1_axr1 8 15 14 mcasp1_axr1 G13 mcasp1_axr2 10 15 14 mcasp1_axr2 J11 mcasp1_axr3 10 15 14 mcasp1_axr3 E12 mcasp1_axr4 10 15 14 mcasp1_axr4 F13 mcasp1_axr5 10 15 14 mcasp1_axr5 C12 mcasp1_axr6 10 15 14 mcasp1_axr6 D12 mcasp1_axr7 10 15 14 mcasp1_axr7 B12 mcasp1_axr8 6 15 14 mcasp1_axr8 A11 mcasp1_axr9 6 15 14 mcasp1_axr9 B13 mcasp1_axr10 6 15 14 mcasp1_axr10 A12 mcasp1_axr11 6 15 14 mcasp1_axr11 E14 mcasp1_axr12 6 15 14 mcasp1_axr12 A13 mcasp1_axr13 6 15 14 mcasp1_axr13 G14 mcasp1_axr14 6 15 14 mcasp1_axr14 F14 mcasp1_axr15 6 15 14 mcasp1_axr15 1. NA in this table stands for Not Applicable. Virtual IO Timings Modes must be used to guarantee some IO timings for McASP2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-62 Virtual Functions Mapping for McASP2 for a definition of the Virtual modes. Table 7-62 presents the values for DELAYMODE bitfield. 294 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-62. Virtual Functions Mapping for McASP2 BALL BALL NAME Delay Mode Value MUXMODE[15:0] MCASP2_ VIRTUAL1 _ ASYNC_R X_80M MCASP2_ VIRTUAL2 _ ASYNC_R X MCASP2_ VIRTUAL3 _ ASYNC_TX MCASP2_ VIRTUAL4 _ SYNC_RX MCASP2_ VIRTUAL5 _ SYNC_RX_ 80M 9 4 8 6 0 1 D18 xref_clk0 10 E17 xref_clk1 10 9 4 8 6 mcasp2_axr9 B26 xref_clk2 13 12 0 11 10 mcasp2_axr10 C23 xref_clk3 13 12 0 11 10 mcasp2_axr11 A19 mcasp2_aclkx 15 14 5 10 9 A18 mcasp2_fsx 15 14 5 10 9 mcasp2_fsx E15 mcasp2_aclkr 15 14 10 N/A N/A mcasp2_aclkr A20 mcasp2_fsr 15 14 10 N/A N/A mcasp2_fsr B15 mcasp2_axr0 15 14 9 13 12 mcasp2_axr0 2 3 mcasp2_axr8 mcasp2_ahclkx mcasp2_aclkx A15 mcasp2_axr1 15 14 9 13 12 mcasp2_axr1 C15 mcasp2_axr2 15 14 4 10 9 mcasp2_axr2 A16 mcasp2_axr3 15 14 4 10 9 mcasp2_axr3 D15 mcasp2_axr4 15 14 7 13 12 mcasp2_axr4 B16 mcasp2_axr5 15 14 7 13 12 mcasp2_axr5 B17 mcasp2_axr6 15 14 7 13 12 mcasp2_axr6 A17 mcasp2_axr7 15 14 7 13 12 mcasp2_axr7 B18 mcasp3_aclkx 15 14 5 10 9 mcasp2_axr12 F15 mcasp3_fsx 15 14 4 10 9 mcasp2_axr13 B19 mcasp3_axr0 15 14 4 10 9 mcasp2_axr14 C17 mcasp3_axr1 15 14 3 10 8 mcasp2_axr15 1. NA in this table stands for Not Applicable. Virtual IO Timings Modes must be used to guarantee some IO timings for McASP3/4/5/6/7/8. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-63 Virtual Functions Mapping for McASP3/4/5/6/7/8 for a definition of the Virtual modes. Table 7-63 presents the values for DELAYMODE bitfield. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 295 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-63. Virtual Functions Mapping for McASP3/4/5/6/7/8 BALL BALL NAME Delay Mode Value MUXMODE[15:0] 0 1 2 MCASP3_VIRTUAL2_SYNC_RX C15 mcasp2_axr2 8 A16 mcasp2_axr3 8 B18 mcasp3_aclkx 8 mcasp3_axr2 mcasp3_axr3 mcasp3_aclkx mcasp3_aclkr mcasp3_fsr F15 mcasp3_fsx 8 mcasp3_fsx B19 mcasp3_axr0 8 mcasp3_axr0 C17 mcasp3_axr1 6 mcasp3_axr1 E12 mcasp1_axr4 13 F13 mcasp1_axr5 13 C18 mcasp4_aclkx 15 MCASP4_VIRTUAL1_SYNC_RX mcasp4_axr2 mcasp4_axr3 mcasp4_aclkx mcasp4_aclkr mcasp4_fsr A21 mcasp4_fsx 15 mcasp4_fsx G16 mcasp4_axr0 15 mcasp4_axr0 D17 mcasp4_axr1 15 mcasp4_axr1 C12 mcasp1_axr6 13 mcasp5_axr2 D12 mcasp1_axr7 13 mcasp5_axr3 AA3 mcasp5_aclkx 15 mcasp5_aclkx mcasp5_aclkr AB9 mcasp5_fsx 15 mcasp5_fsx mcasp5_fsr AB3 mcasp5_axr0 15 mcasp5_axr0 AA4 mcasp5_axr1 15 mcasp5_axr1 G13 mcasp1_axr2 13 mcasp6_axr2 J11 mcasp1_axr3 13 mcasp6_axr3 B12 mcasp1_axr8 10 mcasp6_axr0 A11 mcasp1_axr9 10 mcasp6_axr1 B13 mcasp1_axr10 10 mcasp6_aclkx mcasp6_aclkr A12 mcasp1_axr11 10 mcasp6_fsx mcasp6_fsr MCASP5_VIRTUAL1_SYNC_RX MCASP6_VIRTUAL1_SYNC_RX MCASP7_VIRTUAL2_SYNC_RX 296 B14 mcasp1_aclkr 14 mcasp7_axr2 J14 mcasp1_fsr 14 mcasp7_axr3 E14 mcasp1_axr12 10 mcasp7_axr0 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-63. Virtual Functions Mapping for McASP3/4/5/6/7/8 (continued) BALL BALL NAME Delay Mode Value MUXMODE[15:0] A13 mcasp1_axr13 10 mcasp7_axr1 G14 mcasp1_axr14 10 mcasp7_aclkx mcasp7_aclkr F14 mcasp1_axr15 10 mcasp7_fsx mcasp7_fsr 0 1 2 MCASP8_VIRTUAL1_SYNC_RX E15 mcasp2_aclkr 13 mcasp8_axr2 A20 mcasp2_fsr 13 mcasp8_axr3 D15 mcasp2_axr4 11 mcasp8_axr0 B16 mcasp2_axr5 11 mcasp8_axr1 B17 mcasp2_axr6 11 mcasp8_aclkx mcasp8_aclkr A17 mcasp2_axr7 11 mcasp8_fsx mcasp8_fsr Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 297 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 7.18 Universal Serial Bus (USB) SuperSpeed USB DRD Subsystem has four instances in the device providing the following functions: • USB1: SuperSpeed (SS) USB 3.0 Dual-Role-Device (DRD) subsystem with integrated SS (USB3.0) PHY and HS/FS (USB2.0) PHY. • USB2: High-Speed (HS) USB 2.0 Dual-Role-Device (DRD) subsystem with integrated HS/FS PHY. • USB3: HS USB 2.0 Dual-Role-Device (DRD) subsystem with ULPI (SDR) interface to external HS/FS PHYs. • USB4: HS USB 2.0 Dual-Role-Device (DRD) subsystem with ULPI (SDR) interface to external HS/FS PHYs. NOTE For more information, see the SuperSpeed USB DRD section of the Device TRM. 7.18.1 USB1 DRD PHY The USB1 DRD interface supports the following applications: • USB2.0 High-Speed PHY port (1.8 V and 3.3 V): this asynchronous high-speed interface is compliant with the USB2.0 PHY standard with an internal transceiver (USB2.0 standard v2.0), for a maximum data rate of 480 Mbps. • USB3.0 Super-Speed PHY port (1.8 V): this asynchronous differential super-speed interface is compliant with the USB3.0 RX/TX PHY standard (USB3.0 standard v1.0) for a maximum data bit rate of 5Gbps. 7.18.2 USB2 PHY The USB2 interface supports the following applications: • USB2.0 High-Speed PHY port (1.8 V and 3.3 V): this asynchronous high-speed interface is compliant with the USB2.0 PHY standard with an internal transceiver (USB2.0 standard v2.0), for a maximum data rate of 480 Mbps. 7.18.3 USB3 and USB4 DRD ULPI—SDR—Slave Mode—12-pin Mode TheUSB3 and USB4 DRD interfaces support the following application: • USB ULPI port: this synchronous interface is compliant with the USB2.0 ULPI SDR standard (UTMI+ v1.22), for alternative off-chip USB2.0 PHY interface; that is, with external transceiver with a maximum frequency of 60 MHz (synchronous slave mode, SDR, 12-pin, 8-data-bit). NOTE The Universal Serial Bus k ULPI modules are also refered as USBk where k = 3, 4. Table 7-64, Table 7-65 and Figure 7-51 assume testing over the recommended operating conditions and electrical characteristic conditions. Table 7-64. Timing Requirements for ULPI SDR Slave Mode NO. 298 PARAMETER DESCRIPTION MIN MAX UNIT US1 tc(clk) Cycle time, usb_ulpi_clk period 16.66 ns US5 tsu(ctrlV-clkH) Setup time, usb_ulpi_dir/usb_ulpi_nxt valid before usb_ulpi_clk rising edge 6.73 ns US6 th(clkH-ctrlV) Hold time, usb_ulpi_dir/usb_ulpi_nxt valid after usb_ulpi_clk rising edge -0.41 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-64. Timing Requirements for ULPI SDR Slave Mode (continued) NO. PARAMETER DESCRIPTION MIN MAX UNIT US7 tsu(dV-clkH) Setup time, usb_ulpi_d[7:0] valid before usb_ulpi_clk rising edge 6.73 ns US8 th(clkH-dV) Hold time, usb_ulpi_d[7:0] valid after usb_ulpi_clk rising edge -0.41 ns Table 7-65. Switching Characteristics for ULPI SDR Slave Mode MIN MAX UNIT US4 NO. td(clkH-stpV) PARAMETER Delay time, usb_ulpi_clk rising edge high to output usb_ulpi_stp valid DESCRIPTION 0.44 8.35 ns US9 td(clkL-doV) Delay time, usb_ulpi_clk rising edge high to output usb_ulpi_d[7:0] valid 0.44 8.35 ns US1 US2 US3 usbk_ulpi_clk US4 US4 usbk_ulpi_stp US6 US5 usbk_ulpi_dir_&_nxt US7 US9 US8 usbk_ulpi_d[7:0] Data_IN US9 Data_OUT Figure 7-51. HS USB3 and USB4 ULPI —SDR—Slave Mode—12-pin Mode In Table 7-66 are presented the specific groupings of signals (IOSET) for use with USB3 and USB4 signals. Table 7-66. USB3 and USB4 IOSETs SIGNALS IOSET1 BALL IOSET2 MUX BALL MUX USB3 usb3_ulpi_d0 AE1 2 AC3 3 usb3_ulpi_d1 AE5 2 AC9 3 usb3_ulpi_d2 AE3 2 AC6 3 usb3_ulpi_d3 AF1 2 AC7 3 usb3_ulpi_d4 AF4 2 AC4 3 usb3_ulpi_d5 AF3 2 AD4 3 usb3_ulpi_d6 AF6 2 AB4 3 usb3_ulpi_d7 AF2 2 AC5 3 usb3_ulpi_nxt AE2 2 AC8 3 usb3_ulpi_dir AE6 2 AD6 3 usb3_ulpi_stp AD2 2 AB8 3 usb3_ulpi_clk AD3 2 AB5 3 usb4_ulpi_d0 V6 6 usb4_ulpi_d1 U6 6 usb4_ulpi_d2 U5 6 usb4_ulpi_d3 V5 6 USB4 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 299 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-66. USB3 and USB4 IOSETs (continued) SIGNALS IOSET1 BALL IOSET2 MUX BALL MUX usb4_ulpi_d4 V4 6 usb4_ulpi_d5 V3 6 usb4_ulpi_d6 Y2 6 usb4_ulpi_d7 W2 6 usb4_ulpi_stp V9 6 usb4_ulpi_clk W9 6 usb4_ulpi_dir V7 6 usb4_ulpi_nxt U7 6 7.19 Serial Advanced Technology Attachment (SATA) The SATA RX/TX PHY interface is compliant with the SATA standard v2.6 for a maximum data rate: • Gen2i, Gen2m, Gen2x: 3Gbps. • Gen1i, Gen1m, Gen1x: 1.5Gbps. NOTE For more information, see the SATA Controller section of the Device TRM. 7.20 Peripheral Component Interconnect Express (PCIe) The device supports connections to PCIe-compliant devices via the integrated PCIe master/slave bus interface. The PCIe module is comprised of a dual-mode PCIe core and a SerDes PHY. Each PCIe subsystem controller has support for PCIe Gen-II mode (5.0 Gbps /lane) and Gen-I mode (2.5 Gbps/lane) (Single Lane and Flexible dual lane configuration). The device PCIe supports the following features: • 16-bit operation @250 MHz on PIPE interface (per 16-bit lane) • Supports 2 ports x 1 lane or 1 port x 2 lanes configuration • Single virtual channel (VC0), single traffic class (TC0) • Single function in end-point mode • Automatic width and speed negotiation • Max payload: 128 byte outbound, 256 byte inbound • Automatic credit management • ECRC generation and checking • Configurable BAR filtering • Legacy interrupt reception (RC) and generation (EP) • MSI generation and reception • PCI Express Active State Power Management (ASPM) state L0s and L1 (with exceptions) • All PCI Device Power Management D-states with the exception of D3cold / L2 state The PCIe controller on this device conforms to the PCI Express Base 3.0 Specification, revision 1.0 and the PCI Local Bus Specification, revision 3.0. NOTE For more information, see the PCIe Controller section of the Device TRM. 7.21 Controller Area Network Interface (DCAN) 300 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 The device provides two DCAN interfaces for supporting distributed realtime control with a high level of security. The DCAN interfaces implement the following features: • Supports CAN protocol version 2.0 part A, B • Bit rates up to 1 MBit/s • 64 message objects • Individual identifier mask for each message object • Programmable FIFO mode for message objects • Programmable loop-back modes for self-test operation • Suspend mode for debug support • Software module reset • Automatic bus on after Bus-Off state by a programmable 32-bit timer • Direct access to Message RAM during test mode • CAN Rx/Tx pins are configurable as general-purpose IO pins • Two interrupt lines (plus additional parity-error interrupts line) • RAM initialization • DMA support NOTE For more information, see the DCAN section of the Device TRM. NOTE The Controller Area Network Interface x (x = 1 to 2) is also referred to as DCANx. Table 7-67, Table 7-68 and Figure 7-52 present timing and switching characteristics for DCANx Interface. Table 7-67. Timing Requirements for DCANx Receive(1) NO. 1 PARAMETER DESCRIPTION f(baud) Maximum programmable baud rate tw(DCANRX) Pulse duration, receive data bit (DCANx_RX) MIN NOM H - 15 MAX UNIT 1 Mbps H + 15 ns (1) H = period of baud rate, 1/programmed baud rate. Table 7-68. Switching Characteristics Over Recommended Operating Conditions for DCANx Transmit NO. 2 PARAMETER DESCRIPTION f(baud) Maximum programmable baud rate tw(DCANTX) Pulse duration, transmit data bit (DCANx_TX) MIN H - 15 (1) MAX UNIT 1 Mbps H + 15 ns (1) H = period of baud rate, 1/programmed baud rate. 1 DCANx_RX 2 DCANx_TX Figure 7-52. DCANx Timings 7.22 Ethernet Interface (GMAC_SW) Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 301 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com The three-port gigabit ethernet switch subsystem (GMAC_SW) provides ethernet packet communication and can be configured as an ethernet switch. It provides the Gigabit Media Independent Interface (G/MII) in MII mode, Reduced Gigabit Media Independent Interface (RGMII), Reduced Media Independent Interface (RMII), and the Management Data Input/Output (MDIO) for physical layer device (PHY) management. NOTE For more information, see the Ethernet Subsystem section of the Device TRM. NOTE The Gigabit, Reduced and Media Independent Interface n (n = 0 to 1) are also referred to as MIIn, RMIIn and RGMIIn CAUTION The IO timings provided in this section are only valid if signals within a single IOSET are used. The IOSETs are defined in the Table 7-73, Table 7-76, Table 7-81 and Table 7-88. CAUTION The IO Timings provided in this section are only valid for some GMAC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-69 and Figure 7-53 present timing requirements for MIIn in receive operation. 7.22.1 GMAC MII Timings Table 7-69. Timing Requirements for miin_rxclk - MII Operation NO. PARAMETER DESCRIPTION 1 tc(RX_CLK) Cycle time, miin_rxclk 2 3 4 tw(RX_CLKH) tw(RX_CLKL) tt(RX_CLK) Pulse duration, miin_rxclk high Pulse duration, miin_rxclk low Transition time, miin_rxclk SPEED MIN MAX 10 Mbps 400 100 Mbps 40 ns 10 Mbps 140 260 ns 100 Mbps 14 26 ns 10 Mbps 140 260 ns 100 Mbps 14 26 ns 10 Mbps 3 ns 100 Mbps 3 ns ns 4 1 2 UNIT 3 miin_rxclk 4 Figure 7-53. Clock Timing (GMAC Receive) - MIIn operation 302 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-70 and Figure 7-54 present timing requirements for MIIn in transmit operation. Table 7-70. Timing Requirements for miin_txclk - MII Operation NO. PARAMETER DESCRIPTION SPEED MIN 1 tc(TX_CLK) Cycle time, miin_txclk 10 Mbps 400 2 tw(TX_CLKH) Pulse duration, miin_txclk high 3 tw(TX_CLKL) Pulse duration, miin_txclk low 4 tt(TX_CLK) Transition time, miin_txclk MAX UNIT ns 100 Mbps 40 10 Mbps 140 260 ns ns 100 Mbps 14 26 ns 10 Mbps 140 260 ns 100 Mbps 14 26 ns 10 Mbps 3 ns 100 Mbps 3 ns 4 1 3 2 miin_txclk 4 Figure 7-54. Clock Timing (GMAC Transmit) - MIIn operation Table 7-71 and Figure 7-55 present timing requirements for GMAC MIIn Receive 10/100Mbit/s. Table 7-71. Timing Requirements for GMAC MIIn Receive 10/100 Mbit/s NO. PARAMETER DESCRIPTION MIN MAX UNIT tsu(RXD-RX_CLK) 1 tsu(RX_DV-RX_CLK) Setup time, receive selected signals valid before miin_rxclk 8 ns Hold time, receive selected signals valid after miin_rxclk 8 ns tsu(RX_ER-RX_CLK) th(RX_CLK-RXD) 2 th(RX_CLK-RX_DV) th(RX_CLK-RX_ER) 1 2 miin_rxclk (Input) miin_rxd3−miin_rxd0, miin_rxdv, miin_rxer (Inputs) Figure 7-55. GMAC Receive Interface Timing MIIn operation Table 7-72 and Figure 7-56 present timing requirements for GMAC MIIn Transmit 10/100Mbit/s. Table 7-72. Switching Characteristics Over Recommended Operating Conditions for GMAC MIIn Transmit 10/100 Mbits/s NO. 1 PARAMETER td(TX_CLK-TXD) td(TX_CLK-TX_EN) DESCRIPTION Delay time, miin_txclk to transmit selected signals valid MIN MAX UNIT 0 25 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 303 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 1 miin_txclk (input) miin_txd3 − miin_txd0, miin_txen (outputs) Figure 7-56. GMAC Transmit Interface Timing MIIn operation In Table 7-73 are presented the specific groupings of signals (IOSET) for use with GMAC MII signals. Table 7-73. GMAC MII IOSETs SIGNALS 304 IOSET5 IOSET6 BALL MUX mii1_txd3 C5 8 BALL MUX mii1_txd2 D6 8 mii1_txd1 B2 8 mii0_txd3 V5 3 mii0_txd2 V4 3 mii0_txd1 Y2 3 mii1_txd0 C4 8 mii1_rxd3 F5 8 mii1_rxd2 E4 8 mii1_rxd1 C1 8 mii1_rxd0 E6 8 mii1_col B4 8 mii1_rxer B3 8 mii1_txer A3 8 mii1_txen A4 8 mii1_crs B5 8 mii1_rxclk D5 8 mii1_txclk C3 8 mii1_rxdv C2 8 mii0_txd0 W2 3 mii0_rxd3 W9 3 mii0_rxd2 V9 3 mii0_rxd1 V6 3 mii0_rxd0 U6 3 mii0_txclk U5 3 mii0_txer U4 3 mii0_rxer U7 3 mii0_rxdv V2 3 mii0_crs V7 3 mii0_col V1 3 mii0_rxclk Y1 3 mii0_txen V3 3 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 7.22.2 GMAC MDIO Interface Timings CAUTION The IO Timings provided in this section are only valid for some GMAC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-74, Table 7-74 and Figure 7-57 present timing requirements for MDIO. Table 7-74. Timing Requirements for MDIO Input No PARAMETER MDIO1 tc(MDC) MDIO2 MDIO3 MDIO4 MDIO5 DESCRIPTION MIN MAX UNIT Cycle time, MDC 400 ns tw(MDCH) Pulse Duration, MDC High 160 ns tw(MDCL) Pulse Duration, MDC Low 160 ns tsu(MDIO-MDC) Setup time, MDIO valid before MDC High 90 ns th(MDIO_MDC) Hold time, MDIO valid from MDC High 0 ns Table 7-75. Switching Characteristics Over Recommended Operating Conditions for MDIO Output NO PARAMETER DESCRIPTION MDIO6 tt(MDC) Transition time, MDC MDIO7 td(MDC-MDIO) Delay time, MDC High to MDIO valid MIN MAX UNIT 5 ns 10 390 ns 1 MDIO2 MDIO3 MDCLK MDIO6 MDIO6 MDIO4 MDIO5 MDIO (input) MDIO7 MDIO (output) Figure 7-57. GMAC MDIO diagrams In Table 7-76 are presented the specific groupings of signals (IOSET) for use with GMAC MDIO signals. Table 7-76. GMAC MDIO IOSETs SIGNALS IOSET7 IOSET8 IOSET9 IOSET10 BALL MUX BALL MUX BALL MUX BALL MUX mdio_d F6 3 U4 0 AB4 1 B20 5 mdio_mclk D3 3 V1 0 AC5 1 B21 5 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 305 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 7.22.3 GMAC RMII Timings The main reference clock REF_CLK (RMII_50MHZ_CLK) of RMII interface is internally supplied from PRCM. The source of this clock could be either externally sourced from the RMII_MHZ_50_CLK pin of the device or internally generated from DPLL_GMAC output clock GMAC_RMII_HS_CLK. Please see the PRCM chapter of the device TRM for full details about RMII reference clock. CAUTION The IO Timings provided in this section are only valid for some GMAC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-77, Table 7-78 and Figure 7-58 present timing requirements for GMAC RMIIn Receive. Table 7-77. Timing Requirements for GMAC REF_CLK - RMII Operation NO. PARAMETER DESCRIPTION MIN MAX UNIT RMII1 tc(REF_CLK) Cycle time, REF_CLK 20 ns RMII2 tw(REF_CLKH) Pulse duration, REF_CLK high 7 13 ns RMII3 tw(REF_CLKL) Pulse duration, REF_CLK low 7 13 ns RMII4 ttt(REF_CLK) Transistion time, REF_CLK 3 ns Table 7-78. Timing Requirements for GMAC RMIIn Receive NO. PARAMETER DESCRIPTION MIN MAX UNIT RMII5 tsu(RXD-REF_CLK) Setup time, receive selected signals valid before REF_CLK 4 ns Hold time, receive selected signals valid after REF_CLK 2 ns tsu(CRS_DV-REF_CLK) tsu(RX_ER-REF_CLK) RMII6 th(REF_CLK-RXD) th(REF_CLK-CRS_DV) th(REF_CLK-RX_ER) RMII1 RMII3 RMII4 RMII2 RMII5 RMII6 REF_CLK (PRCM) rmiin_rxd1−rmiin_rxd0, rmiin_crs, rmin_rxer (inputs) SPRS8xx_GMAC_RMIIRX_05 Figure 7-58. GMAC Receive Interface Timing RMIIn operation Table 7-79, Table 7-79 and Figure 7-59 present switching characteristics for GMAC RMIIn Transmit 10/100Mbit/s. Table 7-79. Switching Characteristics Over Recommended Operating Conditions for GMAC REF_CLK RMII Operation NO. PARAMETER DESCRIPTION MIN RMII7 tc(REF_CLK) Cycle time, REF_CLK 20 RMII8 tw(REF_CLKH) Pulse duration, REF_CLK high 7 306 MAX UNIT ns 13 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-79. Switching Characteristics Over Recommended Operating Conditions for GMAC REF_CLK RMII Operation (continued) NO. PARAMETER DESCRIPTION RMII9 tw(REF_CLKL) Pulse duration, REF_CLK low RMII10 tt(REF_CLK) Transistion time, REF_CLK MIN MAX UNIT 7 13 ns 3 ns Table 7-80. Switching Characteristics Over Recommended Operating Conditions for GMAC RMIIn Transmit 10/100 Mbits/s NO. PARAMETER DESCRIPTION td(REF_CLK-TXD) RMII11 tdd(REF_CLK-TXEN) td(REF_CLK-TXD) RMIIn MIN MAX UNIT RMII0 2 13.5 ns RMII1 2 13.8 ns Delay time, REF_CLK high to selected transmit signals valid tdd(REF_CLK-TXEN) RMII7 RMII8 RMII9 RMII11 RMII10 REF_CLK (PRCM) rmiin_txd1−rmiin_txd0, rmiin_txen (Outputs) SPRS8xx_GMAC_RMIITX_06 Figure 7-59. GMAC Transmit Interface Timing RMIIn Operation In Table 7-81 are presented the specific groupings of signals (IOSET) for use with GMAC RMII signals. Table 7-81. GMAC RMII IOSETs SIGNALS IOSET1 IOSET2 BALL MUX BALL MUX RMII_MHZ_50_CLK U3 0 U3 0 rmii1_txd1 V5 2 rmii0_txd1 Y2 1 rmii0_txd0 W2 1 rmii0_rxd1 V6 1 rmii0_rxd0 U6 1 rmii0_txen V3 1 rmii0_rxer U7 1 rmii0_crs V7 1 rmii1_txd0 V4 2 rmii1_rxd1 W9 2 rmii1_rxd0 V9 2 rmii1_rxer Y1 2 rmii1_txen U5 2 rmii1_crs V2 2 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 307 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Manual IO Timings Modes must be used to guarantee some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-82 Manual Functions Mapping for GMAC RMII0 for a definition of the Manual modes. Table 7-82 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-82. Manual Functions Mapping for GMAC RMII0 BALL BALL NAME GMAC_RMII0_MANUAL1 A_DELAY (ps) CFG REGISTER MUXMODE G_DELAY (ps) 0 1 U3 RMII_MHZ_50_CLK 0 0 CFG_RMII_MHZ_50_CLK_IN U6 rgmii0_txd0 500 500 CFG_RGMII0_TXD0_IN RMII_MHZ_50_CLK rmii0_rxd0 V6 rgmii0_txd1 840 1000 CFG_RGMII0_TXD1_IN rmii0_rxd1 U7 rgmii0_txd2 360 840 CFG_RGMII0_TXD2_IN rmii0_rxer V7 rgmii0_txd3 600 1000 CFG_RGMII0_TXD3_IN rmii0_crs Manual IO Timings Modes must be used to guarantee some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-83 Manual Functions Mapping for GMAC RMII1 for a definition of the Manual modes. Table 7-83 list the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-83. Manual Functions Mapping for GMAC RMII1 BALL BALL NAME GMAC_RMII1_MANUAL1 A_DELAY (ps) CFG REGISTER MUXMODE G_DELAY (ps) 0 2 U3 RMII_MHZ_50_CLK 0 0 CFG_RMII_MHZ_50_CLK_IN V9 rgmii0_txctl 300 1200 CFG_RGMII0_TXCTL_IN RMII_MHZ_50_CLK rmii1_rxd0 W9 rgmii0_txc 300 1000 CFG_RGMII0_TXC_IN rmii1_rxd1 Y1 uart3_txd 400 700 CFG_UART3_TXD_IN rmii1_rxer V2 uart3_rxd 300 500 CFG_UART3_RXD_IN rmii1_crs 7.22.4 GMAC RGMII Timings CAUTION The IO Timings provided in this section are only valid for some GMAC usage modes when the corresponding Virtual IO Timings or Manual IO Timings are configured as described in the tables found in this section. Table 7-84, Table 7-85 and Figure 7-60 present timing requirements for receive RGMIIn operation. Table 7-84. Timing Requirements for rgmiin_rxc - RGMIIn Operation NO. 1 2 308 PARAMETER DESCRIPTION SPEED MIN MAX UNIT tc(RXC) Cycle time, rgmiin_rxc 10 Mbps 360 440 ns 100 Mbps 36 44 ns tw(RXCH) Pulse duration, rgmiin_rxc high 1000 Mbps 7.2 8.8 ns 10 Mbps 160 240 ns 100 Mbps 16 24 ns 1000 Mbps 3.6 4.4 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-84. Timing Requirements for rgmiin_rxc - RGMIIn Operation (continued) NO. 3 4 PARAMETER DESCRIPTION SPEED MIN MAX UNIT tw(RXCL) Pulse duration, rgmiin_rxc low 10 Mbps 160 240 ns tt(RXC) Transition time, rgmiin_rxc 100 Mbps 16 24 ns 1000 Mbps 3.6 4.4 ns 10 Mbps 0.75 ns 100 Mbps 0.75 ns 1000 Mbps 0.75 ns Table 7-85. Timing Requirements for GMAC RGMIIn Input Receive for 10/100/1000 Mbps NO. PARAMETER DESCRIPTION MIN MAX UNIT 5 tsu(RXD-RXCH) Setup time, receive selected signals valid before rgmiin_rxc high/low 1 ns 6 th(RXCH-RXD) Hold time, receive selected signals valid after rgmiin_rxc high/low 1 ns (1) For RGMII, receive selected signals include: rgmiin_rxd[3:0] and rgmiin_rxctl. 1 4 2 rgmiin_rxc 4 3 (A) 5 1st Half-byte 6 2nd Half-byte rgmiin_rxd[3:0] rgmiin_rxctl A. B. (B) RGRXD[3:0] RGRXD[7:4] RXDV RXERR (B) rgmiin_rxc must be externally delayed relative to the data and control pins. Data and control information is received using both edges of the clocks. rgmiin_rxd[3:0] carries data bits 3-0 on the rising edge of rgmiin_rxc and data bits 7-4 on the falling edge ofrgmiin_rxc. Similarly, rgmiin_rxctl carries RXDV on rising edge of rgmiin_rxc and RXERR on falling edge of rgmiin_rxc. Figure 7-60. GMAC Receive Interface Timing, RGMIIn operation Table 7-86, Table 7-87 and Figure 7-61 present switching characteristics for transmit - RGMIIn for 10/100/1000Mbit/s. Table 7-86. Switching Characteristics Over Recommended Operating Conditions for rgmiin_txctl - RGMIIn Operation for 10/100/1000 Mbit/s NO. 1 2 3 4 PARAMETER DESCRIPTION SPEED MIN MAX UNIT tc(TXC) Cycle time, rgmiin_txc 10 Mbps 360 440 ns 100 Mbps 36 44 ns tw(TXCH) tw(TXCL) tt(TXC) Pulse duration, rgmiin_txc high Pulse duration, rgmiin_txc low Transition time, rgmiin_txc 1000 Mbps 7.2 8.8 ns 10 Mbps 160 240 ns 100 Mbps 16 24 ns 1000 Mbps 3.6 4.4 ns 10 Mbps 160 240 ns 100 Mbps 16 24 ns 1000 Mbps 3.6 4.4 ns 10 Mbps 0.75 ns 100 Mbps 0.75 ns 1000 Mbps 0.75 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 309 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-87. Switching Characteristics for GMAC RGMIIn Output Transmit for 10/100/1000 Mbps NO. 5 6 PARAMETER DESCRIPTION tosu(TXD-TXC) Output Setup time, transmit selected signals valid to rgmiin_txc high/low toh(TXC-TXD) Output Hold time, transmit selected signals valid after rgmiin_txc high/low (1) MODE MIN RGMII0, Internal Delay Enabled, 1000 Mbps 1.05 MAX UNIT ns RGMII0, Internal Delay Enabled, 10/100 Mbps 1.2 ns RGMII1, Internal Delay Enabled, 1000 Mbps 1.05 ns RGMII1, Internal Delay Enabled, 10/100 Mbps 1.2 ns RGMII0, Internal Delay Enabled, 1000 Mbps 1.05 ns RGMII0, Internal Delay Enabled, 10/100 Mbps 1.2 ns RGMII1, Internal Delay Enabled, 1000 Mbps 1.05 ns RGMII1, Internal Delay Enabled, 10/100 Mbps 1.2 ns (2) (3) (2) (3) (1) For RGMII, transmit selected signals include: rgmiin_txd[3:0] and rgmiin_txctl. (2) RGMII0 1000Mbps operation requires that the rgmii0_txc and rgmii0_txd[3:0] board propogation delays be matched to < 50pS. (3) RGMII1 1000Mbps operation requires that the rgmii1_txc and rgmii1_txd[3:0] board propogation delays be matched to < 50pS. 1 4 2 3 4 (A) rgmiin_txc [internal delay enabled] 5 (B) 1st Half-byte rgmiin_txd[3:0] 2nd Half-byte 6 (B) rgmiin_txctl A. B. TXEN TXERR TXC is delayed internally before being driven to the rgmiin_txc pin. This internal delay is always enabled. Data and control information is transmitted using both edges of the clocks. rgmiin_txd[3:0] carries data bits 3-0 on the rising edge of rgmiin_txc and data bits 7-4 on the falling edge of rgmiin_txc. Similarly, rgmiin_txctl carries TXEN on rising edge of rgmiin_txc and TXERR of falling edge of rgmiin_txc. Figure 7-61. GMAC Transmit Interface Timing RGMIIn operation In Table 7-88 are presented the specific groupings of signals (IOSET) for use with GMAC RGMII signals. Table 7-88. GMAC RGMII IOSETs SIGNALS 310 IOSET3 IOSET4 BALL MUX rgmii1_txd3 C3 3 rgmii1_txd2 C4 3 rgmii1_txd1 B2 3 rgmii1_txd0 D6 3 rgmii1_rxd3 B3 3 rgmii1_rxd2 B4 3 rgmii1_rxd1 B5 3 rgmii1_rxd0 A4 3 rgmii1_rxctl A3 3 rgmii1_txc D5 3 BALL MUX Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-88. GMAC RGMII IOSETs (continued) SIGNALS IOSET3 IOSET4 BALL MUX BALL MUX rgmii1_txctl C2 3 rgmii1_rxc C5 rgmii0_txd3 3 V7 0 rgmii0_txd2 U7 0 rgmii0_txd1 V6 0 rgmii0_txd0 U6 0 rgmii0_rxd3 V4 0 rgmii0_rxd2 V3 0 rgmii0_rxd1 Y2 0 rgmii0_rxd0 W2 0 rgmii0_txc W9 0 rgmii0_rxctl V5 0 rgmii0_rxc U5 0 rgmii0_txctl V9 0 NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-89 Manual Functions Mapping for GMAC RGMII0 for a definition of the Manual modes. Table 7-90 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-89. Manual Functions Mapping for GMAC RGMII0 BALL BALL NAME GMAC_RGMII0_MANUAL1 CFG REGISTER MUXMODE A_DELAY (ps) G_DELAY (ps) U5 rgmii0_rxc 471 0 CFG_RGMII0_RXC_IN rgmii0_rxc 0 V5 rgmii0_rxctl 30 1919 CFG_RGMII0_RXCTL_IN rgmii0_rxctl W2 rgmii0_rxd0 74 1688 CFG_RGMII0_RXD0_IN rgmii0_rxd0 Y2 rgmii0_rxd1 94 1697 CFG_RGMII0_RXD1_IN rgmii0_rxd1 V3 rgmii0_rxd2 0 1703 CFG_RGMII0_RXD2_IN rgmii0_rxd2 V4 rgmii0_rxd3 70 1804 CFG_RGMII0_RXD3_IN rgmii0_rxd3 W9 rgmii0_txc 90 70 CFG_RGMII0_TXC_OUT rgmii0_txc V9 rgmii0_txctl 70 70 CFG_RGMII0_TXCTL_OUT rgmii0_txctl U6 rgmii0_txd0 180 70 CFG_RGMII0_TXD0_OUT rgmii0_txd0 V6 rgmii0_txd1 35 70 CFG_RGMII0_TXD1_OUT rgmii0_txd1 U7 rgmii0_txd2 0 0 CFG_RGMII0_TXD2_OUT rgmii0_txd2 V7 rgmii0_txd3 180 70 CFG_RGMII0_TXD3_OUT rgmii0_txd3 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 311 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Manual IO Timings Modes must be used to guarantee some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-90 Manual Functions Mapping for GMAC RGMII1 for a definition of the Manual modes. Table 7-90 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-90. Manual Functions Mapping for GMAC RGMII1 BALL BALL NAME GMAC_RGMII1_MANUAL1 A_DELAY (ps) CFG REGISTER MUXMODE G_DELAY (ps) 3 C5 vin2a_d18 612 0 CFG_VIN2A_D18_IN rgmii1_rxc A3 vin2a_d19 4 927 CFG_VIN2A_D19_IN rgmii1_rxctl B3 vin2a_d20 136 1340 CFG_VIN2A_D20_IN rgmii1_rxd3 B4 vin2a_d21 130 1450 CFG_VIN2A_D21_IN rgmii1_rxd2 B5 vin2a_d22 144 1269 CFG_VIN2A_D22_IN rgmii1_rxd1 A4 vin2a_d23 0 1330 CFG_VIN2A_D23_IN rgmii1_rxd0 D5 vin2a_d12 65 70 CFG_VIN2A_D12_OUT rgmii1_txc C2 vin2a_d13 125 70 CFG_VIN2A_D13_OUT rgmii1_txctl C3 vin2a_d14 0 70 CFG_VIN2A_D14_OUT rgmii1_txd3 C4 vin2a_d15 0 70 CFG_VIN2A_D15_OUT rgmii1_txd2 B2 vin2a_d16 65 70 CFG_VIN2A_D16_OUT rgmii1_txd1 D6 vin2a_d17 0 0 CFG_VIN2A_D17_OUT rgmii1_txd0 7.23 Media Local Bus (MLB) interface The MLBSS allows connection to a MOST (Media Oriented Systems Transport) network controller for transport of media and control data between multimedia nodes. The MLBSS supports the following features: • 3 pin mode compliant to MediaLB Physical Layer Specification v4.0 • 6 pin mode (3 differential pairs) compliant to MediaLB Physical Layer Specification v4.0 • Supports 256/512/1024Fs in 3 pin mode and 2048Fs in 6 pin mode • Supports all types of transfer (Sync, Isoc, Async/Packet, Control) over 64 logical channels • 16KB buffering for synchronous /isochronous/control/packet data in the subsystem NOTE For more information, see the Media Local Bus (MLB) section of the Device TRM. NOTE MLB in 6-pin mode may require pullups/ pulldowns on SIG and DAT bus signals. For additional details, please consult the MLB bus interface specification. Table 7-91 and Figure 7-62 present Timing Requirements for MLKCLK 3-Pin Option. Table 7-91. Timing Requirements for MLBCLK 3-Pin Option NO. PARAMETER DESCRIPTION MODE MIN 1 tc(MLBCLK) Cycle time, MLB_CLK 512FS 39 ns 1024FS 19.5 ns 512FS 14 ns 1024FS 9.3 ns 2 312 tw(MLBCLK) Pulse duration, MLB_CLK high MAX UNIT Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-91. Timing Requirements for MLBCLK 3-Pin Option (continued) NO. PARAMETER DESCRIPTION MODE MIN 3 tw(MLBCLK) Pulse duration, MLB_CLK low 512FS 14 MAX UNIT ns 1024FS 6.1 ns 2 4 1 MLB_CLK 3 4 Figure 7-62. MLB_CLK Timing Table 7-92 and Table 7-93 present Timing Requirements and Switching Characteristics for MLB 3-Pin Option. Table 7-92. Timing Requirements for Receive Data for the MLB 3-Pin Option NO. PARAMETER DESCRIPTION MODE MIN 5 tsu(MLBDAT-MLBCLKL) Setup time, MLB_DAT/MLB_SIG input valid before MLB_CLK low 512FS 1 ns 1024FS 1 ns 512FS 4 ns 1024FS 2 ns 6 th(MLBCLKL-MLBDAT) Hold time, MLB_DAT/MLB_SIG input valid after MLB_CLK low MAX UNIT Table 7-93. Switching Characteristics Over Recommended Operating Conditions for MLB 3-Pin Option NO. PARAMETER DESCRIPTION MODE MIN MAX UNIT 7 td(MLBCLKH-MLBDATV) Delay time, MLBCLKH rising to MLB_DAT/MLB_SIG valid 512FS 0 10 ns 1024FS 0 7 ns 512FS 0 14 ns 1024FS 0 6.1 ns MIN MAX UNIT 8 tdis(MLBCLKL- Disable time, MLBCLKH falling to MLB_DAT/MLB_SIG Hi-Z MLBDATZ) Table 7-94 and Figure 7-62 present Timing Requirements for MLKCLK 6-Pin Option. Table 7-94. Timing Requirements for MLBCLK 6-Pin Option NO. PARAMETER DESCRIPTION MODE 1 tc(MLBCLKx) Cycle time, MLB_CLKP/N 2048FS 10 ns 2 tw(MLBCLKx) Pulse duration, MLB_CLKP/N high 2048FS 4.5 ns 3 tw(MLBCLKx) Pulse duration, MLB_CLKP/N low 2048FS 4.5 ns Table 7-95 and Table 7-96 present Timing Requirements and Switching Characteristics for MLB 6-Pin Option. Table 7-95. Timing Requirements for Receive Data for the MLB 6-Pin Option (1) NO. PARAMETER DESCRIPTION MODE MIN 5 tsu(DATx-CLKxH) Setup time, MLBP_DATx/MLBP_SIGx input valid before MLBP_CLKx rising 2048FS 1 MAX ns 6 th(CLKxH-DATx) Hold time, MLBP_DATx/MLBP_SIGx input valid after MLBP_CLKx rising 2048FS 0.5 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated UNIT 313 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) MLBP_SIGx/MLBP_DATx is valid at the receiver input for at least TBD. Table 7-96. Switching Characteristics Over Recommended Operating Conditions for MLB 6-Pin Option (1) NO. PARAMETER DESCRIPTION MODE MIN MAX UNIT 7 td(CLKxH-DATxV) Delay time, MLBPCLKxH rising to MLB_DATx/MLB_SIGx valid 2048FS 0.5 7 ns 8 tdis(CLKPH-DATPZ) Disable time, MLBPCLKxH rising to MLBP_DATx/MLBP_SIGx Hi-Z 2048FS 0.5 7 ns (1) MLBP_SIGx/MLBP_DATx is valid at the receiver input for at least TBD. NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for MLB. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-97 Manual Functions Mapping for MLB for a definition of the Manual modes. Table 7-97 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-97. Manual Functions Mapping for MLB BALL BALL NAME A_DELAY (ps) G_DELAY (ps) 0 5 AA3 mcasp5_aclkx 175 0 CFG_MCASP5_ACLKX_IN - mlb_clk AA3 mcasp5_aclkx 430 411 CFG_MCASP5_ACLKX_OUT - mlb_clk AB3 mcasp5_axr0 0 0 CFG_MCASP5_AXR0_IN - mlb_sig AB3 mcasp5_axr0 0 0 CFG_MCASP5_AXR0_OEN - mlb_sig AB3 mcasp5_axr0 0 0 CFG_MCASP5_AXR0_OUT - mlb_sig AA4 mcasp5_axr1 0 0 CFG_MCASP5_AXR1_IN - mlb_dat AA4 mcasp5_axr1 0 0 CFG_MCASP5_AXR1_OEN - mlb_dat AA4 mcasp5_axr1 0 0 CFG_MCASP5_AXR1_OUT - mlb_dat AB1 mlbp_clk_p 0 0 CFG_MLBP_CLK_P_IN mlbp_clk_p - AB1 mlbp_clk_p 321 43 CFG_MLBP_CLK_P_OUT mlbp_clk_p - AA2 mlbp_dat_n 30 1170 CFG_MLBP_DAT_N_IN mlbp_dat_n - AA2 mlbp_dat_n 0 0 CFG_MLBP_DAT_N_OEN mlbp_dat_n - AA2 mlbp_dat_n 0 0 CFG_MLBP_DAT_N_OUT mlbp_dat_n - AA1 mlbp_dat_p 30 1170 CFG_MLBP_DAT_P_IN mlbp_dat_p - AA1 mlbp_dat_p 0 0 CFG_MLBP_DAT_P_OEN mlbp_dat_p - AA1 mlbp_dat_p 0 0 CFG_MLBP_DAT_P_OUT mlbp_dat_p - AC2 mlbp_sig_n 55 1223 CFG_MLBP_SIG_N_IN mlbp_sig_n - AC2 mlbp_sig_n 0 0 CFG_MLBP_SIG_N_OEN mlbp_sig_n - AC2 mlbp_sig_n 0 0 CFG_MLBP_SIG_N_OUT mlbp_sig_n - AC1 mlbp_sig_p 55 1223 CFG_MLBP_SIG_P_IN mlbp_sig_p - AC1 mlbp_sig_p 0 0 CFG_MLBP_SIG_P_OEN mlbp_sig_p - AC1 mlbp_sig_p 0 0 CFG_MLBP_SIG_P_OUT mlbp_sig_p - 314 MLB_MANUAL 1 CFG REGISTER MUXMODE Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 7.24 eMMC/SD/SDIO The Device includes the following external memory interfaces 4 MultiMedia Card/Secure Digital/Secure Digital Input Output Interface (MMC/SD/SDIO). NOTE The eMMC/SD/SDIOi (i = 1 to 4) controller is also referred to as MMCi. 7.24.1 MMC1—SD Card Interface MMC1 interface is compliant with the SD Standard v3.01 and it supports the following SD Card applications: • Default speed, 4-bit data, SDR, half-cycle • High speed, 4-bit data, SDR, half-cycle • SDR12, 4-bit data, half-cycle • SDR25, 4-bit data, half-cycle • UHS-I SDR50, 4-bit data, half-cycle • UHS-I SDR104, 4-bit data, half-cycle • UHS-I DDR50, 4-bit data NOTE For more information, see the eMMC/SD/SDIO chapter of the Device TRM. 7.24.1.1 Default speed, 4-bit data, SDR, half-cycle Table 7-98 and Table 7-99 present Timing requirements and Switching characteristics for MMC1 - Default Speed in receiver and transmitter mode (see Figure 7-63 and Figure 7-64) Table 7-98. Timing Requirements for MMC1 - SD Card Default Speed Mode PARAMETER DESCRIPTION DSSD5 NO. tsu(cmdV-clkH) Setup time, mmc1_cmd valid before mmc1_clk rising clock edge DSSD6 th(clkH-cmdV) Hold time, mmc1_cmd valid after mmc1_clk rising clock edge DSSD7 tsu(dV-clkH) Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge DSSD8 th(clkH-dV) Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge MIN MAX UNIT 25.83 ns 20.9 ns 25.83 ns 20.9 ns Table 7-99. Switching Characteristics for MMC1 - SD Card Default Speed Mode PARAMETER DESCRIPTION DSSD0 NO. fop(clk) Operating frequency, mmc1_clk MIN MAX UNIT 24 DSSD1 tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) MHz ns DSSD2 tw(clkL) Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns DSSD3 td(clkL-cmdV) Delay time, mmc1_clk falling clock edge to mmc1_cmd transition -14.93 14.93 ns DSSD4 td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition -14.93 14.93 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 315 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output mmc1_clk period in ns DSSD2 DSSD1 DSSD0 mmc1_clk DSSD6 DSSD5 mmc1_cmd DSSD8 DSSD7 mmc1_dat[3:0] MMC1_01 Figure 7-63. MMC/SD/SDIO in - Default Speed - Receiver Mode DSSD2 DSSD1 DSSD0 mmcx_clk DSSD3 mmcx_cmd DSSD4 mmcx_dat[3:0] MMC1_02 Figure 7-64. MMC/SD/SDIO in - Default Speed - Transmitter Mode 7.24.1.2 High speed, 4-bit data, SDR, half-cycle Table 7-100 and Table 7-101 present Timing requirements and Switching characteristics for MMC1 - High Speed in receiver and transmitter mode (see Figure 7-65 and Figure 7-66) Table 7-100. Timing Requirements for MMC1 - SD Card High Speed PARAMETER DESCRIPTION MIN HSSD3 NO. tsu(cmdV-clkH) Setup time, mmc1_cmd valid before mmc1_clk rising clock edge 6.64 MAX UNIT ns HSSD4 th(clkH-cmdV) Hold time, mmc1_cmd valid after mmc1_clk rising clock edge 2.6 ns HSSD7 tsu(dV-clkH) Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge 6.64 ns HSSD8 th(clkH-dV) Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge 2.6 ns Table 7-101. Switching Characteristics for MMC1 - SD Card High Speed NO. HSSD1 PARAMETER DESCRIPTION fop(clk) Operating frequency, mmc1_clk MIN MAX UNIT 48 MHz HSSD2H tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns HSSD2L tw(clkL) Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns HSSD5 td(clkL-cmdV) Delay time, mmc1_clk falling clock edge to mmc1_cmd transition -7.6 3.6 ns HSSD6 td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition -7.6 3.6 ns 316 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) P = output mmc1_clk period in ns HSSD1 HSSD2L HSSD2H mmc1_clk HSSD3 HSSD4 mmc1_cmd HSSD7 HSSD8 mmc1_dat[3:0] MMC1_03 Figure 7-65. MMC/SD/SDIO in - High Speed - Receiver Mode HSSD1 HSSD2H HSSD2L mmc1_clk HSSD5 HSSD5 mmc1_cmd HSSD6 HSSD6 mmc1_dat[3:0] MMC1_04 Figure 7-66. MMC/SD/SDIO in - High Speed - Transmitter Mode 7.24.1.3 SDR12, 4-bit data, half-cycle Table 7-102 and Table 7-103 present Timing requirements and Switching characteristics for MMC1 SDR12 in receiver and transmitter mode(see Figure 7-67 and Figure 7-68). Table 7-102. Timing Requirements for MMC1 - SD Card SDR12 Mode NO. PARAMETER DESCRIPTION SDR12 tsu(cmdV-clkH) 5 Setup time, mmc1_cmd valid before mmc1_clk rising clock edge SDR12 th(clkH-cmdV) 6 Hold time, mmc1_cmd valid after mmc1_clk rising clock edge SDR12 tsu(dV-clkH) 7 Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge SDR12 th(clkH-dV) 8 Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge MODE MIN MAX UNIT 27.33 ns Pad Loopback Clock 1.6 ns Internal Loopback Clock 1.6 ns 27.33 ns Pad Loopback Clock 1.6 ns Internal Loopback Clock 1.6 ns Table 7-103. Switching Characteristics for MMC1 - SD Card SDR12 Mode PARAMETER DESCRIPTION SDR120 NO. fop(clk) Operating frequency, mmc1_clk MIN MAX UNIT 24 MHz SDR121 tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns SDR122 tw(clkL) Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns SDR123 td(clkL-cmdV) Delay time, mmc1_clk falling clock edge to mmc1_cmd transition -19.13 16.93 ns SDR124 td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition -19.13 16.93 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 317 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output mmc1_clk period in ns SDR122 SDR121 SDR120 mmc1_clk SDR126 SDR125 mmc1_cmd SDR128 SDR127 mmc1_dat[3:0] MMC1_05 Figure 7-67. MMC/SD/SDIO in - High Speed SDR12 - Receiver Mode SDR122 SDR121 SDR120 mmc1_clk SDR123 mmc1_cmd SDR124 mmc1_dat[3:0] MMC1_06 Figure 7-68. MMC/SD/SDIO in - High Speed SDR12 - Transmitter Mode 7.24.1.4 SDR25, 4-bit data, half-cycle Table 7-104 and Table 7-105 present Timing requirements and Switching characteristics for MMC1 SDR25 in receiver and transmitter mode (see Figure 7-69 and Figure 7-70). Table 7-104. Timing Requirements for MMC1 - SD Card SDR25 Mode NO. PARAMETER DESCRIPTION SDR25 tsu(cmdV-clkH) 3 Setup time, mmc1_cmd valid before mmc1_clk rising clock edge SDR25 th(clkH-cmdV) 4 MODE MIN MAX UNIT 6.64 ns Hold time, mmc1_cmd valid after mmc1_clk rising clock edge 1.6 ns SDR25 tsu(dV-clkH) 7 Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge 6.64 ns SDR25 th(clkH-dV) 8 Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge Pad Loopback Clock 1.6 ns Internal Loopback Clock 1.6 ns Table 7-105. Switching Characteristics for MMC1 - SD Card SDR25 Mode PARAMETER DESCRIPTION SDR251 NO. fop(clk) Operating frequency, mmc1_clk SDR252 H tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns SDR252L tw(clkL) 318 MIN MAX UNIT 48 MHz Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-105. Switching Characteristics for MMC1 - SD Card SDR25 Mode (continued) PARAMETER DESCRIPTION MIN MAX SDR255 NO. td(clkL-cmdV) Delay time, mmc1_clk falling clock edge to mmc1_cmd transition -8.8 6.6 UNIT ns SDR256 td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition -8.8 6.6 ns (1) P = output mmc1_clk period in ns SDR251 SDR252L SDR252H mmc1_clk SDR253 SDR254 mmc1_cmd SDR257 SDR258 mmc1_dat[3:0] MMC1_07 Figure 7-69. MMC/SD/SDIO in - High Speed SDR25 - Receiver Mode SDR251 SDR252H SDR252L mmc1_clk HSSDR255 SDR255 mmc1_cmd SDR256 SDR256 mmc1_dat[3:0] MMC1_08 Figure 7-70. MMC/SD/SDIO in - High Speed SDR25 - Transmitter Mode 7.24.1.5 UHS-I SDR50, 4-bit data, half-cycle Table 7-106 and Table 7-107 present Timing requirements and Switching characteristics for MMC1 SDR50 in receiver and transmitter mode (see Figure 7-71 and Figure 7-72). Table 7-106. Timing Requirements for MMC1 - SD Card SDR50 Mode NO. PARAMETER DESCRIPTION SDR50 tsu(cmdV-clkH) 3 Setup time, mmc1_cmd valid before mmc1_clk rising clock edge SDR50 th(clkH-cmdV) 4 MODE MIN MAX UNIT 2.82 ns Hold time, mmc1_cmd valid after mmc1_clk rising clock edge 1.6 ns SDR50 tsu(dV-clkH) 7 Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge 2.82 ns SDR50 th(clkH-dV) 8 Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge Pad Loopback Clock 1.6 ns Internal Loopback Clock 1.6 ns Table 7-107. Switching Characteristics for MMC1 - SD Card SDR50 Mode PARAMETER DESCRIPTION SDR501 NO. fop(clk) Operating frequency, mmc1_clk SDR502 H tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns SDR502L tw(clkL) Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns SDR505 Delay time, mmc1_clk falling clock edge to mmc1_cmd transition td(clkL-cmdV) MIN -8.8 MAX UNIT 96 MHz 6.6 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated ns 319 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-107. Switching Characteristics for MMC1 - SD Card SDR50 Mode (continued) NO. SDR506 PARAMETER DESCRIPTION td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition MIN MAX UNIT -3.66 1.46 ns (1) P = output mmc1_clk period in ns SDR501 SDR502L SDR502H mmc1_clk SDR503 SDR504 mmc1_cmd SDR507 SDR508 mmc1_dat[3:0] MMC1_09 Figure 7-71. MMC/SD/SDIO in - High Speed SDR50 - Receiver Mode SDR501 SDR502H SDR502L mmc1_clk SDR505 SDR505 mmc1_cmd SDR506 SDR506 mmc1_dat[3:0] MMC1_10 Figure 7-72. MMC/SD/SDIO in - High Speed SDR50 - Transmitter Mode 7.24.1.6 UHS-I SDR104, 4-bit data, half-cycle Table 7-108 presents Timing requirements and Switching characteristics for MMC1 - SDR104 in receiver and transmitter mode (see Figure 7-73 and Figure 7-74) Table 7-108. Switching Characteristics for MMC1 - SD Card SDR104 Mode NO. PARAMETER DESCRIPTION MIN MAX UNIT 192 MHz SDR1041 fop(clk) Operating frequency, mmc1_clk SDR1042 tw(clkH) H Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns SDR1042 tw(clkL) L Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns SDR1045 td(clkL-cmdV) Delay time, mmc1_clk falling clock edge to mmc1_cmd transition -1.09 0.49 ns SDR1046 td(clkL-dV) Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition -1.09 0.49 ns 320 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) P = output mmc1_clk period in ns SDR1041 SDR1042L SDR1042H mmc1_clk SDR1043 SDR1044 mmc1_cmd SDR1047 SDR1048 mmc1_dat[3:0] MMC1_11 Figure 7-73. MMC/SD/SDIO in - High Speed SDR104 - Receiver Mode SDR1041 SDR1042H SDR1042L mmc1_clk SDR1045 SDR1045 mmc1_cmd SDR1046 SDR1046 mmc1_dat[3:0] MMC1_12 Figure 7-74. MMC/SD/SDIO in - High Speed SDR104 - Transmitter Mode 7.24.1.7 UHS-I DDR50, 4-bit data Table 7-109 and Table 7-110 present Timing requirements and Switching characteristics for MMC1 DDR50 in receiver and transmitter mode (see Figure 7-75 and Figure 7-76). Table 7-109. Timing Requirements for MMC1 - SD Card DDR50 Mode NO. PARAME TER DESCRIPTION MODE DDR50 tsu(cmdV-clk) 5 Setup time, mmc1_cmd valid before mmc1_clk transition DDR50 th(clk-cmdV) 6 Hold time, mmc1_cmd valid after mmc1_clk transition DDR50 tsu(dV-clk) 7 Setup time, mmc1_dat[3:0] valid before mmc1_clk transition Pad Loopback DDR50 th(clk-dV) 8 Hold time, mmc1_dat[3:0] valid after mmc1_clk transition Pad Loopback Internal Loopback Internal Loopback MIN MAX UNIT 3.13 ns 1.6 ns 3.13 ns 3.13 ns 1.6 (1) ns 1.6 ns (1) This Hold time requirement is larger than the Hold time provided by a typical SD card. Therefore, the trace length between the Device and SD card must be sufficiently long enough to ensure that the Hold time is met at the Device. Table 7-110. Switching Characteristics for MMC1 - SD Card DDR50 Mode PARAMETER DESCRIPTION DDR500 NO. fop(clk) Operating frequency, mmc1_clk MIN MAX UNIT 48 MHz DDR501 tw(clkH) Pulse duration, mmc1_clk high 0.5*P0.185 (1) ns DDR502 tw(clkL) Pulse duration, mmc1_clk low 0.5*P0.185 (1) ns DDR503 td(clk-cmdV) Delay time, mmc1_clk transition to mmc1_cmd transition 1.225 6.6 DDR504 td(clk-dV) Delay time, mmc1_clk transition to mmc1_dat[3:0] transition 1.225 6.6 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated ns 321 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output mmc1_clk period in ns DDR500 DDR502 DDR501 mmc1_clk DDR505 DDR506 mmc1_cmd DDR507 DDR507 DDR508 DDR508 mmc1_dat[3:0] MMC1_13 Figure 7-75. SDMMC - High Speed SD - DDR - Data/Command Receive DDR500 DDR501 DDR502 mmc1_clk DDR503(max) DDR503(min) mmc1_cmd DDR504(max) DDR504(max) DDR504(min) DDR504(min) mmc1_dat[3:0] MMC1_14 Figure 7-76. SDMMC - High Speed SD - DDR - Data/Command Transmit NOTE To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register. The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter. Virtual IO Timings Modes must be used to guarantee some IO timings for MMC1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-111 Virtual Functions Mapping for MMC1 for a definition of the Virtual modes. Table 7-111 presents the values for DELAYMODE bitfield. Table 7-111. Virtual Functions Mapping for MMC1 BALL 322 BALL NAME Delay Mode Value MUXMODE[15: 0] MMC1_VIRTUA L1 MMC1_VIRTU AL2 MMC1_VIRTUA L5 MMC1_VIRTUA L6 MMC1_VIRTUA L7 0 W6 mmc1_clk 11 10 7 6 5 mmc1_clk Y6 mmc1_cmd 11 10 7 6 5 mmc1_cmd AA6 mmc1_dat0 11 10 7 6 5 mmc1_dat0 Y4 mmc1_dat1 11 10 7 6 5 mmc1_dat1 AA5 mmc1_dat2 11 10 7 6 5 mmc1_dat2 Y3 mmc1_dat3 11 10 7 6 5 mmc1_dat3 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for MMC1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-112 Manual Functions Mapping for MMC1 for a definition of the Manual modes. Table 7-112 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 323 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-112. Manual Functions Mapping for MMC1 BALL BALL NAME MMC1_DDR_MANUAL1 MMC1_SDR104_MANUAL1 CFG REGISTER MUXMODE - CFG_MMC1_CLK_IN mmc1_clk 600 400 CFG_MMC1_CLK_OUT mmc1_clk - - CFG_MMC1_CMD_IN mmc1_cmd 0 0 0 CFG_MMC1_CMD_OEN mmc1_cmd A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) mmc1_clk 0 0 - W6 mmc1_clk 1271 0 Y6 mmc1_cmd 229 0 Y6 mmc1_cmd 0 W6 0 Y6 mmc1_cmd 0 0 0 0 CFG_MMC1_CMD_OUT mmc1_cmd AA6 mmc1_dat0 850 0 - - CFG_MMC1_DAT0_IN mmc1_dat0 AA6 mmc1_dat0 0 0 0 0 CFG_MMC1_DAT0_OEN mmc1_dat0 AA6 mmc1_dat0 20 0 30 0 CFG_MMC1_DAT0_OUT mmc1_dat0 Y4 mmc1_dat1 468 0 - - CFG_MMC1_DAT1_IN mmc1_dat1 Y4 mmc1_dat1 0 0 0 0 CFG_MMC1_DAT1_OEN mmc1_dat1 Y4 mmc1_dat1 0 0 0 0 CFG_MMC1_DAT1_OUT mmc1_dat1 AA5 mmc1_dat2 466 0 - - CFG_MMC1_DAT2_IN mmc1_dat2 AA5 mmc1_dat2 0 0 0 0 CFG_MMC1_DAT2_OEN mmc1_dat2 AA5 mmc1_dat2 0 0 0 0 CFG_MMC1_DAT2_OUT mmc1_dat2 Y3 mmc1_dat3 399 0 - - CFG_MMC1_DAT3_IN mmc1_dat3 Y3 mmc1_dat3 0 0 0 0 CFG_MMC1_DAT3_OEN mmc1_dat3 Y3 mmc1_dat3 0 0 0 0 CFG_MMC1_DAT3_OUT mmc1_dat3 7.24.2 MMC2 — eMMC MMC2 interface is compliant with the JC64 eMMC Standard v4.5 and it supports the following eMMC applications: • Standard JC64 SDR, 8-bit data, half cycle • High-speed JC64 SDR, 8-bit data, half cycle • High-speed JC64 DDR, 8-bit data • High-speed HS200 JC64 SDR, 8-bit data, half cycle NOTE For more information, see the eMMC/SD/SDIO chapter of the Device TRM. 7.24.2.1 Standard JC64 SDR, 8-bit data, half cycle Table 7-113 and Table 7-114 present Timing requirements and Switching characteristics for MMC2 - Standard SDR in receiver and Transmitter mode (see Figure 7-77 and Figure 7-78). 324 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-113. Timing Requirements for MMC2 - JC64 Standard SDR Mode PARAMETER DESCRIPTION SSDR5 NO. tsu(cmdV-clkH) Setup time, mmc2_cmd valid before mmc2_clk rising clock edge SSDR6 th(clkH-cmdV) Hold time, mmc2_cmd valid after mmc2_clk rising clock edge SSDR7 tsu(dV-clkH) Setup time, mmc2_dat[7:0] valid before mmc2_clk rising clock edge SSDR8 th(clkH-dV) Hold time, mmc2_dat[7:0] valid after mmc2_clk rising clock edge MIN MAX UNIT 14.53 ns 8.4 ns 14.53 ns 8.4 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 325 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-114. Switching Characteristics for MMC2 - JC64 Standard SDR Mode NO. SSDR1 PARAMETER DESCRIPTION fop(clk) Operating frequency, mmc2_clk MIN MAX UNIT 24 MHz SSDR2H tw(clkH) Pulse duration, mmc2_clk high 0.5*P0.172 (1) ns SSDR2L tw(clkL) Pulse duration, mmc2_clk low 0.5*P0.172 (1) ns SSDR3 td(clkL-cmdV) Delay time, mmc2_clk falling clock edge to mmc2_cmd transition -16.96 16.96 ns SSDR4 td(clkL-dV) Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition -16.96 16.96 ns (1) P = output mmc2_clk period in ns SSDR2 SSDR2 SSDR1 mmc2_clk SSDR6 SSDR5 mmc2_cmd SSDR8 SSDR7 mmc2_dat[7:0] MMC2_01 Figure 7-77. MMC/SD/SDIO in - Standard JC64 - Receiver Mode SSDR2 SSDR2 SSDR1 mmc2_clk SSDR3 mmc2_cmd SSDR4 mmc2_dat[7:0] MMC2_02 Figure 7-78. MMC/SD/SDIO in - Standard JC64 - Transmitter Mode 7.24.2.2 High-speed JC64 SDR, 8-bit data, half cycle Table 7-115 and Table 7-116 present Timing requirements and Switching characteristics for MMC2 - High speed SDR in receiver and transmitter mode (see Figure 7-79 and Figure 7-80). Table 7-115. Timing Requirements for MMC2 - JC64 High Speed SDR Mode PARAMETER DESCRIPTION MIN JC643 NO. tsu(cmdV-clkH) Setup time, mmc2_cmd valid before mmc2_clk rising clock edge 6.94 ns JC644 th(clkH-cmdV) Hold time, mmc2_cmd valid after mmc2_clk rising clock edge 2.6 ns JC647 tsu(dV-clkH) Setup time, mmc2_dat[7:0] valid before mmc2_clk rising clock edge 6.94 ns JC648 th(clkH-dV) Hold time, mmc2_dat[7:0] valid after mmc2_clk rising clock edge 2.6 ns 326 MAX UNIT Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-116. Switching Characteristics for MMC2 - JC64 High Speed SDR Mode PARAMETER DESCRIPTION JC641 NO. fop(clk) Operating frequency, mmc2_clk MIN MAX UNIT 48 JC642H tw(clkH) Pulse duration, mmc2_clk high 0.5*P0.172 (1) MHz ns JC642L tw(clkL) Pulse duration, mmc2_clk low 0.5*P0.172 (1) ns JC645 td(clkL-cmdV) Delay time, mmc2_clk falling clock edge to mmc2_cmd transition -6.64 6.64 ns JC646 td(clkL-dV) Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition -6.64 6.64 ns (1) P = output mmc2_clk period in ns JC641 JC642L JC642H mmc2_clk JC643 JC644 mmc2_cmd JC647 JC648 mmc2_dat[7:0] MMC2_03 Figure 7-79. MMC/SD/SDIO in - High Speed JC64 - Receiver Mode JC641 JC642L JC642H mmc2_clk JC645 JC645 mmc2_cmd JC646 JC646 mmc2_dat[7:0] MMC2_04 Figure 7-80. MMC/SD/SDIO in - High Speed JC64 - Transmitter Mode 7.24.2.3 High-speed HS200 JC64 SDR, 8-bit data, half cycle Table 7-117 presents Timing requirements and Switching characteristics for MMC2 - HS200 in receiver and transmitter mode (see Figure 7-81). Table 7-117. Switching Characteristics for MMC2 - JEDS84 HS200 Mode NO. HS2001 PARAMETER DESCRIPTION fop(clk) Operating frequency, mmc2_clk MIN MAX UNIT 192 MHz HS2002H tw(clkH) Pulse duration, mmc2_clk high 0.5*P0.172 (1) ns HS2002L tw(clkL) Pulse duration, mmc2_clk low 0.5*P0.172 (1) ns HS2005 td(clkL-cmdV) Delay time, mmc2_clk falling clock edge to mmc2_cmd transition -1.136 0.536 ns HS2006 td(clkL-dV) Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition -1.136 0.536 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 327 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output mmc2_clk period in ns HS2001 HS2002L HS2002H mmc2_clk HS2005 HS2005 mmc2_cmd HS2006 HS2006 mmc2_dat[7:0] MMC2_05 Figure 7-81. eMMC in - HS200 SDR - Transmitter Mode 7.24.2.4 High-speed JC64 DDR, 8-bit data Table 7-118 and Table 7-119 present Timing requirements and Switching characteristics for MMC2 - High speed DDR in receiver and transmitter mode (see Figure 7-82 and Figure 7-83). Table 7-118. Timing Requirements for MMC2 - JC64 High Speed DDR Mode NO. PARAMETER DESCRIPTION DDR3 tsu(cmdV-clk) Setup time, mmc2_cmd valid before mmc2_clk transition DDR4 th(clk-cmdV) Hold time, mmc2_cmd valid after mmc2_clk transition DDR7 tsu(dV-clk) Setup time, mmc2_dat[7:0] valid before mmc2_clk transition DDR8 th(clk-dV) Hold time, mmc2_dat[7:0] valid after mmc2_clk transition MODE MIN MAX UNIT 3.14 ns 1.8 ns 3.14 ns Pad Loopback (1.8V) 1.8 (1) ns Pad Loopback (3.3V) 1.8 ns (1) ns Internal Loopback 1.8 (1) This Hold time requirement is larger than the Hold time provided by a typical eMMC component. Therefore, the trace length between the Device and eMMC component must be sufficiently long enough to ensure that the Hold time is met at the Device. Table 7-119. Switching Characteristics for MMC2 - JC64 High Speed DDR Mode PARAMETER DESCRIPTION DDR1 NO. fop(clk) Operating frequency, mmc2_clk MIN MAX UNIT 48 MHz DDR2H tw(clkH) Pulse duration, mmc2_clk high 0.5*P0.172 (1) ns DDR2L tw(clkL) Pulse duration, mmc2_clk low 0.5*P0.172 (1) ns DDR5 td(clk-cmdV) Delay time, mmc2_clk transition to mmc2_cmd transition 2.9 7.14 ns DDR6 td(clk-dV) Delay time, mmc2_clk transition to mmc2_dat[7:0] transition 2.9 7.14 ns (1) P = output mmc2_clk period in ns Table 7-120 and Table 7-121 present Timing requirements and Switching characteristics for MMC2 - High speed DDR in receiver and transmitter mode During Boot (see Figure 7-82 and Figure 7-83). Table 7-120. Timing Requirements for MMC2 - JC64 High Speed DDR Mode During Boot PARAMETER DESCRIPTION DDR3 NO. tsu(cmdV-clk) Setup time, mmc2_cmd valid before mmc2_clk transition DDR4 th(clk-cmdV) Hold time, mmc2_cmd valid after mmc2_clk transition 328 MODE MIN Boot (1.8V) 3.14 MAX UNIT ns B3oot (3.3V) 3.14 ns Boot (1.8V) 1.8 (1) ns Boot (3.3V) 1.8 (1) ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-120. Timing Requirements for MMC2 - JC64 High Speed DDR Mode During Boot (continued) PARAMETER DESCRIPTION MODE MIN DDR7 NO. tsu(dV-clk) Setup time, mmc2_dat[7:0] valid before mmc2_clk transition Boot (1.8V) 3.14 MAX UNIT ns Boot (3.3V) 3.14 ns DDR8 th(clk-dV) Hold time, mmc2_dat[7:0] valid after mmc2_clk transition Boot (1.8V) 1.8 (1) ns Boot (3.3V) 1.8 (1) ns (1) This Hold time requirement is larger than the Hold time provided by a typical eMMC component. Therefore, the trace length between the Device and eMMC component must be sufficiently long enough to ensure that the Hold time is met at the Device. Table 7-121. Switching Characteristics for MMC2 - JC64 High Speed DDR Mode During Boot NO. DDR1 PARAMETER DESCRIPTION fop(clk) Operating frequency, mmc2_clk DDR2H tw(clkH) MODE MIN Pulse duration, mmc2_clk high MAX UNIT 48 MHz 0.5*P0.172 ns 0.5*P0.172 ns (1) DDR2L tw(clkL) Pulse duration, mmc2_clk low (1) DDR5 DDR6 td(clk-cmdV) td(clk-dV) Delay time, mmc2_clk transition to mmc2_cmd transition Delay time, mmc2_clk transition to mmc2_dat[7:0] transition Boot (1.8V) 2.9 7.14 ns Boot (3.3V) 2.9 7.14 ns Boot (1.8V) 2.9 7.14 ns Boot (3.3V) 2.9 7.14 ns (1) P = output mmc2_clk period in ns DDR1 DDR2H DDR2L mmc2_clk DDR3 DDR4 mmc2_cmd DDR8 DDR8 DDR7 DDR8 DDR7 DDR7 DDR7 mmc2_dat[7:0] MMC2_07 Figure 7-82. MMC/SD/SDIO in - High Speed DDR JC64 - Receiver Mode DDR1 DDR2 DDR2 mmc2_clk DDR5 DDR5 DDR5 DDR5 mmc2_cmd DDR6 DDR6 DDR6 DDR6 DDR6 DDR6 mmc2_dat[7:0] MMC2_08 Figure 7-83. MMC/SD/SDIO in - High Speed DDR JC64 - Transmitter Mode Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 329 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for MMC2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-122 Manual Functions Mapping for MMC2 DDR for a definition of the Manual modes. Table 7-122 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. 330 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-122. Manual Functions Mapping for MMC2 DDR BALL BALL NAME MMC2_DDR_MANUAL1 CFG REGISTER MUXMODE 0 CFG_GPMC_A19_IN mmc2_dat4 A_DELAY (ps) G_DELAY (ps) 270 1 K7 gpmc_a19 K7 gpmc_a19 0 0 CFG_GPMC_A19_OEN mmc2_dat4 K7 gpmc_a19 170 0 CFG_GPMC_A19_OUT mmc2_dat4 M7 gpmc_a20 758 0 CFG_GPMC_A20_IN mmc2_dat5 M7 gpmc_a20 0 0 CFG_GPMC_A20_OEN mmc2_dat5 M7 gpmc_a20 81 0 CFG_GPMC_A20_OUT mmc2_dat5 J5 gpmc_a21 286 0 CFG_GPMC_A21_IN mmc2_dat6 J5 gpmc_a21 0 0 CFG_GPMC_A21_OEN mmc2_dat6 J5 gpmc_a21 123 0 CFG_GPMC_A21_OUT mmc2_dat6 K6 gpmc_a22 346 0 CFG_GPMC_A22_IN mmc2_dat7 K6 gpmc_a22 0 0 CFG_GPMC_A22_OEN mmc2_dat7 K6 gpmc_a22 55 0 CFG_GPMC_A22_OUT mmc2_dat7 J7 gpmc_a23 0 0 CFG_GPMC_A23_IN mmc2_clk J7 gpmc_a23 422 0 CFG_GPMC_A23_OUT mmc2_clk J4 gpmc_a24 642 0 CFG_GPMC_A24_IN mmc2_dat0 J4 gpmc_a24 0 0 CFG_GPMC_A24_OEN mmc2_dat0 J4 gpmc_a24 0 0 CFG_GPMC_A24_OUT mmc2_dat0 J6 gpmc_a25 128 0 CFG_GPMC_A25_IN mmc2_dat1 J6 gpmc_a25 0 0 CFG_GPMC_A25_OEN mmc2_dat1 J6 gpmc_a25 0 0 CFG_GPMC_A25_OUT mmc2_dat1 H4 gpmc_a26 395 0 CFG_GPMC_A26_IN mmc2_dat2 H4 gpmc_a26 0 0 CFG_GPMC_A26_OEN mmc2_dat2 H4 gpmc_a26 0 0 CFG_GPMC_A26_OUT mmc2_dat2 H5 gpmc_a27 623 0 CFG_GPMC_A27_IN mmc2_dat3 H5 gpmc_a27 0 0 CFG_GPMC_A27_OEN mmc2_dat3 H5 gpmc_a27 54 0 CFG_GPMC_A27_OUT mmc2_dat3 H6 gpmc_cs1 0 0 CFG_GPMC_CS1_IN mmc2_cmd H6 gpmc_cs1 0 0 CFG_GPMC_CS1_OEN mmc2_cmd H6 gpmc_cs1 0 0 CFG_GPMC_CS1_OUT mmc2_cmd Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 331 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Manual IO Timings Modes must be used to guarantee some IO timings for MMC2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-123 Manual Functions Mapping for MMC2 with Internal Loopback Clock and for HS200 for a definition of the Manual modes. Table 7-123 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-123. Manual Functions Mapping for MMC2 With Internal Loopback Clock and for HS200 BALL BALL NAME MMC2_DDR_LB_MANUAL1 MMC2_STD_HS_LB_MANUAL1 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) MMC2_HS200_MANUAL1 A_DELAY (ps) CFG REGISTER G_DELAY (ps) MUXMODE 1 K7 gpmc_a19 49 0 850 0 - - CFG_GPMC_A19_IN mmc2_dat4 K7 gpmc_a19 0 0 0 0 274 0 CFG_GPMC_A19_OEN mmc2_dat4 K7 gpmc_a19 170 0 0 0 162 0 CFG_GPMC_A19_OUT mmc2_dat4 M7 gpmc_a20 463 0 1264 0 - - CFG_GPMC_A20_IN mmc2_dat5 M7 gpmc_a20 0 0 0 0 401 0 CFG_GPMC_A20_OEN mmc2_dat5 M7 gpmc_a20 81 0 0 0 73 0 CFG_GPMC_A20_OUT mmc2_dat5 J5 gpmc_a21 8 0 786 0 - - CFG_GPMC_A21_IN mmc2_dat6 J5 gpmc_a21 0 0 0 0 465 0 CFG_GPMC_A21_OEN mmc2_dat6 J5 gpmc_a21 123 0 0 0 115 0 CFG_GPMC_A21_OUT mmc2_dat6 K6 gpmc_a22 0 102 902 0 - - CFG_GPMC_A22_IN mmc2_dat7 K6 gpmc_a22 0 0 0 0 633 0 CFG_GPMC_A22_OEN mmc2_dat7 K6 gpmc_a22 55 0 0 0 47 0 CFG_GPMC_A22_OUT mmc2_dat7 J7 gpmc_a23 592 2815 0 2764 - - CFG_GPMC_A23_IN mmc2_clk J7 gpmc_a23 422 0 0 0 935 280 CFG_GPMC_A23_OUT mmc2_clk J4 gpmc_a24 384 0 1185 0 - - CFG_GPMC_A24_IN mmc2_dat0 J4 gpmc_a24 0 0 0 0 621 0 CFG_GPMC_A24_OEN mmc2_dat0 J4 gpmc_a24 0 0 0 0 0 0 CFG_GPMC_A24_OUT mmc2_dat0 J6 gpmc_a25 0 0 670 0 - - CFG_GPMC_A25_IN mmc2_dat1 J6 gpmc_a25 0 0 0 0 183 0 CFG_GPMC_A25_OEN mmc2_dat1 J6 gpmc_a25 0 0 0 0 0 0 CFG_GPMC_A25_OUT mmc2_dat1 H4 gpmc_a26 171 0 972 0 - - CFG_GPMC_A26_IN mmc2_dat2 H4 gpmc_a26 0 0 0 0 467 0 CFG_GPMC_A26_OEN mmc2_dat2 H4 gpmc_a26 0 0 0 0 0 0 CFG_GPMC_A26_OUT mmc2_dat2 H5 gpmc_a27 315 0 1116 0 - - CFG_GPMC_A27_IN mmc2_dat3 H5 gpmc_a27 0 0 0 0 262 0 CFG_GPMC_A27_OEN mmc2_dat3 H5 gpmc_a27 54 0 0 0 46 0 CFG_GPMC_A27_OUT mmc2_dat3 H6 gpmc_cs1 0 0 250 0 - - CFG_GPMC_CS1_IN mmc2_cmd 332 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-123. Manual Functions Mapping for MMC2 With Internal Loopback Clock and for HS200 (continued) BALL BALL NAME MMC2_DDR_LB_MANUAL1 MMC2_STD_HS_LB_MANUAL1 MMC2_HS200_MANUAL1 A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 1 H6 gpmc_cs1 0 0 0 0 684 0 CFG_GPMC_CS1_OEN mmc2_cmd H6 gpmc_cs1 0 0 0 0 76 0 CFG_GPMC_CS1_OUT mmc2_cmd Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 333 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 7.24.3 MMC3 and MMC4—SDIO/SD MMC3 and MMC4 interfaces are compliant with the SDIO3.0 standard v1.0, SD Part E1 and for generic SDIO devices, it supports the following applications: • MMC3 8-bit data and MMC4 4-bit data, SD Default speed, SDR • MMC3 8-bit data and MMC4 4-bit data, SD High speed, SDR • MMC3 8-bit data and MMC4 4-bit data, UHS-1 SDR12 (SD Standard v3.01), 4-bit data, SDR, half cycle • MMC3 8-bit data and MMC4 4-bit data, UHS-I SDR25 (SD Standard v3.01), 4-bit data, SDR, half cycle • MMC3 8-bit data, UHS-I SDR50 NOTE The eMMC/SD/SDIOj (j = 3 to 4) controller is also referred to as MMCj. NOTE For more information, see the MMC/SDIO chapter of the Device TRM. 7.24.3.1 MMC3 and MMC4, SD Default Speed Figure 7-84, Figure 7-85, and Table 7-124 through Table 7-127 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD Default speed in receiver and transmitter mode. Table 7-124. Timing Requirements for MMC3 - Default Speed Mode (1) NO. PARAMETER DESCRIPTION DS5 tsu(cmdV-clkH) Setup time, mmc3_cmd valid before mmc3_clk rising clock edge DS6 th(clkH-cmdV) Hold time, mmc3_cmd valid after mmc3_clk rising clock edge DS7 tsu(dV-clkH) Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge DS8 th(clkH-dV) Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge MIN MAX UNIT 25.83 ns 20.9 ns 25.83 ns 20.9 ns (1) i in [i:0] = 7 Table 7-125. Switching Characteristics for MMC3 - SD/SDIO Default Speed Mode (2) NO. PARAMETER DESCRIPTION DS0 fop(clk) Operating frequency, mmc3_clk MIN MAX UNIT 24 DS1 tw(clkH) Pulse duration, mmc3_clk high 0.5*P0.270 (1) MHz ns DS2 tw(clkL) Pulse duration, mmc3_clk low 0.5*P0.270 (1) ns DS3 td(clkL-cmdV) Delay time, mmc3_clk falling clock edge to mmc3_cmd transition -14.93 14.93 ns DS4 td(clkL-dV) Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition -14.93 14.93 ns MAX UNIT (1) P = output mmc3_clk period in ns (2) i in [i:0] = 7 Table 7-126. Timing Requirements for MMC4 - Default Speed Mode (1) NO. PARAMETER DESCRIPTION DS5 tsu(cmdV-clkH) Setup time, mmc4_cmd valid before mmc4_clk rising clock edge DS6 th(clkH-cmdV) Hold time, mmc4_cmd valid after mmc4_clk rising clock edge DS7 tsu(dV-clkH) Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge DS8 th(clkH-dV) Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge 334 MIN 28.53 ns 20.9 ns 28.53 ns 20.9 ns Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) i in [i:0] = 3 Table 7-127. Switching Characteristics for MMC4 - Default Speed Mode (2) NO. PARAMETER DESCRIPTION DS0 fop(clk) Operating frequency, mmc4_clk MIN MAX UNIT 24 DS1 tw(clkH) Pulse duration, mmc4_clk high 0.45*P (1) MHz DS2 tw(clkL) Pulse duration, mmc4_clk low 0.45*P (1) DS3 td(clkL-cmdV) Delay time, mmc4_clk falling clock edge to mmc4_cmd transition -14.93 14.93 ns DS4 td(clkL-dV) Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition -14.93 14.93 ns ns ns (1) P = output mmc4_clk period in ns (2) i in [i:0] = 3 DS2 DS1 DS0 mmcj_clk DS6 DS5 mmcj_cmd DS8 DS7 mmcj_dat[i:0] MMC3/4_07 Figure 7-84. MMC/SD/SDIOj in - Default Speed - Receiver Mode DS2 DS1 DS0 mmcj_clk DS3 mmcj_cmd DS4 mmcj_dat[i:0] MMC3/4_08 Figure 7-85. MMC/SD/SDIOj in - Default Speed - Transmitter Mode 7.24.3.2 MMC3 and MMC4, SD High Speed Figure 7-86, Figure 7-87, and Table 7-128 through Table 7-131 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO High speed in receiver and transmitter mode. Table 7-128. Timing Requirements for MMC3 - SD/SDIO High Speed Mode (1) NO. PARAMETER DESCRIPTION MIN HS3 tsu(cmdV-clkH) Setup time, mmc3_cmd valid before mmc3_clk rising clock edge 6.64 MAX ns HS4 th(clkH-cmdV) Hold time, mmc3_cmd valid after mmc3_clk rising clock edge 2.6 ns HS7 tsu(dV-clkH) Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge 6.64 ns HS8 th(clkH-dV) Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge 2.6 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated UNIT 335 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) i in [i:0] = 7 Table 7-129. Switching Characteristics for MMC3 - SD/SDIO High Speed Mode (2) NO. PARAMETER DESCRIPTION HS1 fop(clk) Operating frequency, mmc3_clk MIN MAX UNIT 48 MHz HS2H tw(clkH) Pulse duration, mmc3_clk high 0.5*P0.270 (1) ns HS2L tw(clkL) Pulse duration, mmc3_clk low 0.5*P0.270 (1) ns HS5 td(clkL-cmdV) Delay time, mmc3_clk falling clock edge to mmc3_cmd transition -7.6 3.6 ns HS6 td(clkL-dV) Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition -7.6 3.6 ns (1) P = output mmc3_clk period in ns (2) i in [i:0] = 7 Table 7-130. Timing Requirements for MMC4 - High Speed Mode (1) NO. PARAMETER DESCRIPTION MIN HS3 tsu(cmdV-clkH) Setup time, mmc4_cmd valid before mmc4_clk rising clock edge 6.64 MAX UNIT ns HS4 th(clkH-cmdV) Hold time, mmc4_cmd valid after mmc4_clk rising clock edge 1.6 ns HS7 tsu(dV-clkH) Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge 6.64 ns HS8 th(clkH-dV) Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge 1.6 ns (1) i in [i:0] = 3 Table 7-131. Switching Characteristics for MMC4 - High Speed Mode (2) NO. PARAMETER DESCRIPTION MIN MAX UNIT 48 MHz HS1 fop(clk) Operating frequency, mmc4_clk HS2H tw(clkH) Pulse duration, mmc4_clk high 0.45*P (1) HS2L tw(clkL) Pulse duration, mmc4_clk low 0.45*P (1) HS5 td(clkL-cmdV) Delay time, mmc4_clk falling clock edge to mmc4_cmd transition -8.8 6.6 ns HS6 td(clkL-dV) Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition -8.8 6.6 ns ns ns (1) P = output mmc4_clk period in ns (2) i in [i:0] = 3 HS1 HS2L HS2H mmcj_clk HS3 HS4 mmcj_cmd HS7 HS8 mmcj_dat[i:0] MMC3/4_09 Figure 7-86. MMC/SD/SDIOj in - High Speed - Receiver Mode 336 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 HS1 HS2H HS2L mmcj_clk HS5 HS5 mmcj_cmd HS6 HS6 mmcj_dat[i:0] MMC3/4_10 Figure 7-87. MMC/SD/SDIOj in - High Speed - Transmitter Mode 7.24.3.3 MMC3 and MMC4, SD and SDIO SDR12 Mode Figure 7-88, Figure 7-89, and Table 7-132, through Table 7-135 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO SDR12 in receiver and transmitter mode. Table 7-132. Timing Requirements for MMC3 - SDR12 Mode (1) PARAMETER DESCRIPTION SDR125 NO. tsu(cmdV-clkH) Setup time, mmc3_cmd valid before mmc3_clk rising clock edge SDR126 th(clkH-cmdV) Hold time, mmc3_cmd valid after mmc3_clk rising clock edge SDR127 tsu(dV-clkH) Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge SDR128 th(clkH-dV) Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge MIN MAX UNIT 27.33 ns 1.6 ns 27.33 ns 1.6 ns (1) i in [i:0] = 7 Table 7-133. Switching Characteristics for MMC3 - SDR12 Mode (2) PARAMETER DESCRIPTION SDR120 NO. fop(clk) Operating frequency, mmc3_clk MIN MAX UNIT 24 MHz SDR121 tw(clkH) Pulse duration, mmc3_clk high 0.5*P0.270 (1) ns SDR122 tw(clkL) Pulse duration, mmc3_clk low 0.5*P0.270 (1) ns SDR123 td(clkL-cmdV) Delay time, mmc3_clk falling clock edge to mmc3_cmd transition -19.13 16.93 ns SDR124 td(clkL-dV) Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition -19.13 16.93 ns MAX UNIT (1) P = output mmc3_clk period in ns (2) i in [i:0] = 7 Table 7-134. Timing Requirements for MMC4 - SDR12 Mode (1) PARAMETER DESCRIPTION SDR125 NO. tsu(cmdV-clkH) Setup time, mmc4_cmd valid before mmc4_clk rising clock edge SDR126 th(clkH-cmdV) Hold time, mmc4_cmd valid after mmc4_clk rising clock edge SDR127 tsu(dV-clkH) Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge SDR128 th(clkH-dV) Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge MIN 27.33 ns 1.6 ns 27.33 ns 1.6 ns (1) j in [i:0] = 3 Table 7-135. Switching Characteristics for MMC4 - SDR12 Mode (2) NO. PARAMETER DESCRIPTION MIN MAX UNIT SDR120 fop(clk) Operating frequency, mmc4_clk SDR121 tw(clkH) Pulse duration, mmc4_clk high 0.45*P (1) 24 MHz ns SDR122 tw(clkL) Pulse duration, mmc4_clk low 0.45*P (1) ns SDR125 td(clkL-cmdV) Delay time, mmc4_clk falling clock edge to mmc4_cmd transition -19.13 16.93 ns SDR126 td(clkL-dV) Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition -19.13 16.93 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 337 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) P = output mmc4_clk period in ns (2) j in [i:0] = 3 SDR122 SDR121 SDR120 mmcj_clk SDR126 SDR125 mmcj_cmd SDR128 SDR127 mmcj_dat[i:0] MMC3/4_11 Figure 7-88. MMC/SD/SDIOj in - SDR12 - Receiver Mode SDR122 SDR121 SDR120 mmcj_clk SDR123 mmcj_cmd SDR124 mmcj_dat[i:0] MMC3/4_12 Figure 7-89. MMC/SD/SDIOj in - SDR12 - Transmitter Mode 7.24.3.4 MMC3 and MMC4, SD SDR25 Mode Figure 7-90, Figure 7-91, and Table 7-136 through Table 7-139 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO SDR25 in receiver and transmitter mode. Table 7-136. Timing Requirements for MMC3 - SDR25 Mode (1) NO. PARAMETER DESCRIPTION MIN MAX UNIT SDR253 tsu(cmdV-clkH) Setup time, mmc3_cmd valid before mmc3_clk rising clock edge 6.64 ns SDR254 th(clkH-cmdV) Hold time, mmc3_cmd valid after mmc3_clk rising clock edge 1.6 ns SDR257 tsu(dV-clkH) Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge 6.64 ns SDR258 th(clkH-dV) Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge 1.6 ns (1) i in [i:0] = 7 Table 7-137. Switching Characteristics for MMC3 - SDR25 Mode (2) PARAMETER DESCRIPTION SDR251 NO. fop(clk) Operating frequency, mmc3_clk SDR252 H tw(clkH) Pulse duration, mmc3_clk high 0.5*P0.270 (1) ns SDR252L tw(clkL) Pulse duration, mmc3_clk low 0.5*P0.270 (1) ns SDR255 td(clkL-cmdV) Delay time, mmc3_clk falling clock edge to mmc3_cmd transition -8.8 6.6 ns SDR256 td(clkL-dV) Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition -8.8 6.6 ns 338 MIN MAX UNIT 48 MHz Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) P = output mmc3_clk period in ns (2) i in [i:0] = 7 Table 7-138. Timing Requirements for MMC4 - SDR25 Mode (1) NO. PARAMETER DESCRIPTION MIN MAX UNIT SDR255 tsu(cmdV-clkH) Setup time, mmc4_cmd valid before mmc4_clk rising clock edge 6.64 ns SDR256 th(clkH-cmdV) Hold time, mmc4_cmd valid after mmc4_clk rising clock edge 1.6 ns SDR257 tsu(dV-clkH) Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge 6.64 ns SDR258 th(clkH-dV) Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge 1.6 ns (1) i in [i:0] = 3 Table 7-139. Switching Characteristics for MMC4 - SDR25 Mode (2) PARAMETER DESCRIPTION SDR251 NO. fop(clk) Operating frequency, mmc4_clk MIN MAX UNIT 48 SDR252 H tw(clkH) Pulse duration, mmc4_clk high 0.45*P (1) MHz SDR252L tw(clkL) Pulse duration, mmc4_clk low 0.45*P (1) SDR255 td(clkL-cmdV) Delay time, mmc4_clk falling clock edge to mmc4_cmd transition -8.8 6.6 ns SDR256 td(clkL-dV) Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition -8.8 6.6 ns ns ns (1) P = output mmc4_clk period in ns (2) i in [i:0] = 3 SDR251 SDR252L SDR252H mmcj_clk SDR253 SDR254 mmcj_cmd SDR257 SDR258 mmcj_dat[i:0] MMC3/4_13 Figure 7-90. MMC/SD/SDIOj in - SDR25 - Receiver Mode SDR251 SDR252H SDR252L mmcj_clk SDR255 SDR255 mmcj_cmd SDR256 SDR256 mmcj_dat[i:0] MMC3/4_14 Figure 7-91. .MMC/SD/SDIOj in - SDR25 - Transmitter Mode 7.24.3.5 MMC3 SDIO High-Speed UHS-I SDR50 Mode, Half Cycle Figure 7-92, Figure 7-93, Table 7-140, and Table 7-141 present Timing requirements and Switching characteristics for MMC3 - SDIO High speed SDR50 in receiver and transmitter mode. Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 339 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-140. Timing Requirements for MMC3 - SDR50 Mode (1) PARAMETER DESCRIPTION MIN SDR503 NO. tsu(cmdV-clkH) Setup time, mmc3_cmd valid before mmc3_clk rising clock edge 2.82 MAX UNIT ns SDR504 th(clkH-cmdV) Hold time, mmc3_cmd valid after mmc3_clk rising clock edge 1.6 ns SDR507 tsu(dV-clkH) Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge 2.82 ns SDR508 th(clkH-dV) Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge 1.6 ns (1) i in [i:0] = 7 Table 7-141. Switching Characteristics for MMC3 - SDR50 Mode (2) PARAMETER DESCRIPTION SDR501 NO. fop(clk) Operating frequency, mmc3_clk MIN MAX UNIT 64 MHz SDR502 H tw(clkH) Pulse duration, mmc3_clk high 0.5*P0.270 (1) ns SDR502L tw(clkL) Pulse duration, mmc3_clk low 0.5*P0.270 (1) ns SDR505 td(clkL-cmdV) Delay time, mmc3_clk falling clock edge to mmc3_cmd transition -3.66 1.46 ns SDR506 td(clkL-dV) Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition -3.66 1.46 ns (1) P = output mmc3_clk period in ns (2) i in [i:0] = 7 SDR501 SDR502L SDR502H mmcj_clk SDR503 SDR504 mmcj_cmd SDR507 SDR508 mmcj_dat[7:0] MMC3/4_05 Figure 7-92. MMC/SD/SDIOj in - High Speed SDR50 - Receiver Mode SDR501 SDR502H SDR502L mmcj_clk SDR505 SDR505 mmcj_cmd SDR506 SDR506 mmcj_dat[7:0] MMC3/4_06 Figure 7-93. MMC/SD/SDIOj in - High Speed SDR50 - Transmitter Mode NOTE To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM. The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM. Manual IO Timings Modes must be used to guarantee some IO timings for MMC3. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-142 Manual Functions Mapping for MMC3 for a definition of the Manual modes. 340 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-142 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-142. Manual Functions Mapping for MMC3 BALL BALL NAME MMC3_MANUAL1 A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 0 AD4 mmc3_clk 0 386 CFG_MMC3_CLK_IN mmc3_clk AD4 mmc3_clk 605 0 CFG_MMC3_CLK_OUT mmc3_clk AC4 mmc3_cmd 0 0 CFG_MMC3_CMD_IN mmc3_cmd AC4 mmc3_cmd 0 0 CFG_MMC3_CMD_OEN mmc3_cmd AC4 mmc3_cmd 0 0 CFG_MMC3_CMD_OUT mmc3_cmd AC7 mmc3_dat0 171 0 CFG_MMC3_DAT0_IN mmc3_dat0 AC7 mmc3_dat0 0 0 CFG_MMC3_DAT0_OEN mmc3_dat0 AC7 mmc3_dat0 0 0 CFG_MMC3_DAT0_OUT mmc3_dat0 AC6 mmc3_dat1 221 0 CFG_MMC3_DAT1_IN mmc3_dat1 AC6 mmc3_dat1 0 0 CFG_MMC3_DAT1_OEN mmc3_dat1 AC6 mmc3_dat1 0 0 CFG_MMC3_DAT1_OUT mmc3_dat1 AC9 mmc3_dat2 0 0 CFG_MMC3_DAT2_IN mmc3_dat2 AC9 mmc3_dat2 0 0 CFG_MMC3_DAT2_OEN mmc3_dat2 AC9 mmc3_dat2 0 0 CFG_MMC3_DAT2_OUT mmc3_dat2 AC3 mmc3_dat3 474 0 CFG_MMC3_DAT3_IN mmc3_dat3 AC3 mmc3_dat3 0 0 CFG_MMC3_DAT3_OEN mmc3_dat3 AC3 mmc3_dat3 0 0 CFG_MMC3_DAT3_OUT mmc3_dat3 AC8 mmc3_dat4 792 0 CFG_MMC3_DAT4_IN mmc3_dat4 AC8 mmc3_dat4 0 0 CFG_MMC3_DAT4_OEN mmc3_dat4 AC8 mmc3_dat4 0 0 CFG_MMC3_DAT4_OUT mmc3_dat4 AD6 mmc3_dat5 782 0 CFG_MMC3_DAT5_IN mmc3_dat5 AD6 mmc3_dat5 0 0 CFG_MMC3_DAT5_OEN mmc3_dat5 AD6 mmc3_dat5 0 0 CFG_MMC3_DAT5_OUT mmc3_dat5 AB8 mmc3_dat6 942 0 CFG_MMC3_DAT6_IN mmc3_dat6 AB8 mmc3_dat6 0 0 CFG_MMC3_DAT6_OEN mmc3_dat6 AB8 mmc3_dat6 0 0 CFG_MMC3_DAT6_OUT mmc3_dat6 AB5 mmc3_dat7 636 0 CFG_MMC3_DAT7_IN mmc3_dat7 AB5 mmc3_dat7 0 0 CFG_MMC3_DAT7_OEN mmc3_dat7 AB5 mmc3_dat7 0 0 CFG_MMC3_DAT7_OUT mmc3_dat7 Manual IO Timings Modes must be used to guarantee some IO timings for MMC4. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-143 Manual Functions Mapping for MMC4 for a definition of the Manual modes. Table 7-143 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers. Table 7-143. Manual Functions Mapping for MMC4 BALL BALL NAME MMC4_MANUAL1 MMC4_DS_MANUAL1 CFG REGISTER A_DELAY (ps) G_DELAY (ps) A_DELAY (ps) G_DELAY (ps) 0 0 CFG_UART1_CTSN_IN E25 uart1_ctsn 0 0 MUXMODE 3 mmc4_clk E25 uart1_ctsn 1147 0 0 0 CFG_UART1_CTSN_OUT mmc4_clk C27 uart1_rtsn 1834 0 307 0 CFG_UART1_RTSN_IN mmc4_cmd C27 uart1_rtsn 0 0 0 0 CFG_UART1_RTSN_OEN mmc4_cmd Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 341 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-143. Manual Functions Mapping for MMC4 (continued) BALL BALL NAME MMC4_MANUAL1 A_DELAY (ps) G_DELAY (ps) MMC4_DS_MANUAL1 A_DELAY (ps) G_DELAY (ps) CFG REGISTER MUXMODE 3 C27 uart1_rtsn 0 0 0 0 CFG_UART1_RTSN_OUT mmc4_cmd D27 uart2_ctsn 2165 0 785 0 CFG_UART2_CTSN_IN mmc4_dat2 D27 uart2_ctsn 0 0 0 0 CFG_UART2_CTSN_OEN mmc4_dat2 D27 uart2_ctsn 0 0 0 0 CFG_UART2_CTSN_OUT mmc4_dat2 C28 uart2_rtsn 1929 64 613 0 CFG_UART2_RTSN_IN mmc4_dat3 C28 uart2_rtsn 0 0 0 0 CFG_UART2_RTSN_OEN mmc4_dat3 C28 uart2_rtsn 0 0 0 0 CFG_UART2_RTSN_OUT mmc4_dat3 D28 uart2_rxd 1935 128 683 0 CFG_UART2_RXD_IN mmc4_dat0 D28 uart2_rxd 0 0 0 0 CFG_UART2_RXD_OEN mmc4_dat0 D28 uart2_rxd 0 0 0 0 CFG_UART2_RXD_OUT mmc4_dat0 D26 uart2_txd 2172 44 835 0 CFG_UART2_TXD_IN mmc4_dat1 D26 uart2_txd 0 0 0 0 CFG_UART2_TXD_OEN mmc4_dat1 D26 uart2_txd 0 0 0 0 CFG_UART2_TXD_OUT mmc4_dat1 7.25 General-Purpose Interface (GPIO) The general-purpose interface combines eight general-purpose input/output (GPIO) banks. Each GPIO module provides 32 dedicated general-purpose pins with input and output capabilities; thus, the generalpurpose interface supports up to 247 pins. These pins can be configured for the following applications: • Data input (capture)/output (drive) • Keyboard interface with a debounce cell • Interrupt generation in active mode upon the detection of external events. Detected events are processed by two parallel independent interrupt-generation submodules to support biprocessor operations • Wake-up request generation in idle mode upon the detection of external events NOTE For more information, see the General-Purpose Interface chapter of the Device TRM. NOTE The general-purpose input/output i (i = 1 to 8) bank is also referred to as GPIOi. 7.26 Audio Tracking Logic (ATL) The device contains four ATL modules that can be used for asynchronous sample rate conversion of audio. The ATL calculates the error between two time bases, such as audio syncs, and optionally generates an averaged clock using cycle stealing via software. NOTE For more detailed information on the ATL peripheral, see the Audio Tracking Logic (ATL) chapter of the device-specific Technical Reference Manual. 342 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE Audio Tracking Logic x (x= 1 to 4) module is also referred to as ATLx. 7.26.1 ATL Electrical Data/Timing Table 7-144 and Figure 7-94 present switching characteristics for ATL Table 7-144. Switching Characteristics Over Recommended Operating Conditions for ATL_CLKOUTx NO. 1 PARAMETER tc(ATLCLKOUT) DESCRIPTION MIN MAX UNIT Cycle time, ATL_CLKOUTx 20 ns (1) 2 tw(ATLCLKOUTL) Pulse Duration, ATL_CLKOUTx low 0.45*P - M ns 3 tw(ATLCLKOUTH) Pulse Duration, ATL_CLKOUTx high 0.45*P - M(1) ns (1) P = ATL_CLKOUTx period. M = internal ATL PCLK period. 1 2 atl_clkx 3 ATL_01 Figure 7-94. ATL_CLKOUTx Timing 7.27 System and Miscellaneous interfaces The Device includes the following System and Miscellaneous interfaces: • Sysboot Interface • System DMA Interface • Interrupt Controllers (INTC) Interface • Observability Signal (OBS) Interface 7.28 Test Interfaces The Device includes the following Test interfaces: • IEEE 1149.1 Standard-Test-Access Port (JTAG) • Compact JTAG Interface (cJTAG) • Trace Port Interface Unit (TPIU) • Advanced Event Triggering Interface (AET) 7.28.1 IEEE 1149.1 Standard-Test-Access Port (JTAG) The JTAG (IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture) interface is used for BSDL testing and emulation of the device. The trstn pin only needs to be released when it is necessary to use a JTAG controller to debug the device or exercise the device's boundary scan functionality. For maximum reliability, the device includes an internal Pulldown (IPD) on the trstn pin to ensure that trstn is always asserted upon power up and the device's internal emulation logic is always properly initialized. JTAG controllers from Texas Instruments actively drive trstn high. However, some third-party JTAG controllers may not drive trstn high but expect the use of a Pullup resistor on trstn. When using this type of JTAG controller, assert trstn to initialize the device after powerup and externally drive trstn high before attempting any emulation or boundary-scan operations. The main JTAG features include: • 32KB embedded trace buffer (ETB) Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 343 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 • • • • www.ti.com 5-pin system trace interface for debug Supports Advanced Event Triggering (AET) All processors can be emulated via JTAG ports All functions on EMU pins of the device: – EMU[1:0] - cross-triggering, boot mode (WIR), STM trace – EMU[4:2] - STM trace only (single direction) 7.28.1.1 JTAG Electrical Data/Timing Table 7-145, Table 7-146 and Figure 7-95 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-145. Timing Requirements for IEEE 1149.1 JTAG NO. PARAMETER DESCRIPTION MIN MAX UNIT 1 tc(TCK) Cycle time, TCK 62.29 ns 1a tw(TCKH) Pulse duration, TCK high (40% of tc) 24.92 ns 1b tw(TCKL) Pulse duration, TCK low (40% of tc) 24.92 ns tsu(TDI-TCK) Input setup time, TDI valid to TCK high 6.23 ns tsu(TMS-TCK) Input setup time, TMS valid to TCK high 6.23 ns th(TCK-TDI) Input hold time, TDI valid from TCK high 31.15 ns th(TCK-TMS) Input hold time, TMS valid from TCK high 31.15 ns 3 4 Table 7-146. Switching Characteristics Over Recommended Operating Conditions for IEEE 1149.1 JTAG NO. 2 PARAMETER td(TCKL-TDOV) DESCRIPTION Delay time, TCK low to TDO valid MIN MAX UNIT 0 30.5 ns 1 1a 1b TCK 2 TDO 3 4 TDI/TMS JTAG_01 Figure 7-95. JTAG Timing Table 7-147, Table 7-148 and Figure 7-96 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-147. Timing Requirements for IEEE 1149.1 JTAG With RTCK NO. DESCRIPTION MIN MAX UNIT 1 tc(TCK) Cycle time, TCK 62.29 ns 1a tw(TCKH) Pulse duration, TCK high (40% of tc) 24.92 ns 1b tw(TCKL) Pulse duration, TCK low (40% of tc) 24.92 ns tsu(TDI-TCK) Input setup time, TDI valid to TCK high 6.23 ns tsu(TMS-TCK) Input setup time, TMS valid to TCK high 6.23 ns 3 344 PARAMETER Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-147. Timing Requirements for IEEE 1149.1 JTAG With RTCK (continued) NO. PARAMETER 4 DESCRIPTION MIN MAX UNIT th(TCK-TDI) Input hold time, TDI valid from TCK high 31.15 ns th(TCK-TMS) Input hold time, TMS valid from TCK high 31.15 ns Table 7-148. Switching Characteristics Over Recommended Operating Conditions for IEEE 1149.1 JTAG With RTCK NO. PARAMETER DESCRIPTION MIN MAX UNIT 0 27 ns 5 td(TCK-RTCK) Delay time, TCK to RTCK with no selected subpaths (i.e. ICEPick is the only tap selected - when the ARM is in the scan chain, the delay time is a function of the ARM functional clock). 6 tc(RTCK) Cycle time, RTCK 62.29 ns 7 tw(RTCKH) Pulse duration, RTCK high (40% of tc) 24.92 ns 8 tw(RTCKL) Pulse duration, RTCK low (40% of tc) 24.92 ns 5 TCK 6 7 8 RTCK JTAG_02 Figure 7-96. JTAG With RTCK Timing 7.28.1.2 Compact JTAG Interface (cJTAG) The cJTAG module is a component which can run a 2-pin communication protocol on top of an IEEE 1149.1 JTAG Test Access Port (TAP). The cJTAG logic serializes the IEEE 1149.1 transactions, using a variety of compression formats, to reduce the number of pins needed to implement a JTAG debug and boundary scan port. Table 7-149, Table 7-150 and Figure 7-97 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-149. Timing Requirements for IEEE 1149.7 cJTAG NO. PARAMETER DESCRIPTION MIN MAX UNIT CJ1 tc(TCK) Cycle time, TCK 62.29 ns CJ1a tw(TCKH) Pulse duration, TCK high (40% of tc) 24.92 ns CJ1b tw(TCKL) Pulse duration, TCK low(40% of tc) 24.92 ns CJ9a tsu(TMSC-TCKre) Input setup time, TMSC valid to TCK high (RE timing selected) 12.46 ns CJ10a tsu(TMSC-TCKfe) Input setup time, TMSC valid to TCK low (FE timing selected) 12.46 ns CJ9b th(TCKre-TMSC) Input hold time, TMSC valid from TCK high (RE timing selected) 0.00 ns CJ10b th(TCKfe-TMSC) Input hold time, TMSC valid from TCK low (FE timing selected) 0.00 ns Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 345 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 7-150. Switching Characteristics Over Recommended Operating Conditions for IEEE 1149.7 cJTAG MIN MAX UNIT CJ11 NO. td(TCKL-TMSCV) PARAMETER Delay time, TCK low to TMSC valid DESCRIPTION 0 12.45 ns CJ13 td(TCKH-TMSCZ) Delay time, TCK high to TMSC HiZ 0 20.7 ns CJ12 td(TMSCV-KPRV) Delay time, TMSC valid to Keeper Valid 0 18 ns CJ2 td(TCKL-TDOV) Delay time, TCK low to TDO valid 0 29.14 ns CJ1 CJ1b CJ1a jtag_tck CJ9a CJ10a CJ9b CJ10b CJ11 CJ13 jtag_tms_tmsc(IN) CJ2 jtag_tms_tmsc(OUT) JTAG_03 Figure 7-97. cJTAG Interface Timing—Normal Mode 7.28.2 Trace Port Interface Unit (TPIU) CAUTION The I/O timings provided in this section are valid only if signals within a single IOSET are used. The IOSETs are defined in Table 7-152. 7.28.2.1 TPIU PLL DDR Mode Table 7-151 and Figure 7-98 assume testing over the recommended operating conditions and electrical characteristic conditions below. Table 7-151. Switching Characteristics for TPIU NO. PARAMETER DESCRIPTION MIN MAX 5.56 UNIT TPIU1 tc(clk) Cycle time, TRACECLK period TPIU4 td(clk-ctlV) Skew time, TRACECLK transition to TRACECTL transition -0.96 0.96 ns ns TPIU5 td(clk-dataV) Skew time, TRACECLK transition to TRACEDATA[17:0] -0.96 0.96 ns TPIU1 TPIU2 TPIU3 TRACECLK TPIU4 TPIU4 TRACECTL TPIU5 TPIU5 TRACEDATA[X:0] TPIU_01 Figure 7-98. TPIU—PLL DDR Transmit Mode(1) (1) In d[X:0], X is equal to 15 or 17. In Table 7-152 are presented the specific groupings of signals (IOSET) for use with TPIU signals. 346 Timing Requirements and Switching Characteristics Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 7-152. TPIU IOSETs SIGNALS IOSET1 IOSET2 BALL MUX BALL MUX emu0 G21 0 G21 0 emu1 D24 0 D24 0 emu2 F10 2 F10 2 emu3 D7 2 D7 2 emu4 A7 2 A7 2 emu5 E1 5 G11 2 emu6 G2 5 E9 2 emu7 H7 5 F9 2 emu8 G1 5 F8 2 emu9 G6 5 E7 2 emu10 F2 5 D8 2 emu11 F3 5 A5 2 emu12 D1 5 C6 2 emu13 E2 5 C8 2 emu14 D2 5 C7 2 emu15 F4 5 A8 2 emu16 C1 5 C9 2 emu17 E4 5 A9 2 emu18 F5 5 B9 2 emu19 E6 5 A10 2 Timing Requirements and Switching Characteristics Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 347 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8 Applications, Implementation, and Layout NOTE Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test design implementation to confirm system functionality. 8.1 Introduction This chapter is intended to communicate, guide and illustrate a PCB design strategy resulting in a PCB that can support TI’s latest Application Processor. This Processor is a high-performance processor designed for automotive Infotainment and Advanced Driver Assistance Systems based on enhanced OMAP™ architecture integrated on a 28-nm CMOS process technology. These guidelines first focus on designing a robust Power Delivery Network (PDN) which is essential to achieve the desirable high performance processing available on Device. The general principles and stepby-step approach for implementing good power integrity (PI) with specific requirements will be described for the key Device power domains. TI strongly believes that simulating a PCB’s proposed PDN is required for first pass PCB design success. Key Device processor high-current power domains need to be evaluated for Power Rail IR Drop, Decoupling Capacitor Loop-Inductance and Power Rail Target Impedance. Only then can a PCB’s PDN performance be truly accessed by comparing these model PI parameters vs. TI’s recommended values. Ultimately for any high-volume product, TI recommends conducting a “Processor PDN Validation” test on prototype PCBs across processor “split lots” to verify PDN robustness meets desired performance goals for each customer’s worst-case scenario. Please contact your TI representative to receive guidance on PDN PI modeling and validation testing. Likewise, the methodology and requirements needed to route Device high-speed, differential interfaces (i.e. USB2.0, USB3.0, HDMI, PCI, SATA), single-ended interfaces (i.e. DDR2/DDR3, QSPI) and general purpose interfaces using LVCMOS drivers that meet timing requirements while minimizing signal integrity (SI) distortions on the PCB’s signaling traces. Signal trace lengths and flight times are aligned with FR-4 standard specification for PCBs. Several different PCB layout stack-up examples have been presented to illustrate a typical number of layers, signal assignments and controlled impedance requirements. Different Device interface signals demand more or less complexity for routing and controlled impedance stack-ups. Optimizing the PCB’s PDN stack-up needs with all of these different types of signal interfaces will ultimately determine the final layer count and layer assignments in each customer’s PCB design. This guideline must be used as a supplement in complement to TI’s Application Processor, Power Management IC (PMIC) and Audio Companion components along with other TI component technical documentation (i.e. Technical Reference Manual, Data Manual, Data Sheets, Silicon Errata, Pin-Out Spreadsheet, Application Notes, etc.). NOTE Notwithstanding any provision to the contrary, TI makes no warranty expressed, implied, or statutory, including any implied warranty of merchantability of fitness for a specific purpose, for customer boards. The data described in this appendix are intended as guidelines only. 348 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE These PCB guidelines are in a draft maturity and consequently, are subject to change depending on design verification testing conducted during IC development and validation. Note also that any references to Application Processor’s ballout or pin muxing are subject to change following the processor’s ballout maturity. 8.1.1 Initial Requirements and Guidelines Unless otherwise specified, the characteristic impedance for single-ended interfaces is recommended to be between 35 Ω and 65 Ω to minimize the overshoot or undershoot on far-end loads. Characteristic impedance for differential interfaces must be routed as differential traces on the same layer. The trace width and spacing must be chosen to yield the recommended differential impedance. For more information see Section 8.5.1. The PDN must be optimized for low trace resistance and low trace inductance for all high-current power nets from PMIC to the device. An external interface using a connector must be protected following the IEC61000-4-2 level 4 system ESD. 8.2 Power Optimizations This section describes the necessary steps for designing a robust Power Distribution Network (PDN): • Section 8.2.1, Step 1: PCB Stack-up • Section 8.2.2, Step 2: Physical Placement • Section 8.2.3, Step 3: Static Analysis • Section 8.2.4, Step 4: Frequency Analysis 8.2.1 Step 1: PCB Stack-up The PCB stack-up (layer assignment) is an important factor in determining the optimal performance of the power distribution system. An optimized PCB stack-up for higher power integrity performance can be achieved by following these recommendations: • Power and ground plane pairs must be closely coupled together. The capacitance formed between the planes can decouple the power supply at high frequencies. Whenever possible, the power and ground planes must be solid to provide continuous return path for return current. • Use a thin dielectric between the power and ground plane pair. Capacitance is inversely proportional to the separation of the plane pair. Minimizing the separation distance (the dielectric thickness) maximizes the capacitance. • Optimize the power and ground plane pair carrying high current supplies to key component power domains as close as possible to the same surface where these components are placed (see Figure 81). This will help to minimize “loop inductance” encountered between supply decoupling capacitors and component supply inputs and between power and ground plane pairs. NOTE 1-2oz for planes per total thickness and layer count is preferred! NOTE PCB thermal spreading can help to reduce Processor junction temperatures and is more effective when using heavier Cu weights on the outer Gnd plane layers. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 349 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Capacitor Trace DIE Package Via 3 1 Power/Ground 2 Ground/Power Note: 1. BGA via pair loop inductance 2. Power/Ground net spreading inductance 3. Capacitor trace inductance Loop inductance SPRABP6-001 Figure 8-1. Minimize Loop Inductance With Proper Layer Assignment The placement of power and ground planes in the PCB stackup (determined by layer assignment) has a significant impact on the parasitic inductances of power current path as shown in Figure 8-1. For this reason, it is recommended to consider layer order in the early stages of the PCB PDN design cycle, putting high-priority supplies in the top half of the stackup (assuming high load and priority components are mounted on the top-side of PCB) and low-priority supplies in the bottom half of the stackup as shown in the examples below (vias have parasitic inductances which impact the bottom layers more, so it is advised to put the sensitive and high-priority power supplies on the top/same layers). Two PCB stack-ups with layer assignments and via types that can enable an optimize PDN are shown in Figure 8-2 and Figure 8-3. TOP/SIGNAL1 GROUND POWER SIGNAL2 SIGNAL3 POWER GROUND BOTTOM/SIGNAL4 SPRABP6-002 Figure 8-2. Layer PCB With High Density Interconnect (HDI) Vias 350 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 TOP/SIGNAL1 POWER GROUND SIGNAL2 SIGNAL3 GROUND POWER BOTTOM/SIGNAL4 SPRABP6-003 Figure 8-3. Layer PCB With Plated Through Holes (PTH) Vias 8.2.2 Step 2: Physical Placement A critical step in designing an optimized PDN is that proper care must be taken to making sure that the initial floor planning of the PCB layout is done with good power integrity design guidelines in mind. The following points are important for optimizing a PCB’s PDN: • Minimizing the physical distance between power sources and key high load components is the first step toward optimization. Placing source and load components on the same side of the PCB is desirable. This will minimize via inductance impact for high current loads and steps • External trace routing between components must be as wide as possible. The wider the traces, the lower the DC resistance and consequently the lower the static IR drop. • Whenever possible for the internal layers (routing and plane), wide traces and copper area fills are preferred for PDN layout. The routing of power nets in plane provide for more interplane capacitance and improved high frequency performance of the PDN. • Whenever possible, use a via to component pin/pad ratio of 1:1 or better (i.e. especially decoupling capacitors, power inductors and current sensing resistors). Do not share vias among multiple capacitors for connecting power supply and ground planes. • Placement of vias must be as close as possible or even within a component’s solder pad if the PCB technology you are using provides this capability. Figure 8-4 shows an example of acceptable width for power net routing but with poor via placement. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 351 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com SWPS040-211 Figure 8-4. Poor Via Assignment for PDN Figure 8-5 shows an improved power net routing with better via assignment and placement, respectively. SWPS040-212 • 352 Figure 8-5. Improved Via Assignment for PDN To avoid any “ampacity” issue – maximum current-carrying capacity of each transitional via should be evaluated to determine the appropriate number of vias required to connect components. Figure 8-6 and Figure 8-7 show examples of “via starvation” on a power net transitioning from top routing layer to internal layers and the improved layout, respectively. Adding vias to bring the “via-topad” ratio to 1:1 will improve PDN performance. Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 SWPS040-213 One via for 5 capacitor pads is NOT good practice Figure 8-6. Via Starvation SWPS040-214 Added vias • Figure 8-7. Improved Layout With More Transitional Vias For noise sensitive power supplies (i.e. Phase Lock-Loops, analog signals like audio and video), a Gnd shield can be used to isolate coplanar supplies that may have high step currents or high frequency switching transitions from coupling into low-noise supplies. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 353 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com vdd_mpu vss vdd PCB_PO_8 Figure 8-8. Coplanar Shielding of Power Net Using Ground Guard-band 8.2.3 Step 3: Static Analysis Delivering reliable power to circuits is always of critical importance because voltage drops (also known as IR drops) can happen at every level within an electronic system, on-chip, within a package, and across the board. Robust system performance can only be ensured by understanding how the system elements will perform under typical stressful Use Cases. Therefore, it is a good practice to perform a Static or DC Analysis. Static or DC analysis and design methodology results in a PDN design that minimizes voltage or IR drops across power and ground planes, traces and vias. This ensures the application processor’s internal transistors will be operating within their specified voltage ranges for proper functionality. The amount of IR drop that will be encounter is based upon amount power drawn for a desired Use Case and PCB trace (widths, geometry and number of parallel traces) and via (size, type and number) characteristics. Components that are distant from their power source are particularly susceptible to IR drop. Designs that rely on battery power must minimize voltage drops to avoid unacceptable power loss that can negatively impact system performance. Early assessments a PDN’s static (DC) performance helps to determine basic power distribution parameters such as best system input power point, optimal PCB layer stackup, and copper area needed for load currents. The resistance Rs of a plane conductor for a unit length and unit width is called the surface resistivity (ohms per square). L r 1 = σ ×t t l R = Rs × w Rs = W t SWPS040-178 Figure 8-9. Depiction of Sheet Resistivity and Resistance Ohm’s Law (V = I × R) relates conduction current to voltage drop. At DC, the relation coefficient is a constant and represents the resistance of the conductor. Even current carrying conductors will dissipate power at high currents even though their resistance may be very small. Both voltage drop and power dissipation are proportional to the resistance of the conductor. Figure 8-10 shows a PCB-level static IR drop budget defined between the power management device (PMIC) pins and the application processor’s balls when the PMIC is supplying power. • It is highly recommended to physically place the PMIC as close as possible to the processor and on the same side. The orientation of the PMIC vs. processor should be aligned to minimize distance for the highest current rail. 354 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 PCB Static IR drop and Effective Resistance Load Component Source Component BGA pad on PCB PCB_PO_10 Figure 8-10. Static IR Drop Budget for PCB Only The system-level IR drop budget is made up of three portions: on-chip, package, and PCB board. Static IR or DC analysis/design methodology consists of designing the PDN such that the voltage drop (under DC operating conditions) across power and ground pads of the transistors of the application processor device is within a specified value of the nominal voltage for proper functionality of the device. A PCB system-level voltage drop budget for proper device functionality is typically 1.5% of nominal voltage. For a 1.35-V supply, this would be ≤20 mV. To accurately analyze PCB static IR drop, the actual geometry of the PDN must be modeled properly and simulated to accurately characterize long distribution paths, copper weight impacts, electro-migration violations of current-carrying vias, and “Swiss-cheese” effects via placement has on power rails. It is recommended to perform the following analyses: • Lumped resistance/IR drop analysis • Distributed resistance/IR drop analysis NOTE The PMIC companion device supporting Processor has been designed with voltage sensing feedback loop capabilities that enable a remote sense of the SMPS output voltage at the point of use. The NOTE above means the SMPS feedback signals and returns must be routed across PCB and connected to the Device input power ball for which a particular SMPS is supplying power. This feedback loop provides compensation for some of the voltage drop encountered across the PDN within limits. As such, the effective resistance of the PDN within this loop should be determined in order to optimize voltage compensation loop performance. The resistance of two PDN segments are of interest: one from the power inductor/bulk power filtering capacitor node to the Processor’s input power and second is the entire PDN route from SMPS output pin/ball to the Processor input power. In the following sections each methodology is described in detail and an example has been provided of analysis flow that can be used by the PCB designer to validate compliance to the requirements on their PCB PDN design. 8.2.3.1 PDN Resistance and IR Drop Lumped methodology consists of grouping all of the power pins on both the PMIC (voltage source) and processor (current sink) devices. Then the PMIC source is set to an expected Use Case voltage level and the processor load has its Use Case current sink value set as well. Now the lumped/effective resistance for the power rail trace/plane routes can be determine based upon the actual layout’s power rail etch wide, shape, length, via count and placement Figure 8-11 illustrates the pin-grouping/lumped concept. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 355 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com The lumped methodology consists of importing the PCB layout database (from Cadence Allegro tool or any other layout design tool) into the static IR drop modeling and simulation tool of preference for the PCB designer. This is followed by applying the correct PCB stack-up information (thickness, material properties) of the PCB dielectric and metallization layers. The material properties of dielectric consist of permittivity (Dk) and loss tangent (Df). For the conductor layers, the correct conductivity needs to be programmed into the simulation tool. This is followed by pin-grouping of the power and ground nets, and applying appropriate voltage/current sources. The current and voltage information can be obtained from the power and voltage specifications of the device under different operating conditions / Use Cases. Sources Multiport net Sources Branch Grouped Power/Ground pins to create 1 equivalent resistive branch Port/Pin Sinks Sinks SWPS040-179 Figure 8-11. Pin-grouping concept: Lumped and Distributed Methodologies 8.2.4 Step 4: Frequency Analysis Delivering low noise voltage sources are very important to allowing a system to operate at the lowest possible Operational Performance Point (OPP) for any one Use Case. An OPP is a combination of the supply voltage level and clocking rate for key internal processor domains. A SCH and PCB designed to provide low noise voltage supplies will then enable the processor to enter optimal OPPs for each Use Case that in turn will minimize power dissipation and junction temperatures on-die. Therefore, it is a good engineering practice to perform a Frequency Analysis over the key power domains. Frequency analysis and design methodology results in a PDN design that minimizes transient noise voltages at the processor’s input power balls. This allows the processor’s internal transistors to operate near the minimum specified operating supply voltage levels. To accomplish this one must evaluate how a voltage supply will change due to impedance variations over frequency. This analysis will focus on the decoupling capacitor network (VDD_xxx and VSS/Gnd rails) at the load. Sufficient capacitance with a distribution of self-resonant points will provide for an overall lower impedance vs frequency response for each power domain. Decoupling components that are distant from their load’s input power are susceptible to encountering spreading loop inductance from the PCB design. Early analysis of each key power domain’s frequency response helps to determine basic decoupling capacitor placement, optimal footprint, layer assignment, and types needed for minimizing supply voltage noise/fluctuations due to switching and load current transients. NOTE Evaluation of loop inductance values for decoupling capacitors placed ~300mils closer to the load’s input power balls has shown an 18% reduction in loop inductance due to reduced distance. • 356 Decoupling capacitors must be carefully placed in order to minimize loop inductance impact on supply voltage transients. A real capacitor has characteristics not only of capacitance but also inductance and resistance. Figure 8-12 shows the parasitic model of a real capacitor. A real capacitor must be treated as an RLC circuit with effective series resistance (ESR) and effective series inductance (ESL). Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 C ESL ESR SWPS040-175 Figure 8-12. Characteristics of a Real Capacitor With ESL and ESR The magnitude of the impedance of this series model is given as: Z = 1 ö æ ESR 2 +ωESL ç ωESL - ωC ÷ ø è 2 where : w = 2π¦ SWPS040-e002 Figure 8-13. Series Model Impedance Equation Figure 8-14 shows the resonant frequency response of a typical capacitor with a self-resonant frequency of 55 MHz. The impedance of the capacitor is a combination of its series resistance and reactive capacitance and inductance as shown in the equation above. S-Parameter Magnitude Job: GCM155R71E153KA55_15NF; 1.0e+01 1.0e+00 1.0e–01 1.0e–02 XC=1/ωC XL=ωL 1.0e–03 Resonant frequency (55 MHz) (minimum) 1.0e–04 1.00e–002 1.00e+000 1.00e+002 1.00e+004 1.00e+006 1.00e+008 Frequency (MHz) SWPS040-176 Figure 8-14. Typical Impedance Profile of a Capacitor Because a capacitor has series inductance and resistance that impacts its effectiveness, it is important that the following recommendations are adopted in placing capacitors on the PDN. Wherever possible, mount the capacitor with the geometry that minimizes the mounting inductance and resistance. This was shown earlier in Figure 8-1. The capacitor mounting inductance and resistance values include the inductance and resistance of the pads, trace, and vias. Whenever possible, use footprints that have the lowest inductance configuration as shown in Figure 8-15 Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 357 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com The length of a trace used to connect a capacitor has a big impact on parasitic inductance and resistance of the mounting. This trace must be as short and as wide as possible. wherever possible, minimize distance to supply and Gnd vias by locating vias nearby or within the capacitor’s solder pad landing. Further improvements can be made to the mounting by placing vias to the side of capacitor lands or doubling the number of vias as shown in Figure 8-15. If the PCB manufacturing processes allow it and if cost-effective, via-in-pad (VIP) geometries are strongly recommended. In addition to mounting inductance and resistance associated with placing a capacitor on the PCB, the effectiveness of a decoupling capacitor also depends on the spreading inductance and resistance that the capacitor sees with respect to the load. The spreading inductance and resistance is strongly dependent on the layer assignment in the PCB stack-up. Therefore, try to minimize X, Y and Z dimensions where the Z is due to PCB thickness (as shown in Figure 8-2). From left (highest inductance) to right (lowest inductance) the capacitor footprint types shown in Figure 815 are known as: • 2-via, Skinny End Exit (2vSEE) • 2-via, Wide End Exit (2vWEE) • 2-via, Wide Side Exit (2vWSE) • 4-via, Wide Side Exit (4vWSE) • 2-via, In-Pad (2vIP) Via Via-in-pad Pad Trace Mounting geometry for reduced inductance SWPS040-177 Figure 8-15. Capacitor Placement Geometry for Improved Mounting Inductance NOTE Evaluation of loop inductance values for decoupling capacitor footprints 2vSEE (worst case) vs 4vWSE (2nd best) has shown a 30% reduction in inductance when 4vWSE footprint was used in place of 2vSEE. Decoupling Capacitor (Dcap) Strategy: 1. Use lowest inductance footprint and trace connection scheme possible for given PCB technology and layout area in order to minimize Dcap loop inductance to power pin as much as possible (see Figure 815). 2. Place Dcaps on “same-side” as component within their power plane outline to minimize “decoupling loop inductance”. Target distance to power pin should be less than ~500mils depending upon PCB layout characteristics (plane's layer assignment and solid nature). Use PI modeling CAD tool to verify 358 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 minimum inductance for top vs bottom-side placement. 3. Place Dcaps on “opposite-side” as component within their power plane outline if “same-side” is not feasible or if distance to power pin is greater than ~500mils for top-side location. Use PI modeling CAD tool to verify minimum inductance for top vs bottom-side placement. 4. Use minimum 10mil trace width for all voltage and gnd planes connections (i.e. Dcap pads, component power pins, etc.). 5. Place all voltage and gnd plane vias “as close as possible” to point of use (i.e. Dcap pads, component power pins, etc.). 6. Use a “Power/Gnd pad/pin to via” ratio of 1:1 whenever possible. Do not exceed 2:1 ratio for small number of vias within restricted PCB areas (i.e. underneath BGA components). Frequency analysis for the MPU power domain has yielded the vdd_mpu Impedance vs Frequency response shown in Section 8.3.7.2, vdd_mpu Example Analysis. As the example shows the overall MPU PDN Reff meets the maximum recommended PDN resistance of 10mΩ. 8.2.5 System ESD Generic Guidelines 8.2.5.1 System ESD Generic PCB Guideline Protection devices must be placed close to the ESD source which means close to the connector. This allows the device to subtract the energy associated with an ESD strike before it reaches the internal circuitry of the application board. To help minimize the residual voltage pulse that will be built-up at the protection device due to its nonzero turn-on impedance, it is mandatory to route the ESD device with minimum stub length so that the lowresistive, low-inductive path from the signal to the ground is granted and not increasing the impedance between signal and ground. For ESD protection array being railed to a power supply when no decoupling capacitor is available in close vicinity, consider using a decoupling capacitor (≥ 0.1 µF) tight to the VCC pin of the ESD protection. A positive strike will be partially diverted to this capacitance resulting in a lower residual voltage pulse. Ensure that there is sufficient metallization for the supply of signals at the interconnect side (VCC and GND in Figure 8-16) from connector to external protection because the interconnect may see between 15A to 30-A current in a short period of time during the ESD event. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 359 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Bypass capacitor 0.1 mf (minimum) Stub inductance Connector Stub inductance Interconnection inductance vcc Signal VCC VCC Protected circuit Stub inductance Minimize such inductance by optimizing layout ESD strike External protection Ground inductance Keep distance between protected circuit and external protection Signal Keep external protection closed by connector SPRABP6-004 Figure 8-16. Placement Recommendation for an ESD External Protection NOTE To ensure normal behavior of the ESD protection (unwanted leakage), it is better to ground the ESD protection to the board ground rather than any local ground (example isolated shield or audio ground). 8.2.5.2 • • • • • • • • 360 Miscellaneous EMC Guidelines to Mitigate ESD Immunity Avoid running critical signal traces (clocks, resets, interrupts, control signals, and so forth) near PCB edges. Add high frequency filtering: Decoupling capacitors close to the receivers rather than close to the drivers to minimize ESD coupling. Put a ground (guard) ring around the entire periphery of the PCB to act as a lightning rod. Connect the guard ring to the PCB ground plane to provide a low impedance path for ESD-coupled current on the ring. Fill unused portions of the PCB with ground plane. Minimize circuit loops between power and ground by using multilayer PCB with dedicated power and ground planes. Shield long line length (strip lines) to minimize radiated ESD. Avoid running traces over split ground planes. It is better to use a bridge connecting the two planes in one area. Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 BAD BETTER SWPS040-220 • 8.2.6 Figure 8-17. Trace Examples Always route signal traces and their associated ground returns as close to one another as possible to minimize the loop area enclosed by current flow: – At high frequencies current follows the path of least inductance. – At low frequencies current flows through the path of least resistance. EMI / EMC Issues Prevention All high-speed digital integrated circuits can be sources of unwanted radiation, which can affect nearby sensitive circuitry and cause the final product to have radiated emissions levels above the limits allowed by the EMC regulations if some preventative steps are not taken. Likewise, analog and digital circuits can be susceptible to interference from the outside world and picked up by the circuitry interconnections. To minimize the potential for EMI/EMC issues, the following guidelines are recommended to be followed. 8.2.6.1 Signal Bandwidth To evaluate the frequency of a digital signal, an estimated rule of thumb is to consider its bandwidth fBW with respect to its rise time, tR: fBW ≈ 0.35 / tR This frequency actually corresponds to the break point in the signal spectrum, where the harmonics start to decay at 40 dB per decade instead of 20 dB per decade. 8.2.6.2 Signal Routing 8.2.6.2.1 Signal Routing—Sensitive Signals and Shielding Keep radio frequency (RF) sensitive circuitry (like GPS receivers, GSM/WCDMA, Bluetooth/WLAN transceivers, frequency modulation (FM) radio) away from high-speed ICs (the device, power and audio manager, chargers, memories, and so forth) and ideally on the opposite side of the PCB. For improved protection it is recommended to place these emission sources in a shield can. If the shield can have a removable lid (two-piece shield), ensure there is low contact impedance between the fence and the lid. Leave some space between the lid and the components under it to limit the high-frequency currents induced in the lid. Limit the shield size to put any potential shield resonances above the frequencies of interest; see Figure 8-14, Typical Impedance Profile of a Capacitor. 8.2.6.2.2 Signal Routing—Outer Layer Routing In case there is a need to use the outer layers for routing outside of shielded areas, it is recommended to route only static signals and ensure that these static signals do not carry any high-frequency components (due to parasitic coupling with other signals). In case of long traces, make provision for a bypass capacitor near the signal source. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 361 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Routing of high-frequency clock signals on outer layers, even for a short distance, is discouraged, because their emissions energy is concentrated at the discrete harmonics and can become significant even with poor radiators. Coplanar shielding of traces on outer layers (placing ground near the sides of a track along its length) is effective only if the distance between the trace sides and the ground is smaller that the trace height above the ground reference plane. For modern multilayer PCBs this is often not possible, so coplanar shielding will not be effective. Do not route high-frequency traces near the periphery of the PCB, as the lack of a ground reference near the trace edges can increase EMI: see Section 8.2.6.3, Ground Guidelines. 8.2.6.3 Ground Guidelines 8.2.6.3.1 PCB Outer Layers Ideally the areas on the top and bottom layers of the PCB that are not enclosed by a shield should be filled with ground after the routing is completed and connected with an adequate number of vias to the ground on the inner ground planes. 8.2.6.3.2 Metallic Frames Ensure that all metallic parts are well connected to the PCB ground (like LCD screens metallic frames, antennas reference planes, connector cages, flex cables grounds, and so forth). If using flex PCB ribbon cables to bring high-frequency signals off the PCB, ensure they are adequately shielded (coaxial cables or flex ribbons with a solid reference ground). 8.2.6.3.3 Connectors For high-frequency signals going to connectors choose a fully shielded connector, if possible (for example, SD card connectors). For signals going to external connectors or which are routed over long distances, it is recommended to reduce their bandwidth by using low-pass filters (resistor, capacitor (RC) combinations or lossy ferrite inductors). These filters will help to prevent emissions from the board and can also improve the immunity from external disturbances. 8.2.6.3.4 Guard Ring on PCB Edges The major advantage of a multilayer PCB with ground-plane is the ground return path below each and every signal or power trace. As shown in Figure 8-18 the field lines of the signal return to PCB ground as long as an infinite ground is available. Traces near the PCB-edges do not have this infinite ground and therefore may radiate more than the others. Thus, signals (clocks) or power traces (core power) identified to be critical must not be routed in the vicinity of PCB edges, or, if not avoidable, must be accompanied by a guard ring on the PCB edge. SWPS040-199 Figure 8-18. Field Lines of a Signal Above Ground 362 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Signal Power Ground Signal SWPS040-200 Figure 8-19. Guard Ring Routing The intention of the guard ring is that HF-energy, that otherwise would have been emitted from the PCB edge, is reflected back into the board where it partially will be absorbed. For this purpose ground traces on the borders of all layers (including power layer) must be applied as shown in Figure 8-19. As these traces must have the same (HF–) potential as the ground plane they must be connected to the ground plane at least every 10 mm. 8.2.6.3.5 Analog and Digital Ground For the optimum solution, the AGND and the DGND planes must be connected together at the power supply source in a same point. This ensures that both planes are at the same potential, while the transfer of noise from the digital to the analog domain is minimized. 8.3 Core Power Domains This section provides boundary conditions and theoretical background to be applied as a guide for optimizing a PCB design. The decoupling capacitor and PDN characteristics tables shown below give recommended capacitors and PCB parameters to be followed for schematic and PCB designs. Board designs that meet the static and dynamic PDN characteristics shown in tables below will be aligned to the expected PDN performance needed to optimize SoC performance. 8.3.1 General Constraints and Theory • • • • • • • Max PCB static/DC voltage drop (IRd) budget of 1.5% of supply voltage when using PMICs without remote sensing as measured from PMIC’s power inductor and filter capacitor node to Processor input including any ground return losses. Max PCB static/DC voltage drop (IRd) budget can be relaxed to 5% of supply voltage when using PMICs with remote sensing at the load as measured from PMIC’s power inductor and filter capacitor node to Device’s supply input including any ground return losses. PMIC component DM and guidelines should be referenced for the following: – Routing remote feedback sensing to optimize per each SMPS’s implementation – Selecting power filtering capacitor values and PCB placement. Max Effective Resistance (Reff) budget can range from 4 – 50mΩ for key Device power rails not including ground returns depending upon maximum load currents and maximum DC voltage drop budget (as discussed above). Max Device supply input voltage difference budget of 5mV under max current loading shall be maintained across all balls connected to a common power rail. This represents any voltage difference that may exist between a remote sense point to any power input. Max PCB Loop Inductance (LL) budget between Device’s power inputs and local bulk and high frequency decoupling capacitors including ground returns should range from 0.4 – 2.5nH depending upon maximum transient load currents. Max PCB dynamic/AC peak-to-peak transient noise voltage budgets between PMIC and Device including ground returns are as follows: – +/-3% of nominal supply voltage for frequencies below the PMIC bandwidth (typ Fpmic ~ 200kHz) – +/-5% of nominal supply voltage for frequencies between Fpmic to Fpcb (typ 20 – 100MHz) Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 363 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 • www.ti.com Max PCB Impedance (Z) vs Frequency (F) budget between Device’s power inputs and PMIC’s output power filter node including ground return is determined by applying the Frequency Domain Target Impedance Method to determine the PCB’s maximum frequency of interest (Fpcb). Ideally a properly designed and decoupled PDN will exhibit smoothly increasing Z vs. F curve. There are 2 general regions of interest as can be seen in Figure 8-20. – 1st area is from DC (0Hz) up to Fpmic (typ a few 100 kHz) where a PMIC’s transient response characteristic (i.e. Switching Freq, Compensation Loop BW) dominate. A PDN’s Z is typically very low due to power filtering & bulk capacitor values when PDN has very low trace resistance (i.e. good Reff performance). The goal is to maintain a smoothly increasing Z that is less than Zt1 over this low frequency range. This will ensure that a max transient current event will not cause a voltage drop more than the PMIC’s current step response can support (typ 3%). – 2nd area is from Fpmic up to Fpcb (typ 20-100MHz) where a PCB’s inherent characteristics (i.e. parasitic capacitance, planar spreading inductances) dominate. A PDN’s Z will naturally increase with frequency. At frequencies between Fpmic up to Fpcb, the goal is to maintain a smoothly increasing Z to be less than Zt2. This will ensue that the high frequency content of a max transient current event will not cause a voltage drop to be more than 5% of the min supply voltage. Figure 8-20. PDN’s Target impedance 1.Voltage Rail Drop includes regulation accuracy, voltage distribution drops, and all dynamic events such as transient noise, AC ripple, voltage dips etc. 364 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 2.Typical max transient current is defined as 50% of max current draw possible. 8.3.2 Voltage Decoupling Recommended power supply decoupling capacitors main characteristics for commercial products whose ambient temperature is not to exceed +85C are shown in table below: Table 8-1. Commercial Applications Recommended Decoupling Capacitors Characteristics(1)(2)(3) Value Voltage [V] Package Stability Dielectric Capacitan ce Tolerance Temp Range [°C] Temp Sensitivity [%] REFERENCE 22µF 6,3 0603 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM188R60J226MEA0L 10µF 4,0 0402 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM155R60G106ME44 4.7µF 6,3 0402 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM155R60J475ME95 2.2µF 6,3 0402 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM155R60J225ME95 1µF 6,3 0201 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM033R60J105MEA2 470nF 6,3 0201 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM033R60G474ME90 220nF 6,3 0201 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM033R60J224ME90 100nF 6,3 0201 Class 2 X5R - / + 20% -55 to + 85 - / + 15 GRM033R60J104ME19 (1) Minimum value for each PCB capacitor: 100 nF. (2) Among the different capacitors, 470 nF is recommended (not required) to filter at 5-MHz to 10-MHz frequency range. (3) In comparison with the EIA Class 1 dielectrics, Class 2 dielectric capacitors tend to have severe temperature drift, high dependence of capacitance on applied voltage, high voltage coefficient of dissipation factor, high frequency coefficient of dissipation, and problems with aging due to gradual change of crystal structure. Aging causes gradual exponential loss of capacitance and decrease of dissipation factor. Recommended power supply decoupling capacitors main characteristics for automotive products are shown in table below: Table 8-2. Automotive Applications Recommended Decoupling Capacitors Characteristics (1)(2) Value Voltage [V] Package Stability Dielectric Capacitan ce Tolerance Temp Range [°C] Temp Sensitivity [%] REFERENCE 22µF 6,3 1206 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM31CR70J226ME23 10µF 6,3 0805 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM21BR70J106ME22 4.7µF 10 0805 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM21BC71A475MA73 2.2µF 6,3 0603 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM188R70J225ME22 1µF 16 0603 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM188R71C105MA64 470nF 16 0603 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM188R71C474MA55 220nF 25 0603 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM188L81C224MA37 100nF 16 0402 Class 2 X7R - / + 20% -55 to + 125 - / + 15 GCM155R71C104MA55 (1) Minimum value for each PCB capacitor: 100 nF. (2) Among the different capacitors, 470 nF is recommended (not required) to filter at 5-MHz to 10-MHz frequency range. 8.3.3 Static PDN Analysis One power net parameter derived from a PCB’s PDN static analysis is the Effective Resistance (Reff). This is the total PCB power net routing resistance that is the sum of all the individual power net segments used to deliver a supply voltage to the point of load and includes any series resistive elements (i.e. current sensing resistor) that may be installed between the PMIC outputs and Processor inputs. 8.3.4 Dynamic PDN Analysis Three power net parameters derived from a PCB’s PDN dynamic analysis are the Loop Inductance (LL), Impedance (Z) and PCB Frequency of Interest (Fpcb). Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 365 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 • • • www.ti.com LL values shown are the recommended max PCB trace inductance between a decoupling capacitor’s power supply and ground reference terminals when viewed from the decoupling capacitor with a “theoretical shorted” applied across the Processor’s supply inputs to ground reference. Z values shown are the recommended max PCB trace impedances allowed between Fpmic up to Fpcb frequency range that limits transient noise drops to no more than 5% of min supply voltage during max transient current events. Fpcb (Frequency of Interest) is defined to be a power rail’s max frequency after which adding a reasonable number of decoupling capacitors no longer significantly reduces the power rail impedance below the desired impedance target (Zt2). This is due to the dominance of the PCB’s parasitic planar spreading and internal package inductances. Table 8-3. Recommended PDN and Decoupling Characteristics PDN Analysis: Static Supply Max Reff (7) [mΩ] Dynamic (1)(2)(3)(4)(5) Number of Recommended Decoupling Capacitors per Supply Dec. Cap. Max LL(8) (6) [nH] Impedance [mΩ] Frequency of Interest [MHz] 100 nF(6) 220 nF 470 nF 1μF 2.2 μF 4.7 μF 10 μF 22 μF vdd_mpu 10 2 57 20 12 2 2 3 1 1 vdd_dspeve 13 2.5 54 20 8 1 1 2 1 1 vdd 27 2 87 50 6 1 1 1 1 1 vdd_gpu 18 2.5 207 50 6 1 1 1 1 1 vdd_iva 48 2 800 100 5 vdds_ddr1 10 2.5 200 100 8 4 2 2 1 vdds_ddr2 10 2.5 200 100 8 4 2 2 1 cap_vbbldo_dsp eve N/A 6 N/A N/A cap_vbbldo_gpu N/A 6 N/A N/A cap_vbbldo_iva N/A 6 N/A N/A cap_vbbldo_mpu N/A 6 N/A N/A cap_vddram_cor e1 N/A 6 N/A N/A cap_vddram_cor e2 N/A 6 N/A N/A cap_vddram_cor e3 N/A 6 N/A N/A cap_vddram_cor e4 N/A 6 N/A N/A cap_vddram_cor e5 N/A 6 N/A N/A cap_vddram_dsp eve1 N/A 6 N/A N/A cap_vddram_dsp eve2 N/A 6 N/A N/A cap_vddram_gpu N/A 6 N/A N/A cap_vddram_iva N/A 6 N/A N/A cap_vddram_mp u1 N/A 6 N/A N/A cap_vddram_mp u2 N/A 6 N/A N/A 1 1 1 1 (1) For more information on peak-to-peak noise values, see the Recommended Operating Conditions table of the Specifications chapter. (2) ESL must be as low as possible and must not exceed 0.5 nH. (3) The PDN (Power Delivery Network) impedance characteristics are defined versus the device activity (that runs at different frequency) based on the Recommended Operating Conditions table of the Specifications chapter. (4) The static drop requirement drives the maximum acceptable PCB resistance between the PMIC or the external SMPS and the processor 366 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 power balls. (5) Assuming that the external SMPS (power IC) feedback sense is taken close to processor power balls. (6) High-frequency (30 to 70MHz) PCB decoupling capacitors (7) Maximum Reff from SMPS to Processor. (8) Maximum Loop Inductance for decoupling capacitor. NOTE For power IC which can support more than 10µF close to processor, a bulk capacitor of at least 22µF is strongly recommended for VDD_MPU power domains. 8.3.5 Power Supply Mapping TPS65917 or TPS659039 are the Power Management ICs (PMICs) that should be used for the Device designs. TI requires use of these PMICs for the following reasons: • TI has validated their use with the Device • Board level margins including transient response and output accuracy are analyzed and optimized for the entire system • Support for power sequencing requirements (refer to Section 5.9 Power Supply Sequences) • Support for Adaptive Voltage Scaling (AVS) Class 0 requirements, including TI provided software Whenever we allow for combining of rails mapped on any of the SMPSes, the PDN guidelines that are the most stringent of the rails combined should be implemented for the particular supply rail. It is possible that some voltage domains on the device are unused in some systems. In such cases, to ensure device reliability, it is still required that the supply pins for the specific voltage domains are connected to some core power supply output. These unused supplies though can be combined with any of the core supplies that are used (active) in the system. e.g. if IVA and GPU domains are not used, they can be combined with the CORE domain, thereby having a single power supply driving the combined CORE, IVA and GPU domains. For the combined rail, the following relaxations do apply: • The AVS voltage of active rail in the combined rail needs to be used to set the power supply • The decoupling capacitance should be set according to the active rail in the combined rail Table 8-4 illustrates the approved and validated power supply connections to the Device for the SMPS outputs of the TPS659039 PMIC. Table 8-4. TPS659039 Power Supply Connections(1) SMPS Valid Combination 1: Reference Platform Valid Combination 2: MPU Centric Valid Combination 3: DSPEVE Centric(3) Valid Combination 4: IVA Centric TPS659039 Current Rating Limitation (4) vdd_mpu vdd_mpu vdd_mpu, vdd_gpu, vdd_iva vdd_mpu SMPS12: 6A SMPS123: 9A SMPS3(2) Free (DDR Memory) Free (DDR Memory) Free (DDR Memory) Free (DDR Memory) SMPS3: 3A SMPS4/5 vdd_dspeve vdd_dspeve, vdd_gpu, vdd_iva vdd_dspeve vdd_dspeve, vdd_gpu SMPS45: 4A SMPS6 vdd_gpu vdd vdd vdd SMPS6: 2-3A (BOOST_CURRENT =0/1) SMPS7 vdd Free Free Free 2A SMPS8 vdd_iva Free Free vdd_iva 1A SMPS9 vdds18v vdds18v vdds18v vdds18v 1A (2) SMPS1/2/3 (5) Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 367 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) Power consumption is highly application-specific. Separate analysis must be performed to ensure output current ratings (average and peak) is within the limits of the PMIC for all rails of the device (2) Dual phase (SMPS1/2) can be used as long as the peak power consumption is maintained below the SMPS1/2 capacity (a) For the latest rated output current specifications for the TPS659039 device, please refer to the PMIC data manual. (b) MPU power consumption is highly system dependent. A detailed power consumption estimate must be performed to confirm compatibility. Example: Single vs Dual MPU, OPP_NOM vs OPP_OD vs OPP_HIGH, TPS659039 configured with VI≥3V vs VI<3V, etc. Contact your TI representative for details. (3) Combination 3 must only be used in systems where the MPU frequency is 1 GHz or lower. If greater than 1 GHz MPU is required, then the vdd_mpu domain must be powered independently. (4) Refer to the PMIC data manual for the latest TPS659039 specifications (5) A product’s maximum ambient temperature, thermal system design & heat spreading performance could limit the maximum power dissipation below the full PMIC capacity in order to not exceed recommended SoC max Tj Table 8-5 illustrates the approved and validated power supply connections to the Device for the SMPS outputs of the TPS65917 PMIC. Table 8-5. TPS65917 Power Supply Connections TPS65917 Valid Combination 1: Valid Combination 2 TPS65917 Current Rating Limitation (1) (3) SMPS1 vdd_mpu vdd_mpu SMPS1: 3.5A ≤ OPP_NOM (dual or single) OR ≤ OPP_OD (single ONLY) 3.5A SMPS2 (2) vdd_dspeve, vdd_gpu, vdd_iva vdd SMPS3 (2) vdd vdd_dspeve, vdd_gpu, vdd_iva 3A SMPS4 (3) vdds18v vdds18v 1.5A SMPS5 (4) Free (DDR Memory) Free (DDR Memory) 2A (1) Refer to the TPS65917 Data Manual for exact current rating limitations, including assumed VIN and other parameters. Values provided in this table are for comparison purposes. (2) DSP, EVE, GPU, and IVAHD power consumption is highly application-specific. Separate analysis must be performed to ensure output current ratings (average and peak) is within the limits of the PMIC. VDD only supports OPP_NOM. (3) Highly application-specific. Separate analysis must be performed to ensure average and peak power is within the limits of the PMIC. (4) Furthermore, if SMPS5 is used for DDR power, both total memory + SoC power must be within the PMIC limits. 8.3.6 DPLL Voltage Requirement The voltage input to the DPLLs has a low noise requirement. Board designs should supply these voltage inputs with a low noise LDO to ensure they are isolated from any potential digital switching noise. The TPS65917 and TPS659039 PMIC LDOLN outputs are specifically designed to meet this low noise requirement. NOTE For more information about Input Voltage Sources, see Section 6.2 DPLLs, DLLs Specifications. Table 8-4 presents the voltage inputs that supply the DPLLs. Table 8-6. Input Voltage Power Supplies for the DPLLs 368 POWER SUPPLY DPLLs vdda_abe_per DPLL_PER, DPLL_ABE and PER HSDIVIDER analog power supply vdda_ddr DPLL_DDR and DDR HSDIVIDER analog power supply vdda_debug DPLL_DEBUG analog power supply vdda_dsp_eve DPLL_DSP and DPLL_EVE analog power supply vdda_gmac_core DPLL_CORE and HSDIVIDER analog power supply vdda_gpu DPLL_GPU analog power supply vdda_iva DPLL_IVA analog power supply Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 8-6. Input Voltage Power Supplies for the DPLLs (continued) 8.3.7 POWER SUPPLY DPLLs vdda_video DPLL_VIDEO1 and DPLL_VIDEO2 analog power supply vdda_mpu DPLL_MPU analog power supply vdda_osc not DPLL input but is required to be supplied by low noise input voltage Example PCB Design The following sections describe an example PCB design and its resulting PDN performance for the vdd_mpu key processor power domain. 8.3.7.1 Example Stack-up Layer Assignments: • Layer Top: Signal and Segmented Power Plane – Processor and PMIC components placed on Top-side • Layer 2: Gnd Plane1 • Layer 3: Signals • Layer n: Power Plane1 • Layer n+1: Power Plane 2 • Layer n+2: Signal • Layer n+3: Gnd Plane2 • Layer Bottom: Signal and Segmented Power Planes – Decoupling caps, etc. Via Technology: Through-hole Copper Weight: • ½ oz for all signal and plane layers other thanGnd Plane1 and Gnd Plane2 set to 2oz for improved thermal heat spreading • Total PCB Thickness 0.080inches 8.3.7.2 vdd_mpu Example Analysis Maximum acceptable PCB resistance (Reff) between the PMIC and Processor input power balls should not exceed 10mΩ. Maximum decoupling capacitance loop inductance (LL) between Processor input power balls and decoupling capacitances should not exceed 2.0nH (ESL NOT included) Impedance target for key frequency of interest between Processor input power balls and PMIC’s SMPS output power balls should not exceed 57mΩ at 20MHz. Table 8-7. Example PCB vdd_mpu PI Analysis Summary Parameter Recommendation Processor OPP High Clocking Rate 1.5 GHz Example PCB Voltage Level 1.22V 1.22V Max Current Draw 5.12 A 5.12 A Max Effective Resistance: Power Inductor Segment Total Reff 10mΩ 9.0mΩ Max Loop Inductance 2.0nH 1.0 – 1.4nH Impedance Target 57mΩ F<20Mhz 57mΩ F<20Mhz Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 369 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Figure 8-21, Figure 8-22, Figure 8-23, and Figure 8-24 show a PCB layout example and the resulting PI analysis results. U45 PMIC SMPS (3000mA) SW1 SMPS1_SW L17 1.0uH, 4.5A, 1616 IHLP-1616ABER1R0M11 PCB – Top-side C410 22uF, 4V, 0603 GRM188R60G226MEA0L PCB – Bottom-side (E11, E12, E13) SMPS2 (3000mA) SMPS1_SW SW2 U52 R181 0.001ohm, 1%, 4W, 2725 CSS2725FT1L00 PCB – Top-side 6A C365, 366, 368, 369, 370, 384, 385, 387, 389, 391, 392, 396 0.1uF, 6.3V, X5R, 0201 GRM033R60J104KE19D PCB – Bottom-side C378 22uF, 4V, 0603 GRM188R60G226MEA0L PCB – Bottom-side SMPS3 (3000mA) SW3 Device SoC vdd_mpu vdd_mpu (N18, K18, L19 L15 1.0uH, 4.5A, 1616 IHLP-1616ABER1R0M11 PCB – Top-side (E11, E12, E13) SMPS1_SW SMPS_1_2_3 N17, M17, L17 M18, L18, P18 K17, L15, L16 M15, M16, P17 R18) C92, 96 0.22uF, 6.3V, X5R, 0201 ECJ-ZEB0J224M PCB – Top-side L13x 1.0uH, 4.5A, 1616 IHLP-1616ABER1R0M11 PCB – Top-side C93, 94 (E11, E12, E13) 0.47uF, 4V, X5R, 0201 AMK063BJ474MP-F PCB – Top-side C350 22uF, 4V, 0603 GRM188R60G226MEA0L PCB – Bottom-side C91, 95, 367 PS_EVM_3V3 1.0uF, 6.3V, X5R, 0201 GRM033R60J105MEA2D PCB – 2 Top-side & 1 Bottom U39 INA226 A0 VIN+ C359 A1 VIN- 2.2uF, 6.3V, X5R, 0402 C1005X5R0J225M PCB – Bottom-side PM I2C Addr: 100 0001 C360 4.7uF, 6.3V, X5R, 0402 GRM155R60J475ME8 7D PCB – Bottom-side C356 22uF, 4V, X5R, 0603 GRM188R60G226ME A0L PCB – Bottom-side Figure 8-21. vdd_mpu Simplified SCH Diagram Sense Resistor (R181; 2725) PMIC (U45) Device (U52) Power Inductors (L13, 15 & 17; 1616) vdd_mpu “Ball-Field” Top -side segmented planes (vdd_mpu = Green) 4 of 22 Decoupling Caps (C96, 385, 387, 389; 0201) Multiple vias connecting power segments on different layers Figure 8-22. vdd_mpu routing [Top Layer] 370 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Interior Power Plane #2, Layer 9 of 16 (vdd_mpu = Green) Figure 8-23. vdd_mpu routing [Internal Power Plane #2] Bulk Caps underneath power inductors (C410, C378, C350; 0603) Larger Value Decoupling Caps (2.2uF C359, 4.7uF C360 & 22uF C356; 0402 & 0603) Remaining 15 of 22 Decoupling Caps (C96, 385, 387, 389; 0201) PCB_CPD_4 Figure 8-24. vdd_mpu routing and cap placements [Bottom Layer] Table 8-8. PCB Etch Resistance Breakdown - From PMIC Source to Device Load Net[from] Component [from]: Net[to] Component [to]: Etch Resistance (Ω) % of Total Etch Resistance SW1 L17 SW1 U45 0,001038 13% SW2 L15 SW2 U45 0,000898 12% SW3 L13 SW3 U45 0,000861 11% SW1 L17 SMPS_1_2_3 R181 0,000696 9% SW2 L15 SMPS_1_2_3 R181 0,000541 7% SW3 L13 SMPS_1_2_3 R181 0,000526 7% vdd_mpu R181 vdd_mpu U52 0,006311 78% vdd_mpu R181 vdd_mpu U52 0,006311 81% vdd_mpu R181 vdd_mpu U52 0,006311 82% Total Etch Resistance from SW1 = 0,008045 100% Total Etch Resistance from SW2 = 0,00775 100% Total Etch Resistance from SW3 = 0,007698 100% Max Value = 0,008045 Table 8-9. PCB Etch Resistance Breakdown - From Power Inductor to Device Load Net[from] Component [from]: Net[to] Component [to]: Etch Resistance (Ω) % of Total Etch Resistance SMPS_1_2_3 L17 SMPS_1_2_3 R181 0,000696 10% SMPS_1_2_3 L15 SMPS_1_2_3 R181 0,000541 8% SMPS_1_2_3 L13 SMPS_1_2_3 R181 0,000526 8% Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 371 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-9. PCB Etch Resistance Breakdown - From Power Inductor to Device Load (continued) Net[from] Component [from]: Net[to] Component [to]: Etch Resistance (Ω) % of Total Etch Resistance vdd_mpu R181 vdd_mpu U52 0,006311 90% vdd_mpu R181 vdd_mpu U52 0,006311 92% vdd_mpu R181 vdd_mpu U52 0,006311 92% Total Etch Resistance = 0,007007 100% Total Etch Resistance = 0,006852 100% Total Etch Resistance = 0,006837 100% Max Value = 0,007007 Table 8-10. PDN Effective Resistance - From PMIC Source to Device Load PDN Elements Etch Inductor Sense Resistor Max PDN Effectiv Resistance from Source IR • • • • PDN Effective Resistance (Ω) % of Total Etch Resistance 0,008045 89% 0 0% 0,001 11% 0,009045 100% Drop: vdd_mpu (PCB RevJan14, Sentinel PSI) Source Conditions: 1.22V @ 5,12A Recommended Reff < 10mΩ Reff = Total Trace Resistance + Sence Resistor = 8,04mΩ + 1mΩ = 9,04mΩ Voltage / IR Drop: 1,22 - 1,179 = 52,6 mV PCB_CPD_5 Figure 8-25. vdd_mpu Voltage/IR Drop [All Layers] Dynamic analysis of this PCB design for the MPU power domain determined the vdd_mpu decoupling capacitor loop inductance and impedance vs frequency analysis shown below. As you can see, the loop inductance values ranged from 1.0 to 1.4nH and were less than maximum 2.0nH recommended. 372 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 NOTE Comparing loop inductances for capacitors at different distances from the processor’s input power balls shows an 18% reduction for caps placed closer. This was derived by averaging the inductances for the 3 caps with distances over 800mils (Avg LL = 1.33nH) vs the 3 caps with distances less than 600mils (Avg LL = 1.096nH). Table 8-11. Rail - vdd_mpu Cap Ref Des Model Port # Loop Inductacne [nH] Footprint Types PCB Side Distance to Ball-Field [mils] Value [μF] Size C356 1 1,4 4vWSE Bottom 897 22 0603 C359 2 1,26 4vWSE Bottom 855 2,2 0402 C360 3 1,33 4vWSE Bottom 850 4,7 0402 C365 4 1,14 4vWSE Bottom 817 0,1 0201 C366 5 1,13 4vWSE Bottom 755 0,1 0201 C367 6 1,07 4vWSE Bottom 758 1 0201 C368 7 1,12 4vWSE Bottom 811 0,1 0201 C369 8 1,06 4vWSE Bottom 690 0,1 0201 C370 9 1,12 4vWSE Bottom 680 0,1 0201 C384 10 1,04 4vWSE Bottom 686 0,1 0201 C385 11 1,07 4vWSE Top 686 0,1 0201 C387 12 1,16 4vWSE Top 755 0,1 0201 C389 13 1,18 4vWSE Top 693 0,1 0201 C391 14 1,14 4vWSE Bottom 693 0,1 0201 C392 15 1,18 4vWSE Bottom 542 0,1 0201 C396 16 1,11 4vWSE Bottom 745 0,1 0201 C91 17 1,1 4vWSE Bottom 515 1 0201 C92 18 1,09 4vWSE Bottom 622 0,22 0201 C93 19 1,01 4vWSE Bottom 504 0,47 0201 C94 20 1,13 4vWSE Bottom 604 0,47 0201 C95 21 1,04 4vWSE Bottom 612 1 0201 C96 22 1,08 4vWSE Top 612 0,22 0201 Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 373 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Loop Inductance range: 1,01 - 1,40 nH PCB_CPD_6 Figure 8-26. vdd_mpu Decoupling Cap Loop Inductances Figure 8-27 shows vdd_mpu Impedance vs Frequency characteristics. 310mΩ @ 100MHz 30mΩ @ 10MHz 160mΩ @ 50MHz 56,6mΩ @ 20MHz PCB_CPD_7 Figure 8-27. vdd_mpu Impedance vs Frequency 8.4 8.4.1 Single-Ended Interfaces General Routing Guidelines The following paragraphs detail the routing guidelines that must be observed when routing the various functional LVCMOS interfaces. 374 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com • SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Line spacing: – For a line width equal to W, the spacing between two lines must be 2W, at least. This minimizes the crosstalk between switching signals between the different lines. On the PCB, this is not achievable everywhere (for example, when breaking signals out from the device package), but it is recommended to follow this rule as much as possible. When violating this guideline, minimize the length of the traces running parallel to each other (see Figure 8-28). W D+ S = 2 W = 200 µm SWPS040-185 • • • 8.4.2 Figure 8-28. Ground Guard Illustration Length matching (unless otherwise specified): – For bus or traces at frequencies less than 10 MHz, the trace length matching (maximum length difference between the longest and the shortest lines) must be less than 25 mm. – For bus or traces at frequencies greater than 10 MHz, the trace length matching (maximum length difference between the longest and the shortest lines) must be less than 2.5 mm. Characteristic impedance – Unless otherwise specified, the characteristic impedance for single-ended interfaces is recommended to be between 35-Ω and 65-Ω. Multiple peripheral support – For interfaces where multiple peripherals have to be supported in the star topology, the length of each branch has to be balanced. Before closing the PCB design, it is highly recommended to verify signal integrity based on simulations including actual PCB extraction. QSPI Board Design and Layout Guidelines The following section details the routing guidelines that must be observed when routing the QSPI interfaces. • The qspi1_sclk output signal must be looped back into the qspi1_rtclk input. • The signal propagation delay from the qspi1_sclk ball to the QSPI device CLK input pin (A to C) must be approximately equal to the signal propagation delay from the QSPI device CLK pin to the qspi1_rtclk ball (C to D). • The signal propagation delay from the QSPI device CLK pin to the qspi1_rtclk ball (C to D) must be approximately equal to the signal propagation delay of the control and data signals between the QSPI device and the SoC device (E to F, or F to E). • The signal propagation delay from the qspi1_sclk signal to the series terminators (R2 = 10 Ω) near the QSPI device must be < 450pS (~7cm as stripline or ~8cm as microstrip) • 50 Ω PCB routing is recommended along with series terminations, as shown in Figure 8-29. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 375 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 • www.ti.com Propagation delays and matching: – A to C = C to D = E to F. – Matching skew: < 60pS – A to B < 450pS – B to C = as small as possible (<60pS) Locate both R2 resistors close together near the QSPI device A B C R1 R2 0 Ω* 10 Ω R2 10 Ω qspi1_sclk QSPI device clock input D qspi1_rtclk E F QSPI deice IOx, CS# qspi1_d[x], qspi1_cs[y] PCB_QSPI_1 Figure 8-29. QSPI Interface High Level Schematic NOTE *0 Ω resistor (R1), located as close as possible to the qspi1_sclk pin, is placeholder for finetuning if needed. 8.5 8.5.1 Differential Interfaces General Routing Guidelines To maximize signal integrity, proper routing techniques for differential signals are important for high-speed designs. The following general routing guidelines describe the routing guidelines for differential lanes and differential signals. • As much as possible, no other high-frequency signals must be routed in close proximity to the differential pair. • Must be routed as differential traces on the same layer. The trace width and spacing must be chosen to yield the differential impedance value recommended. • Minimize external components on differential lanes (like external ESD, probe points). • Through-hole pins are not recommended. • Differential lanes mustn’t cross image planes (ground planes). • No sharp bend on differential lanes. 376 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com • • 8.5.2 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Number of vias on the differential pairs must be minimized, and identical on each line of the differential pair. In case of multiple differential lanes in the same interface, all lines should have the same number of vias. Shielded routing is to be promoted as much as possible (for instance, signals must be routed on internal layers that are inside power and/or ground planes). USB 2.0 Board Design and Layout Guidelines This section discusses schematic guidelines when designing a universal serial bus (USB) system. 8.5.2.1 Background Clock frequencies generate the main source of energy in a USB design. The USB differential DP/DM pairs operate in high-speed mode at 480 Mbps. System clocks can operate at 12 MHz, 48 MHz, and 60 MHz. The USB cable can behave as a monopole antenna; take care to prevent RF currents from coupling onto the cable. When designing a USB board, the signals of most interest are: • Device interface signals: Clocks and other signal/data lines that run between devices on the PCB. • Power going into and out of the cable: The USB connector socket pin 1 (VBUS ) may be heavily filtered and need only pass low frequency signals of less than ~100 KHz. The USB socket pin 4 (analog ground) must be able to return the current during data transmission, and must be filtered sparingly. • Differential twisted pair signals going out on cable, DP and DM: Depending upon the data transfer rate, these device terminals can have signals with fundamental frequencies of 240 MHz (high speed), 6 MHz (full speed), and 750 kHz (low speed). • External crystal circuit (device terminals XI and X0): 12 MHz, 19.2 MHz, 24 MHz, and 48 MHz fundamental. When using an external crystal as a reference clock, a 24 MHz and higher crystal is highly recommended. 8.5.2.2 USB PHY Layout Guide The following sections describe in detail the specific guidelines for USB PHY Layout. 8.5.2.2.1 General Routing and Placement Use the following routing and placement guidelines when laying out a new design for the USB physical layer (PHY). These guidelines help minimize signal quality and electromagnetic interference (EMI) problems on a four-or-more layer evaluation module (EVM). • Place the USB PHY and major components on the un-routed board first. For more details, see Section 8.5.2.2.2.3. • Route the high-speed clock and high-speed USB differential signals with minimum trace lengths. • Route the high-speed USB signals on the plane closest to the ground plane, whenever possible. • Route the high-speed USB signals using a minimum of vias and corners. This reduces signal reflections and impedance changes. • When it becomes necessary to turn 90°, use two 45° turns or an arc instead of making a single 90° turn. This reduces reflections on the signal traces by minimizing impedance discontinuities. • Do not route USB traces under or near crystals, oscillators, clock signal generators, switching regulators, mounting holes, magnetic devices or IC’s that use or duplicate clock signals. • Avoid stubs on the high-speed USB signals because they cause signal reflections. If a stub is unavoidable, then the stub should be less than 200 mils. • Route all high-speed USB signal traces over continuous planes (VCC or GND), with no interruptions. Avoid crossing over anti-etch, commonly found with plane splits. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 377 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.5.2.2.2 Specific Guidelines for USB PHY Layout The following sections describe in detail the specific guidelines for USB PHY Layout. 8.5.2.2.2.1 Analog, PLL, and Digital Power Supply Filtering To minimize EMI emissions, add decoupling capacitors with a ferrite bead at power supply terminals for the analog, phase-locked loop (PLL), and digital portions of the chip. Place this array as close to the chip as possible to minimize the inductance of the line and noise contributions to the system. An analog and digital supply example is shown in Figure 8-30. In case of multiple power supply pins with the same function, tie them up to a single low-impedance point in the board and then add the decoupling capacitors, in addition to the ferrite bead. This array of caps and ferrite bead improve EMI and jitter performance. Take both EMI and jitter into account before altering the configuration. Analog Power Supply Digital Power Supply Ferrite Bead 0.1 µF 0.01 µF 0.001 µF 10 µF 0.1 µF 0.01 µF 0.001 µF 10 µF SoC Board Ferrite Bead Figure 8-30. Suggested Array Capacitors and a Ferrite Bead to Minimize EMI 378 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Consider the recommendations listed below to achieve proper ESD/EMI performance: • Use a 0.01 μF cap on each cable power VBUS line to chassis GND close to the USB connector pin. • Use a 0.01 μF cap on each cable ground line to chassis GND next to the USB connector pin. • If voltage regulators are used, place a 0.01 μF cap on both input and output. This is to increase the immunity to ESD and reduce EMI. For other requirements, see the device-specific datasheet. 8.5.2.2.2.2 Analog, Digital, and PLL Partitioning If separate power planes are used, they must be tied together at one point through a low-impedance bridge or preferably through a ferrite bead. Care must be taken to capacitively decouple each power rail close to the device. The analog ground, digital ground, and PLL ground must be tied together to the lowimpedance circuit board ground plane. 8.5.2.2.2.3 Board Stackup Because of the high frequencies associated with the USB, a printed circuit board with at least four layers is recommended; two signal layers separated by a ground and power layer as shown in Figure 8-31. Signal 1 GND Plane Power Plane Signal 2 Figure 8-31. Four-Layer Board Stack-Up The majority of signal traces should run on a single layer, preferably SIGNAL1. Immediately next to this layer should be the GND plane, which is solid with no cuts. Avoid running signal traces across a split in the ground or power plane. When running across split planes is unavoidable, sufficient decoupling must be used. Minimizing the number of signal vias reduces EMI by reducing inductance at high frequencies. 8.5.2.2.2.4 Cable Connector Socket Short the cable connector sockets directly to a small chassis ground plane (GND strap) that exists immediately underneath the connector sockets. This shorts EMI (and ESD) directly to the chassis ground before it gets onto the USB cable. This etch plane should be as large as possible, but all the conductors coming off connector pins 1 through 6 must have the board signal GND plane run under. If needed, scoop out the chassis GND strap etch to allow for the signal ground to extend under the connector pins. Note that the etches coming from pins 1 and 4 (VBUS power and GND) should be wide and via-ed to their respective planes as soon as possible, respecting the filtering that may be in place between the connector pin and the plane. See Figure 8-32 for a schematic example. Place a ferrite in series with the cable shield pins near the USB connector socket to keep EMI from getting onto the cable shield. The ferrite bead between the cable shield and ground may be valued between 10 Ω and 50 Ω at 100 MHz; it should be resistive to approximately 1 GHz. To keep EMI from getting onto the cable bus power wire (a very large antenna) a ferrite may be placed in series with cable bus power, VBUS, near the USB connector pin 1. The ferrite bead between connector pin 1 and bus power may be valued between 47 Ω and approximately 1000 Ω at 100 MHz. It should continue being resistive out to approximately 1 GHz, as shown in Figure 8-32. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 379 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 5 SHIELD_GND 4 GND 3 DP 2 DM 1 VBUS Ferrite Bead +5 V U2 6 SHIELD_GND USB Socket U1 Ferrite Bead Figure 8-32. USB Connector 8.5.2.2.2.5 Clock Routings To address the system clock emissions between devices, place a ~10 to 130 Ω resistor in series with the clock signal. Use a trial and error method of looking at the shape of the clock waveform on a high-speed oscilloscope and of tuning the value of the resistance to minimize waveform distortion. The value on this resistor should be as small as possible to get the desired effect. Place the resistor close to the device generating the clock signal. If an external crystal is used, follow the guidelines detailed in the Selection and Specification of Crystals for Texas Instruments USB 2.0 Devices (SLLA122). When routing the clock traces from one device to another, try to use the 3W spacing rule. The distance from the center of the clock trace to the center of any adjacent signal trace should be at least three times the width of the clock trace. Many clocks, including slow frequency clocks, can have fast rise and fall times. Using the 3W rule cuts down on crosstalk between traces. In general, leave space between each of the traces running parallel between the devices. Avoid using right angles when routing traces to minimize the routing distance and impedance discontinuities. For further protection from crosstalk, run guard traces beside the clock signals (GND pin to GND pin), if possible. This lessens clock signal coupling, as shown in Figure 8-33. 3W 3W W Trace Figure 8-33. 3W Spacing Rule 380 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.5.2.2.2.6 Crystals/Oscillator Keep the crystal and its load capacitors close to the USB PHY pins, XI and XO (see Figure 8-34). Note that frequencies from power sources or large capacitors can cause modulations within the clock and should not be placed near the crystal. In these instances, errors such as dropped packets occur. A placeholder for a resistor, in parallel with the crystal, can be incorporated in the design to assist oscillator startup. Power is proportional to the current squared. The current is I = C*dv/dt, because dv/dt is a function of the PHY, current is proportional to the capacitive load. Cutting the load to 1/2 decreases the current by 1/2 and the power to 1/4 of the original value. For more details on crystal selection, see the Selection and Specification of Crystals for Texas Instruments USB 2.0 Devices (SLLA122). X1 0.1 µF Power Pins XTAL X0 0.001 µF USB PHY Figure 8-34. Power Supply and Clock Connection to the USB PHY 8.5.2.2.2.7 DP/DM Trace Place the USB PHY as close as possible to the USB 2.0 connector. The signal swing during high-speed operation on the DP/DM lines is relatively small (400 mV ± 10%), so any differential noise picked up on the twisted pair can affect the received signal. When the DP/DM traces do not have any shielding, the traces tend to behave like an antenna and picks up noise generated by the surrounding components in the environment. To minimize the effect of this behavior: • DP/DM traces should always be matched lengths and must be no more than 4 inches in length; otherwise, the eye opening may be degraded (see Figure 8-35). • Route DP/DM traces close together for noise rejection on differential signals, parallel to each other and within two mils in length of each other. The measurement for trace length must be started from device's balls. • A high-speed USB connection is made through a shielded, twisted pair cable with a differential characteristic impedance of 90 Ω ±15%. In layout, the impedance of DP and DM should each be 45 Ω ± 10%. • DP/DM traces should not have any extra components to maintain signal integrity. For example, traces cannot be routed to two USB connectors. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 381 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Minimize This Distance VBUS GND D+ USB PHY Cable Connector D+ Connector D- D- Figure 8-35. USB PHY Connector and Cable Connector 8.5.2.2.2.8 DP/DM Vias When a via must be used, increase the clearance size around it to minimize its capacitance. Each via introduces discontinuities in the signal’s transmission line and increases the chance of picking up interference from the other layers of the board. Be careful when designing test points on twisted pair lines; through-hole pins are not recommended. 8.5.2.2.2.9 Image Planes An image plane is a layer of copper (voltage plane or ground plane), physically adjacent to a signal routing plane. Use of image planes provides a low impedance, shortest possible return path for RF currents. For a USB board, the best image plane is the ground plane because it can be used for both analog and digital circuits. • Do not route traces so they cross from one plane to the other. This can cause a broken RF return path resulting in an EMI radiating loop as shown in Figure 8-36. This is important for higher frequency or repetitive signals. Therefore, on a multi-layer board, it is best to run all clock signals on the signal plane above a solid ground plane. • Avoid crossing the image power or ground plane boundaries with high-speed clock signal traces immediately above or below the separated planes. This also holds true for the twisted pair signals (DP, DM). Any unused area of the top and bottom signal layers of the PCB can be filled with copper that is connected to the ground plane through vias. 382 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Do Don't • Figure 8-36. Do Not Cross Plane Boundaries Do not overlap planes that do not reference each other. For example, do not overlap a digital power plane with an analog power plane as this produces a capacitance between the overlapping areas that could pass RF emissions from one plane to the other, as shown in Figure 8-37. Analog Power Plane Unwanted Capacitance Digital Power Plane • Figure 8-37. Do Not Overlap Planes Avoid image plane violations. Traces that route over a slot in an image plane results in a possible RF return loop, as shown in Figure 8-38. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 383 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com RF Return Current RF Return Current Slot in Image Plane Slot in Image Plane Bad Better Figure 8-38. Do Not Violate Image Planes 8.5.2.2.2.10 JTAG Interface For test and debug of the USB PHY only, an IEEE Standard 1149.1-1990, IEEE Standard Test Access Port and Boundary-Scan Architecture (JTAG) and Serial Test and Configuration Interface (STCI) may be available on the System-on-Chip (SoC). If available, keep the USB PHY JTAG interface less than six inches; keeping this distance short reduces noise coupling from other devices and signal loss due to resistance. 8.5.2.2.2.11 Power Regulators Switching power regulators are a source of noise and can cause noise coupling if placed close to sensitive areas on a circuit board. Therefore, the switching power regulator should be kept away from the DP/DM signals, the external clock crystal (or clock oscillator), and the USB PHY. 8.5.2.3 Electrostatic Discharge (ESD) International Electronic Commission (IEC) 61000-4-xx is a set of about 25 testing specifications from the IEC. IEC ESD Stressing is done both un-powered and with power applied, and with the device functioning. There must be no physical damage, and the device must keep working normally after the conclusion of the stressing. Typically, equipment has to pass IEC stressing at 8 kV contact and 15 kV air discharge, or higher. To market products/systems in the European community, all products/systems must be CE compliant and have the CE Mark. To obtain the CE Mark, all products/systems need to go through and pass IEC standard requirements; for ESD, it is 61000-4-2. 61000-4-2 requires that the products/systems pass contact discharge at 8 kV and air discharge at 15 kV. When performing an IEC ESD Stressing, only pins accessible to the outside world need to pass the test. The system into which the integrated circuit (IC) is placed makes a difference in how well the IC does. For example: • Cable between the zap point and the IC attenuate the high frequencies in the waveform. • Series inductance on the PCB board attenuates the high frequencies. • Unless the capacitor’s ground connection is inductive, capacitance to ground shunts away high frequencies. 8.5.2.3.1 IEC ESD Stressing Test The following sections describe in detail the IEC ESD Stressing Test modes and test types. 8.5.2.3.1.1 Test Mode The IEC ESD Stressing test is done through two modes: contact discharge mode and air discharge mode. 384 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 For the contact discharge test mode, the preferred way is direct contact applied to the conductive surfaces of the equipment under test (EUT). In the case of the USB system, the conductive surface is the outer casing of the USB connector. The electrode of the ESD generator is held in contact with the EUT or a coupling plane prior to discharge. The arc formation is created under controlled conditions, inside a relay, resulting in repeatable waveforms; however, this arc does not accurately recreate the characteristic unique to the arc of an actual ESD event. 8.5.2.3.1.2 Air Discharge Mode The air discharge usually applies to a non-conductive surface of the EUT. Instead of a direct contact with the EUT, the charged electrode of the ESD generator is brought close to the EUT, and a spark in the air to the EUT actuates the discharge. Compared to the contact discharge mode, the air discharge is more realistic to the actual ESD occurrence. However, due to the variations of the arc length, it may not be able to produce repeatable waveform. 8.5.2.3.1.3 Test Type The IEC ESD Stressing test has two test types: direct discharge and indirect discharge. Direct discharge is applies directly to the surface or the structure of the EUT. It includes both contact discharge and air discharge modes. Indirect discharge applies to a coupling plane in the vicinity of the EUT. The indirect discharge is used to simulate personal discharge to objects which are adjacent to the EUT. It includes contact discharge mode only. 8.5.2.3.2 TI Component Level IEC ESD Test TI Component Level IEC ESD Test tests only the IC terminals that are exposed in system level applications. It can be used to determine the robustness of on-chip protection and the latch-up immunity. The IC can only pass the TI Component Level IEC ESD test when there is no latch-up and IC is fully functional after the test. 8.5.2.3.3 Construction of a Custom USB Connector A standard USB connector, either type A or type B, provides good ESD protection. However, if a custom USB connector is desired, the following guidelines should be observed to ensure good ESD protection. • There should be an easily accessible shield plate next to the connector for air-discharge mode purpose. • Tie the outer shield of the connector to GND. When a cable is inserted into the connector, the shield of the cable should first make contact with the outer shield. • If the connector includes power and GND, the lead of power and GND need to be longer than the leads of signal. • The connector needs to have a key to ensure proper insertion of the cable. • See the standard USB connector for reference. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 385 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.5.2.3.4 ESD Protection System Design Consideration ESD protection system design consideration is covered in Section 8.5.2.2 of this document. The following are additional considerations for ESD protection in a system. • Metallic shielding for both ESD and EMI • Chassis GND isolation from the board GND • Air gap designed on board to absorb ESD energy • Clamping diodes to absorb ESD energy • Capacitors to divert ESD energy • The use of external ESD components on the DP/DM lines may affect signal quality and are not recommended. 8.5.2.4 • • • 8.5.3 References USB 2.0 Specification, Intel, 2000, http://www.usb.org/developers/docs/ High Speed USB Platform Design Guidelines, Intel, http://www.intel.com/technology/usb/download/usb2dg_R1_0.pdf Selection and Specification of Crystals for Texas Instruments USB 2.0 Devices (SLLA122) 2000, USB 3.0 Board Design and Layout Guidelines This section provides the timing specification for the USB3.0 (USB1 in the device) interface as a PCB design and manufacturing specification. The design rules constrain PCB trace length, PCB trace skew, signal integrity, cross-talk, and signal timing. TI has performed the simulation and system design work to ensure the USB3.0 interface requirements are met. The design rules stated within this document are targeted at DEVICE mode electrical compliance. HOST mode and/or systems that do not include the 3m USB cable and far-end 11-inch PCB trace required by DEVICE mode compliance testing may not need the complete list of optimizations shown in this document; however, applying these optimizations to HOST mode systems will lead to optimal DEVICE mode performance. 8.5.3.1 USB 3.0 interface introduction The USB 3.0 has two unidirectional differential pairs: TXp/TXn pair and RXp/RXn pair. AC coupling caps are needed on the board for TX traces. Figure 8-39 present high level schematic diagram for USB 3.0 interface. 386 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 GND Device AC Caps GND GND CMF Vias (if necessary) Vias (if necessary) usb_rxp0 usb_rxn0 CMF Vias (if necessary) Vias (if necessary) GND USB 3.0 usb_txp0 usb_txn0 USB 3.0 connector www.ti.com Place near connector, and keep routing short SPRS85x_PCB_USB30_1 Figure 8-39. USB 3.0 Interface High Level Schematic NOTE ESD components should be on a PCB layer next to a system GND plane layer so the inductance of the via to GND will be minimal. If vias are used, place the vias near the AC Caps or CMFs and under the SoC BGA, if necessary. AC Cap SoC TX USB 3.0 connector via Figure 8-40 present placement diagram for USB 3.0 interface. AC Cap via via CMF SoC RX via CMF SPRS85x_PCB_USB30_2 Figure 8-40. USB 3.0 placement diagram Table 8-12. USB1 Component Reference INTERFACE COMPONENT SUPPLIER PART NUMBER ESD TI TPD1E05U06 USB3 PHY CMF Murata DLW21SN900HQ2 C - 100nF (typical size: 0201) Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 387 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.5.3.2 www.ti.com USB 3.0 General routing rules Some general routing guidelines regarding USB 3.0: • Avoid crossing splits reference plane(s). • Shorter trace length is preferred. • Minimize the via usage and layer transition • Keep large spacing between TX and RX pairs. • Intra-lane delay mismatch between DP and DM less than 1ps. Same for RXp and RXn. • Distance between common mode filter (CMF) and ESD protection device should be as short as possible • Distance between ESD protection device and USB connector should be as short as possible. • Distance between AC capacitors (TX only) and CMF should be as short as possible. • USB 3.0 signals should always be routed over an adjacent ground plane. Table 8-13 and Table 8-14 present routing specification and recommendations for USB1 in the device. Table 8-13. USB1 Routing Specifications PARAMETER MIN TYP MAX UNIT 3500 Mils 3 6 Mils 0 Stubs 90 96.3 Ω 2 Vias Number of ground plane cuts allowed within USB3 routing region (except for specific ground carving as explained in this document) 0 Cuts Number of layers between USB3.0 routing region and reference ground plane 0 Layers Device balls to USB 3.0 connector trace length Skew within a differential pair Number of stubs allowed on TX/RX traces TX/RX pair differential impedance 83.7 Number of vias on each TX/RX trace (1) Differential pair to any other trace spacing (2) (3) (4) 2xDS 3xDS PCB trace width 6 Mils PCB BGA escape via pad size 18 Mils PCB BGA escape via hole size 10 Mils (1) Vias must be used in pairs and spaced equally along a signal path. (2) DS = differential spacing of the traces. (3) Exceptions may be necessary in the SoC package BGA area. (4) GND guard-bands on the same layer may be closer, but should not be allowed to affect the impedance of the differential pair routing. GND guard-bands to isolate USB3.0 differential pairs from all other signals are recommended. Table 8-14. USB1 Routing Recommendations 388 Item Description Reason ESD location Place ESD component on same layer as connector (no via or stub to ESD component) Eliminate reflection loss from via & stub to ESD ESD part number TPD1E05U06 Minimize capacitance (0.42pF) CMF part number DLW21SN900HQ2 Manufacturer’s recommended device Connector Use USB3.0 connector with supporting s-parameter model Enable full signal chain simulation Carve Ground Carve GND underneath AC Caps, ESD, CMF, and connector Minimize capacitance under ESD and CMF Round pads Minimize pad size and round the corners of the pads for the ESD and CMF components Minimize capacitance Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 8-14. USB1 Routing Recommendations (continued) Item Description Reason Vias Max 2 vias per signal trace. If vias are required, place vias close to the AC Caps and CMFs. Vias under the SoC grid array may be used if necessary to route signals away from BGA pattern. Vias significantly degrade signal integrity at 2.5GHz via Figure 8-41 presents an example layout, demonstrating the “carve GND” concept. USB 3.0 connector AC Cap CMF via via AC Cap via CMF Top Layer: Routing from SoC through AC Caps, CMF, and ESD to connector. Layer2, GND: Gaps carved in GND underneath AC Caps, CMF, ESD, and connector. Layer3, Signal: Implement as keep-out zone underneath carved GND areas. Layer4, GND Plane underneath AC Caps, CMF, ESD, and connector. SPRS85x_PCB_USB30_3 Figure 8-41. USB 3.0 Example “carve GND” layout 8.5.4 HDMI Board Design and Layout Guidelines This section provides the timing specification for the HDMI interface as a PCB design and manufacturing specification. The design rules constrain PCB trace length, PCB trace skew, signal integrity, cross-talk, and signal timing. TI has performed the simulation and system design work to ensure the HDMI interface requirements are met. The design rules stated within this document are targeted at resolutions less than or equal to 1080p60 with 8-bit color; deep color (10-bit) requires further signal integrity optimization. 8.5.4.1 HDMI Interface Schematic The HDMI bus is separated into three main sections (HDMI Ethernet and the optional Audio Return Channel are not specifically supported by this Device): 1. Transition Minimized Differential Signaling (TMDS) high speed digital video interface Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 389 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 2. Display Data Channel (I2C bus for configuration and status exchange between two devices) 3. Consumer Electronics Control (optional) for remote control of connected devices. The DDC and CEC are low speed interfaces, so nothing special is required for PCB layout of these signals. The TMDS channels are high speed differential pairs and therefore require the most care in layout. Specifications for TMDS layout are below. Figure 8-42 shows the HDMI interface schematic. CMF HDMI connector hdmi_tx*hdmi_tx*+ GND HDMI GND Device Place near connector, and keep routing short SPRS85x_PCB_HDMI_1 Figure 8-42. HDMI Interface High Level Schematic Figure 8-43 presents placement diagram for HDMI interface. HDMI connector CMF CMF CMF CMF SPRS85x_PCB_HDMI_2 Figure 8-43. HDMI Placement Diagram Table 8-15. HDMI Component Reference INTERFACE HDMI 390 DEVICE SUPPLIER ESD TI TPD1E05U06 CMF Murata DLW21SN900HQ2 Applications, Implementation, and Layout PART NUMBER Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 8.5.4.2 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 TMDS General Routing Guidelines The TMDS signals are high speed differential pairs. Care must be taken in the PCB layout of these signals to ensure good signal integrity. The TMDS differential signal traces must be routed to achieve 100 Ohms (+/- 10%) differential impedance and 60 ohms (+/-10%) single ended impedance. Single ended impedance control is required because differential signals can’t be closely coupled on PCBs and therefore single ended impedance becomes important. These impedances are impacted by trace width, trace spacing, distance to reference planes, and dielectric material. Verify with a PCB design tool that the trace geometry for both data signal pairs results in as close to 60 ohms impedance traces as possible. For best accuracy, work with your PCB fabricator to ensure this impedance is met. In general, closely coupled differential signal traces are not an advantage on PCBs. When differential signals are closely coupled, tight spacing and width control is necessary. Very small width and spacing variations affect impedance dramatically, so tight impedance control can be more problematic to maintain in production. Loosely coupled PCB differential signals make impedance control much easier. Wider traces and spacing make obstacle avoidance easier, and trace width variations don’t affect impedance as much, therefore it’s easier to maintain accurate impedance over the length of the signal. The wider traces also show reduced skin effect and therefore often result in better signal integrity. Some general routing guidelines regarding TMDS: • Avoid crossing splits reference plane(s). • Shorter trace length is preferred. • Distance between common mode filter (CMF) and ESD protection device should be as short as possible • Distance between ESD protection device and HDMI connector should be as short as possible. Table 8-16 shows the routing specifications for the TMDS signals. Table 8-16. TMDS Routing Specifications PARAMETER MIN TYP Device balls to HDMI header trace length Skew within a differential pair 3 Number of stubs allowed on TMDS traces MAX UNIT 4000 Mils 5 Mils 0 stubs TMDS pair differential impedance 90 100 110 Ω TMDS single-ended impedance 54 60 66 Ω 0 Vias 2×DS 3xDS Number of vias on each TMDS trace TMDS differential pair to any other trace spacing (1) (2) (3) Number of ground plane cuts allowed within HDMI routing region (except for specific ground carving as explained in this document) Number of layers between HDMI routing region and reference ground plane PCB trace width Mils 0 Cuts 0 Layers 4.4 Mils (1) DS = differential spacing of the traces. (2) Exceptions may be necessary in the SoC package BGA area. (3) GND guard-bands may be closer, but should not be allowed to affect the impedance of the differential pair routing. GND guard-bands to isolate HDMI differential pairs from all other signals is recommended. Table 8-17. TDMS Routing Recommendations Item Description Reason ESD part number TPD1E05U06 Minimize capacitance (0.42pF) Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 391 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-17. TDMS Routing Recommendations (continued) Item Description Reason Carve Ground Carve GND underneath ESD and CMF Minimize capacitance under ESD and CMF Round pads Reduce pad size and round the corners of the pads for the ESD and CMF components Minimize capacitance Routing layer Route all signals only on the same layer as SoC Minimize reflection loss Figure 8-44presents an example layout, demonstrating the “carve GND” concept. HDMI connector CMF ia v AC Cap CMF CMF a iv AC Cap a iv CMF CMF a iv CMF Top Layer: Routing from SoC through CMF, and ESD to connector. Layer2, GND: Gaps carved in GND underneath, CMF, ESD, and connector. SPRS85x_PCB_HDMI_3 Figure 8-44. HDMI Example “carve GND” layout 8.5.4.3 TPD5S115 The TPD5S115 is an integrated HDMI companion chip solution. The device provides a regulated 5 V output (5VOUT) for sourcing the HDMI power line. The TPD5S115 exceeds the IEC61000-4-2 (Level 4) ESD protection level. 8.5.4.4 HDMI ESD Protection Device (Required) Interfaces that connect to a cable such as HDMI generally require more ESD protection than can be built into the processor’s outputs. Therefore this HDMI interface requires the use of an ESD protection chip to provide adequate ESD. When selecting an ESD protection chip, choose the lowest capacitance ESD protection available to minimize signal degradation. In no case should be ESD protection circuit capacitance be more than 5pF. TI manufactures these devices that provide ESD protection for HDMI signals such as the TPDxE05U06. For more information see the www.ti.com website. 8.5.4.5 PCB Stackup Specifications Table 8-18 shows the stackup and feature sizes required for HDMI. Table 8-18. HDMI PCB Stackup Specifications 392 PARAMETER MIN TYP MAX UNIT PCB Routing/Plane Layers 4 6 - Layers Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 8-18. HDMI PCB Stackup Specifications (continued) PARAMETER MIN TYP MAX UNIT Signal Routing Layers 2 3 - Layers Number of ground plane cuts allowed within HDMI routing region - - 0 Cuts Number of layers between HDMI routing region and reference ground plane - - 0 Layers PCB Trace width 8.5.4.6 4 Mils Grounding Each TMDS channel has its own shield pin and they should be grounded to provide a return current path for the TMDS signal. 8.5.5 SATA Board Design and Layout Guidelines The device provides one SATA port. This section provides the timing specification for the SATA interface as a PCB design and manufacturing specification. The design rules constrain PCB trace length, PCB trace skew, signal integrity, cross-talk, and signal timing. TI has performed the simulation and system design work to ensure the SATA interface requirements are met. 8.5.5.1 SATA Interface Schematic Figure 8-45 shows the data portion of the SATA interface schematic. DEVICE SATA Interface sata1_rxn0 C sata1_rxp0 C sata1_txn0l C sata1_txp0 C SATA Connector PCB_SATA_1 Figure 8-45. SATA Interface High Level Schematic NOTE AC coupling capacitors (C) are required on the receive and transmit data pairs. Table 8-19 shows the requirements for these capacitors. Table 8-19. SATA AC Coupling Capacitors Requirements PARAMETER MIN TYP MAX UNIT SATA AC coupling capacitor value 0.3 10 12 nF 0402 0603 EIA(1)(2) SATA AC coupling capacitor package size (1) EIA LxW units, i.e., a 0402 is a 40x20 mils surface mount capacitor. (2) The physical size of the capacitor should be as small as practical. Use the same size on both lines in each pair placed side by side. 8.5.5.2 Compatible SATA Components and Modes Table 8-20 shows the compatible SATA components and supported modes. Note that the only supported configuration is an internal cable from the processor host to the SATA device. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 393 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-20. Compatible SATA Components and Modes 8.5.5.3 PARAMETER MIN MAX UNIT Transfer Rates 1.5 3 Gbps Internal Cable - - - SUPPORTED YES PCB Stackup Specifications Table 8-21 shows the stackup and feature sizes required for these types of SATA connections. Table 8-21. SATA PCB Stackup Specifications PARAMETER MIN TYP MAX UNIT Number of ground plane cuts allowed within SATA routing region - - 0 Cuts Number of layers between SATA routing area and reference plane - - 0 Layers 8.5.5.4 PCB Routing clearance 4 Mils PCB Trace width 4 Mils Routing Specifications The SATA data signal traces must be routed to achieve 100 Ohms (+/-10%) differential impedance and 60 ohms (+/-10%) single ended impedance. The signal ended impedance is required because differential signals can’t be closely coupled on PCBs and therefore single ended impedance becomes important. 60 ohms is chosen for the single ended impedance to minimize problems caused by too low an impedance. These impedances are impacted by trace width, trace spacing, distance to reference planes, and dielectric material. Verify with a PCB design tool that the trace geometry for both data signal pairs results in as close to 100 ohms differential and 60 ohms single ended impedance traces as possible. For best accuracy, work with your PCB fabricator to ensure this impedance is met. Table 8-22 shows the routing specifications for the SATA data signals. Table 8-22. SATA Routing Specifications PARAMETER MIN TYP SATA signal trace length (device balls to SATA connector) Differential pair trace skew matching Number of stubs allowed on SATA traces MAX UNIT 3050(1) Mils 5 Mils 0 stubs TX/RX pair differential impedance 90 100 110 Ω TX/RX single-ended impedance 54 60 66 Ω 0 Vias (2) Number of vias on each SATA trace SATA differential pair to any other trace spacing 2×DS(3) (1) Beyond this, signal integrity may suffer. (2) Inline pads may be used for probing. (3) DS = differential spacing of the SATA traces. Table 8-23. SATA Routing Recommendations Item ESD part number 394 Applications, Implementation, and Layout Description Reason None ESD suppression generally not used on SATA Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 8.5.6 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 PCIe Board Design and Layout Guidelines The PCIe interface on the device provides support for a 5.0 Gbps lane with polarity inversion. 8.5.6.1 PCIe Connections and Interface Compliance The PCIe interface on the device is compliant with the PCIe revision 2.0 specification. Please refer to the PCIe specifications for all connections that are described in it. Those recommendations are more descriptive and exhaustive than what is possible here. The use of PCIe compatible bridges and switches is allowed for interfacing with more than one other processor or PCIe device. 8.5.6.1.1 Coupling Capacitors AC coupling capacitors are required on the transmit data pair. Table 8-24 shows the requirements for these capacitors. Table 8-24. PCIe AC Coupling Capacitors Requirements PARAMETER MIN PCIe AC coupling capacitor value 90 PCIe AC coupling capacitor package size TYP MAX UNIT 100 110 nF 0402 0603 EIA(1)(2) (1) EIA LxW units, i.e., a 0402 is a 40x20 mils surface mount capacitor. (2) The physical size of the capacitor should be as small as practical. Use the same size on both lines in each pair placed side by side. 8.5.6.1.2 Polarity Inversion The PCIe specification requires polarity inversion support. This means for layout purposes, polarity is unimportant because each signal can change its polarity on die inside the chip. This means polarity within a lane is unimportant for layout. 8.5.6.2 Non-standard PCIe connections The following sections contain suggestions for any PCIe connection that is NOT described in the official PCIe specification, such as an on-board Device to Device or Device to other PCIe compliant processor connection. 8.5.6.2.1 PCB Stackup Specifications Table 8-25 shows the stackup and feature sizes required for these types of PCIe connections. Table 8-25. PCIe PCB Stackup Specifications PARAMETER MIN TYP MAX UNIT Number of ground plane cuts allowed within PCIe routing region - - 0 Cuts Number of layers between PCIe routing area and reference plane (1) - - 0 Layers PCB Routing clearance 4 Mils PCB Trace width 4 Mils Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 395 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) A reference plane may be a ground plane or the power plane referencing the PCIe signals. 8.5.6.2.2 Routing Specifications 8.5.6.2.2.1 Impedance The PCIe data signal traces must be routed to achieve 100-Ω (±10%) differential impedance and 60-Ω (±10%) single-ended impedance. The single-ended impedance is required because differential signals are extremely difficult to closely couple on PCBs and, therefore, single-ended impedance becomes important. These requirements are the same as those recommended in the PCIe Motherboard Checklist 1.0 document, available from PCI-SIG (www.pcisig.com). These impedances are impacted by trace width, trace spacing, distance between signals and referencing planes, and dielectric material. Verify with a PCB design tool that the trace geometry for both data signal pairs result in as close to 100-Ω differential impedance and 60-Ω single-ended impedance as possible. For best accuracy, work with your PCB fabricator to ensure this impedance is met. See Table 8-26 below. 8.5.6.2.2.2 Differential Coupling In general, closely coupled differential signal traces are not an advantage on PCBs. When differential signals are closely coupled, tight spacing and width control is necessary. Very small width and spacing variations affect impedance dramatically, so tight impedance control can be more problematic to maintain in production. For PCBs with very tight space limitations (which are usually small) this can work, but for most PCBs, the loosely coupled option is probably best. Loosely coupled PCB differential signals make impedance control much easier. Wider traces and spacing make obstacle avoidance easier (because each trace is not so fixed in position relative to the other), and trace width variations don’t affect impedance as much, therefore it’s easier to maintain an accurate impedance over the length of the signal. For longer routes, the wider traces also show reduced skin effect and therefore often result in better signal integrity with a larger eye diagram opening. Table 8-26 shows the routing specifications for the PCIe data signals. Table 8-26. PCI-E Routing Specifications PARAMETER MIN TYP PCIe signal trace length Differential pair trace matching MAX UNIT 4700(1) Mills 5 Number of stubs allowed on PCIe traces(3) TX/RX pair differential impedance 90 100 TX/RX single-ended impedance 54 60 (2) Mils 0 stubs 110 Ω 66 Ω Pad size of vias on PCIe trace 25(4) Mils Hole size of vias on PCIe trace 14 Mils Number of vias on each PCIe trace 0 Vias PCIe differential pair to any other trace spacing 2×DS(5) (1) Beyond this, signal integrity may suffer. (2) For example, RXP0 within 5 Mils of RXN0. (3) Inline pads may be used for probing. (4) 35-Mil antipad maximum recommended. (5) DS = differential spacing of the PCIe traces. Table 8-27. PCI-E Routing Recommendations Item ESD part number 396 Applications, Implementation, and Layout Description Reason None ESD suppression generally not used on PCIe Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.5.6.2.2.3 Pair Length Matching Each signal in the differential pair should be matched to within 5 mils of its matching differential signal. Length matching should be done as close to the mismatch as possible. 8.5.6.3 LJCB_REFN/P Connections A Common Refclk Rx Architecture is required to be used for the device PCIe interface. Specifically, two modes of Common Refclk Rx Architecture are supported: • External REFCLK Mode: An common external 100MHz clock source is distributed to both the Device and the link partner • Output REFCLK Mode: A 100MHz HCSL clock source is output by the device and used by the link partner In External REFCLK Mode, a high-quality, low-jitter, differential HCSL 100MHz clock source compliant to the PCIe REFCLK AC Specifications should be provided on the Device’s ljcb_clkn / ljcb_clkp inputs. Alternatively, an LVDS clock source can be used with the following additional requirements: • External AC coupling capacitors described in Table 8-28 should be populated at the ljcb_clkn / ljcb_clkp inputs. • All termination requirements (ex. parallel 100ohm termination) from the clock source manufacturer should be followed. In Output REFCLK Mode, the 100MHz clock from the Device’s DPLL_PCIE_REF should be output on the Device’s ljcb_clkn / ljcb_clkp pins and used as the HCSL REFCLK by the link partner. External nearside termination to ground described in Table 8-29 is required on both of the ljcb_clkn / ljcb_clkp outputs in this mode. Table 8-28. LJCB_REFN/P Requirements in External LVDS REFCLK Mode PARAMETER MIN TYP ljcb_clkn / ljcb_clkp AC coupling capacitor value 100 ljcb_clkn / ljcb_clkp AC coupling capacitor package size 0402 MAX UNIT nF 0603 EIA(1)(2) (1) EIA LxW units, i.e., a 0402 is a 40x20 mils surface mount capacitor. (2) The physical size of the capacitor should be as small as practical. Use the same size on both lines in each pair placed side by side. Table 8-29. LJCB_REFN/P Requirements in Output REFCLK Mode PARAMETER MIN TYP MAX UNIT ljcb_clkn / ljcb_clkp near-side termination to ground value 47.5 50 52.5 Ohms 8.6 8.6.1 Clock Routing Guidelines 32-kHz Oscillator Routing When designing the printed-circuit board: • Keep the crystal as close as possible to the crystal pins X1 and X2. • Keep the trace lengths short and small to reduce capacitor loading and prevent unwanted noise pickup. • Place a guard ring around the crystal and tie the ring to ground to help isolate the crystal from unwanted noise pickup. • Keep all signals out from beneath the crystal and the X1 and X2 pins to prevent noise coupling. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 397 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 • www.ti.com Finally, an additional local ground plane on an adjacent PCB layer can be added under the crystal to shield it from unwanted pickup from traces on other layers of the board. This plane must be isolated from the regular PCB ground plane and tied to the GND pin of the RTC. The plane must not be any larger than the perimeter of the guard ring. Make sure that this ground plane does not contribute to significant capacitance (a few pF) between the signal line and ground on the connections that run from X1 and X2 to the crystal. Cap Via to GND X 1 Crystal Cap IC X 2 Local ground plane SWPS040-196 Figure 8-46. Slow Clock PCB Requirements 8.6.2 Oscillator Ground Connection Although the impedance of a ground plane is low it is, of course, not zero. Therefore, any noise current in the ground plane causes a voltage drop in the ground. Figure 8-47 shows the grounding scheme for slow (low frequency) clock generated from the internal oscillator. Device rtc_osc_xo rtc_osc_xi_clkin32 Rd (Optional) Crystal Cf1 Cf2 SPRS85v_PCB_CLK_OSC_2 Figure 8-47. Grounding Scheme for Low-Frequency Clock Figure 8-48 shows the grounding scheme for high-frequency clock. 398 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Device xi_oscj xo_oscj Rd (Optional) Crystal Cf1 vssa_oscj Cf2 SPRS85v_PCB_CLK_OSC_3 (1) j in *_osc = 0 or 1 Figure 8-48. Grounding Scheme for High-Frequency Clock 8.7 DDR2/DDR3 Board Design and Layout Guidelines 8.7.1 DDR2/DDR3 General Board Layout Guidelines To • • • • • • • • • • • 8.7.2 help ensure good signaling performance, consider the following board design guidelines: Avoid crossing splits in the power plane. Minimize Vref noise. Use the widest trace that is practical between decoupling capacitors and memory module. Maintain a single reference. Minimize ISI by keeping impedances matched. Minimize crosstalk by isolating sensitive bits, such as strobes, and avoiding return path discontinuities. Use proper low-pass filtering on the Vref pins. Keep the stub length as short as possible. Add additional spacing for on-clock and strobe nets to eliminate crosstalk. Maintain a common ground reference for all bypass and decoupling capacitors. Take into account the differences in propagation delays between microstrip and stripline nets when evaluating timing constraints. DDR2 Board Design and Layout Guidelines 8.7.2.1 Board Designs TI only supports board designs that follow the guidelines outlined in this document. The switching characteristics and the timing diagram for the DDR2 memory controller are shown in Table 8-30 and Figure 8-49. Table 8-30. Switching Characteristics Over Recommended Operating Conditions for DDR2 Memory Controller NO. DDR21 PARAMETE R tc(DDR_CLK) DESCRIPTION MIN MAX UNIT Cycle time, DDR_CLK 2.5 8 ns 1 ddrx_ck PCB_DDR2_0 Figure 8-49. DDR2 Memory Controller Clock Timing Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 399 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.7.2.2 www.ti.com DDR2 Interface This section provides the timing specification for the DDR2 interface as a PCB design and manufacturing specification. The design rules constrain PCB trace length, PCB trace skew, signal integrity, cross-talk, and signal timing. These rules, when followed, result in a reliable DDR2 memory system without the need for a complex timing closure process. For more information regarding the guidelines for using this DDR2 specification, see the Understanding TI’s PCB Routing Rule-Based DDR Timing Specification Application Report (Literature Number: SPRAAV0). 8.7.2.2.1 DDR2 Interface Schematic Figure 8-50 shows the DDR2 interface schematic for a x32 DDR2 memory system. In Figure 8-51 the x16 DDR2 system schematic is identical except that the high-word DDR2 device is deleted. When not using all or part of a DDR2 interface, the proper method of handling the unused pins is to tie off the ddrx_dqsi pins to ground via a 1k-Ω resistor and to tie off the ddrx_dqsni pins to the corresponding vdds_ddrx supply via a 1k-Ω resistor. This needs to be done for each byte not used. The vdds_ddrx and ddrx_vref0 power supply pins need to be connected to their respective power supplies even if DDRx is not being used. All other DDR interface pins can be left unconnected. Note that the supported modes for use of the DDR EMIF are 32-bits wide, 16-bits wide, or not used. 400 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DDR2 ddrx_d0 DQ0 ddrx_d7 ddrx_dqm0 ddrx_dqs0 DQ7 LDM LDQS ddrx_dqsn0 ddrx_d8 LDQS DQ8 ddrx_d15 ddrx_dqm1 ddrx_dqs1 DQ15 UDM UDQS ddrx_dqsn1 ddrx_odt0 UDQS ODT T0 DDR2 ddrx_odt1 NC ODT ddrx_d16 DQ0 ddrx_d23 ddrx_dqm2 ddrx_dqs2 ddrx_dqsn2 ddrx_d24 DQ7 LDM LDQS LDQS DQ8 ddrx_d31 ddrx_dqm3 ddrx_dqs3 ddrx_dqsn3 DQ15 UDM UDQS UDQS ddrx_ba0 T0 BA0 BA0 ddrx_ba2 ddrx_a0 T0 T0 BA2 A0 BA2 A0 T0 T0 NC T0 T0 A14 CS A14 CS CAS RAS CAS T0 T0 T0 T0 WE CKE CK CK VREF WE CKE CK CK VREF ddrx_a14 ddrx_csn0 ddrx_csn1 ddrx_casn ddrx_rasn ddrx_wen ddrx_cke ddrx_ck ddrx_nck ddrx_vref0 (B) 0.1 µF ddrx_rst T0 A. B. 0.1 µF (B) vdds_ddrx (A) RAS VREF 0.1 µF VREF 1 K Ω 1% VREF (B) 0.1 µF 0.1 µF 1 K Ω 1% NC Termination is required. See terminator comments. PCB_DDR2_1 vdds_ddrx is the power supply for the DDR2 memories and the Device DDR2 interface. One of these capacitors can be eliminated if the divider and its capacitors are placed near a VREF pin. Figure 8-50. 32-Bit DDR2 High-Level Schematic Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 401 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com DDR2 ddrx_d0 DQ0 ddrx_d7 ddrx_dqm0 ddrx_dqs0 DQ7 LDM LDQS ddrx_dqsn0 ddrx_d8 LDQS DQ8 ddrx_d15 ddrx_dqm1 ddrx_dqs1 ddrx_dqsn1 DQ15 UDM UDQS UDQS ddrx_odt0 ddrx_odt1 ddrx_d16 T0 NC NC ddrx_d23 ddrx_dqm2 NC NC 1 KΩ ddrx_d24 NC 1 KΩ ddrx_d31 ddrx_dqm3 ddrx_dqsn3 ddrx_dqs3 NC NC ODT vdds_ddrx (A) ddrx_dqsn2 ddrx_dqs2 vdds_ddrx (A) 1 KΩ 1 KΩ ddrx_ba0 T0 BA0 ddrx_ba2 ddrx_a0 T0 T0 BA2 A0 T0 T0 NC T0 T0 T0 T0 T0 T0 A14 CS ddrx_a14 ddrx_csn0 ddrx_csn1 ddrx_casn ddrx_rasn ddrx_wen ddrx_cke ddrx_ck ddrx_nck CAS ddrx_vref0 VREF 0.1 µF ddrx_rst T0 A. B. vdds_ddrx RAS WE CKE CK CK (B) 0.1 µF 0.1 µF VREF (A) 1 K Ω 1% VREF (B) 0.1 µF 1 K Ω 1% NC Termination is required. See terminator comments. PCB_DDR2_2 vdds_ddrx is the power supply for the DDR2 memories and the Device DDR2 interface. One of these capacitors can be eliminated if the divider and its capacitors are placed near a VREF pin. Figure 8-51. 16-Bit DDR2 High-Level Schematic 402 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.7.2.2.2 Compatible JEDEC DDR2 Devices Table 8-31 shows the parameters of the JEDEC DDR2 devices that are compatible with this interface. Generally, the DDR2 interface is compatible with x16 DDR2-800 speed grade DDR2 devices. Table 8-31. Compatible JEDEC DDR2 Devices (Per Interface) NO. PARAMETER CJ21 JEDEC DDR2 device speed grade(1) CJ22 JEDEC DDR2 device bit width CJ23 JEDEC DDR2 device count(2) CJ24 JEDEC DDR2 device ball count(3) MIN MAX UNIT DDR2-800 x16 x16 1 2 Devices Bits 84 92 Balls (1) Higher DDR2 speed grades are supported due to inherent JEDEC DDR2 backwards compatibility. (2) One DDR2 device is used for a 16-bit DDR2 memory system. Two DDR2 devices are used for a 32-bit DDR2 memory system. (3) The 92-ball devices are retained for legacy support. New designs will migrate to 84-ball DDR2 devices. Electrically, the 92- and 84-ball DDR2 devices are the same. 8.7.2.2.3 PCB Stackup The minimum stackup required for routing the Device is a six-layer stackup as shown in Table 8-32. Additional layers may be added to the PCB stackup to accommodate other circuitry or to reduce the size of the PCB footprint. Table 8-32. Minimum PCB Stackup LAYER TYPE DESCRIPTION 1 Signal Top routing mostly horizontal 2 Plane Ground 3 Plane Power 4 Signal Internal routing 5 Plane Ground 6 Signal Bottom routing mostly vertical Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 403 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Complete stackup specifications are provided in Table 8-33. Table 8-33. PCB Stackup Specifications NO. PARAMETER MIN PS21 PCB routing/plane layers 6 PS22 Signal routing layers 3 PS23 Full ground reference layers under DDR2 routing region(1) 1 PS24 Full vdds_ddrx power reference layers under the DDR2 routing region(1) 1 PS25 Number of reference plane cuts allowed within DDR routing region(2) TYP PS26 Number of layers between DDR2 routing layer and reference plane PS27 PCB routing feature size 4 PS28 PCB trace width, w 4 PS29 Single-ended impedance, Zo PS210 Impedance control UNIT 0 (3) (5) MAX 0 50 Z-5 Z Mils Mils 75 Ω Z+5 Ω (1) Ground reference layers are preferred over power reference layers. Be sure to include bypass caps to accommodate reference layer return current as the trace routes switch routing layers. A full ground reference layer should be placed adjacent to each DDR routing layer in PCB stack up. (2) No traces should cross reference plane cuts within the DDR routing region. High-speed signal traces crossing reference plane cuts create large return current paths which can lead to excessive crosstalk and EMI radiation. (3) Reference planes are to be directly adjacent to the signal plane to minimize the size of the return current loop. (4) An 18-mil pad assumes Via Channel is the most economical BGA escape. A 20-mil pad may be used if additional layers are available for power routing. An 18-mil pad is required for minimum layer count escape. (5) Z is the nominal singled-ended impedance selected for the PCB specified by PS29. 404 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.7.2.2.4 Placement Figure 8-52 shows the required placement for the Device as well as the DDR2 devices. The dimensions for this figure are defined in Table 8-34. The placement does not restrict the side of the PCB on which the devices are mounted. The ultimate purpose of the placement is to limit the maximum trace lengths and allow for proper routing space. For a 16-bit DDR memory system, the high-word DDR2 device is omitted from the placement. y2 DDR2 Controller y1 y1 x1 y2 PCB_DDR2_3 Figure 8-52. Device and DDR2 Device Placement Table 8-34. Placement Specifications DDR2 NO. PARAMETER MIN MAX UNIT KOD21 X1 2000 Mils KOD22 Y1 500 Mils KOD23 Y2 1300 Mils 4 W (1) KOD24 DDR2 keepout region KOD25 Clearance from non-DDR2 signal to DDR2 keepout region (2) (3) (1) DDR2 keepout region to encompass entire DDR2 routing area. (2) Non-DDR2 signals allowed within DDR2 keepout region provided they are separated from DDR2 routing layers by a ground plane. (3) If a device has more than one DDR controller, the signals from the other controller(s) are considered non-DDR2 and should be separated by this specification. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 405 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.7.2.2.5 DDR2 Keepout Region The region of the PCB used for the DDR2 circuitry must be isolated from other signals. The DDR2 keepout region is defined for this purpose and is shown in Figure 8-53. The size of this region varies with the placement and DDR routing. Additional clearances required for the keepout region are shown in Table 8-34. DDR2 Controller DDR2 Device DDR2 Device DDR2 Device DDR2 Device The region shown in Table 8-34 should encompass all the DDR2 circuitry and varies depending on placement. Non-DDR2 signals should not be routed on the DDR signal layers within the DDR2 keepout region. Non-DDR2 signals may be routed in the region, provided they are routed on layers separated from DDR2 signal layers by a ground layer. No breaks should be allowed in the reference ground layers in this region. In addition, the vdds_ddrx power plane should cover the entire keepout region. Routes for the two DDR interfaces must be separated by at least 4x; the more separation, the better. Device PCB_DDR2_4 Figure 8-53. DDR2 Keepout Region 8.7.2.2.6 Bulk Bypass Capacitors Bulk bypass capacitors are required for moderate speed bypassing of the DDR2 and other circuitry. Table 8-35 contains the minimum numbers and capacitance required for the bulk bypass capacitors. Note that this table only covers the bypass needs of the DDR2 interfaces and DDR2 device. Additional bulk bypass capacitance may be needed for other circuitry. Table 8-35. Bulk Bypass Capacitors NO. PARAMETER BC21 vdds_ddrx bulk bypass capacitor (≥1µF) count BC22 vdds_ddrx bulk bypass total capacitance MIN (1) TYP MAX UNIT 1 Devices 22 μF (1) These devices should be placed near the devices they are bypassing, but preference should be given to the placement of the highspeed (HS) bypass capacitors and DDR2 signal routing. 8.7.2.2.7 High-Speed Bypass Capacitors TI recommends that a PDN/power integrity analysis is performed to ensure that capacitor selection and placement is optimal for a given implementation. This section provides guidelines that can serve as a good starting point. 406 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 High-speed (HS) bypass capacitors are critical for proper DDR2 interface operation. It is particularly important to minimize the parasitic series inductance of the HS bypass capacitors, processor/DDR power, and processor/DDR ground connections. Table 8-36 contains the specification for the HS bypass capacitors as well as for the power connections on the PCB. Generally speaking, it is good to: 1. Fit as many HS bypass capacitors as possible. 2. HS bypass capacitor value is < 1µF 3. Minimize the distance from the bypass cap to the pins/balls being bypassed. 4. Use the smallest physical sized capacitors possible with the highest capacitance readily available. 5. Connect the bypass capacitor pads to their vias using the widest traces possible and using the largest hole size via possible. 6. Minimize via sharing. Note the limites on via sharing shown in Table 8-36. Table 8-36. High-Speed Bypass Capacitors NO. PARAMETER MIN HS21 HS bypass capacitor package size(1) HS22 Distance, HS bypass capacitor to processor being bypassed(2)(3)(4) processor HS bypass capacitor count per vdds_ddrx rail HS24 processor vdds_ddrx HS bypass capacitor total capacitance MAX UNIT 0402 10 Mils 400(12) (12) HS23 TYP 0201 See Table 8-3 and (12) (5) Number of connection vias for each device power/ground ball HS26 Trace length from device power/ground ball to connection via(2) HS27 Distance, HS bypass capacitor to DDR device being bypassed(6) HS28 Number of connection vias for each HS capacitor(8)(9) 4 HS29 DDR2 device HS bypass capacitor count(7) 12 HS210 DDR2 device HS bypass capacitor total capacitance HS211 Trace length from bypass capacitor connect to connection via(2)(9) HS212 Number of connection vias for each DDR2 device power/ground ball(10) HS213 Trace length from DDR2 device power/ground ball to connection via(2)(8) Mils Devices See Table 8-3 and (11) HS25 (7) (11) μF 1 Vias 35 70 Mils 150 Mils (14) Vias (13) Devices μF 0.85 35 100 1 Mils Vias 35 60 Mils (1) LxW, 10-mil units, that is, a 0402 is a 40x20-mil surface-mount capacitor. (2) Closer/shorter is better. (3) Measured from the nearest processor power/ground ball to the center of the capacitor package. (4) Three of these capacitors should be located underneath the processor, between the cluster of vdds_ddrx balls and ground balls, between the DDR interfaces on the package. (5) See the Via Channel™ escape for the processor package. (6) Measured from the DDR2 device power/ground ball to the center of the capacitor package. (7) Per DDR2 device. (8) An additional HS bypass capacitor can share the connection vias only if it is mounted on the opposite side of the board. No sharing of vias is permitted on the same side of the board. (9) An HS bypass capacitor may share a via with a DDR device mounted on the same side of the PCB. A wide trace should be used for the connection and the length from the capacitor pad to the DDR device pad should be less than 150 mils. (10) Up to a total of two pairs of DDR power/ground balls may share a via. (11) The capacitor recommendations in this data manual reflect only the needs of this processor. Please see the memory vendor’s guidelines for determining the appropriate decoupling capacitor arrangement for the memory device itself. (12) For more information, see Section 8.3, Core Power Domains (13) For more information refer to DDR2 specification. (14) Preferred configuration is 4 vias: 2 to power and 2 to ground. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 407 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.7.2.2.8 Net Classes Table 8-37 lists the clock net classes for the DDR2 interface. Table 8-38 lists the signal net classes, and associated clock net classes, for the signals in the DDR2 interface. These net classes are used for the termination and routing rules that follow. Table 8-37. Clock Net Class Definitions CLOCK NET CLASS CK PIN NAMES ddrx_ck / ddrx_nck DQS0 ddrx_dqs0 / ddrx_dqsn0 DQS1 ddrx_dqs1 / ddrx_dqsn1 (1) ddrx_dqs2 / ddrx_dqsn2 DQS3(1) ddrx_dqs3 / ddrx_dqsn3 DQS2 (1) Only used on 32-bit wide DDR2 memory systems. Table 8-38. Signal Net Class Definitions SIGNAL NET CLASS ASSOCIATED CLOCK NET CLASS ADDR_CTRL CK DQ0 DQS0 ddrx_d[7:0], ddrx_dqm0 DQ1 DQS1 ddrx_d[15:8], ddrx_dqm1 DQ2(1) DQS2 ddrx_d[23:16], ddrx_dqm2 DQ3(1) DQS3 ddrx_d[31:24], ddrx_dqm3 PIN NAMES ddrx_ba[2:0], ddrx_a[14:0], ddrx_csnj, ddrx_casn, ddrx_rasn, ddrx_wen, ddrx_cke, ddrx_odti (1) Only used on 32-bit wide DDR2 memory systems. 8.7.2.2.9 DDR2 Signal Termination Signal terminators are required in CK and ADDR_CTRL net classes. Serial terminators may be used on data lines to reduce EMI risk; however, serial terminations are the only type permitted. ODTs are integrated on the data byte net classes. They should be enabled to ensure signal integrity.Table 8-39 shows the specifications for the series terminators. Table 8-39. DDR2 Signal Terminations NO. PARAMETER MIN ST21 CK net class(1)(2) 0 ST22 ADDR_CTRL net class(1)(2)(3)(4) 0 ST23 Data byte net classes (DQS0-DQS3, DQ0-DQ3) (5) 0 TYP 22 MAX UNIT 10 Ω Zo Ω Zo Ω (1) Only series termination is permitted, parallel or SST specifically disallowed on board. (2) Only required for EMI reduction. (3) Terminator values larger than typical only recommended to address EMI issues. (4) Termination value should be uniform across net class. (5) No external terminations allowed for data byte net classes. ODT is to be used. 8.7.2.2.10 VREF Routing VREF (ddrx_vref0) is used as a reference by the input buffers of the DDR2 memories as well as the processor. VREF is intended to be half the DDR2 power supply voltage and should be created using a resistive divider as shown in Figure 8-51. Other methods of creating VREF are not recommended. Figure 8-54 shows the layout guidelines for VREF. 408 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 VREF Bypass Capacitor DDR2 Device DDR2 Device VREF Nominal Max Trace width is 20 mils DDR2 Controller Neck down to minimum in BGA escape regions is acceptable. Narrowing to accomodate via congestion for short distances is also acceptable. Best performance is obtained if the width of VREF is maximized. PCB_DDR2_5 Figure 8-54. VREF Routing and Topology 8.7.2.3 DDR2 CK and ADDR_CTRL Routing B DDR2 Device DDR2 Device Figure 8-55 shows the topology of the routing for the CK and ADDR_CTRL net classes. The route is a balanced T as it is intended that the length of segments B and C be equal. In addition, the length of A = (A'+A'') should be maximized. C A” DDR2 Controller T A’ PCB_DDR2_6 Figure 8-55. CK and ADDR_CTRL Routing and Topology Table 8-40. CK and ADDR_CTRL Routing Specification (1) NO. PARAMETER RSC21 Center-to-center ddrx_ck - ddrx_nck spacing RSC22 ddrx_ck / ddrx_nck skew(1) RSC23 CK A-to-B/A-to-C skew mismatch (2) MIN MAX UNIT 2w 5 ps 10 ps Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 409 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-40. CK and ADDR_CTRL Routing Specification NO. (1) (continued) PARAMETER MAX UNIT 10 ps CK/ADDR_CTRL trace length(4) 680 ps RSC27 ADDR_CTRL-to-CK skew mismatch 25 ps RSC28 ADDR_CTRL-to-ADDR_CTRL skew mismatch 25 ps RSC29 Center-to-center ADDR_CTRL to other DDR2 trace spacing(3) 4w RSC210 Center-to-center ADDR_CTRL to other ADDR_CTRL trace spacing(3) 3w 25 ps 25 ps RSC24 CK B-to-C skew mismatch RSC25 Center-to-center CK to other DDR2 trace spacing(3) RSC26 RSC211 ADDR_CTRL A-to-B/A-to-C skew mismatch RSC212 ADDR_CTRL B-to-C skew mismatch MIN 4w (2) (1) The length of segment A = A' + A′′ as shown in Figure 8-55. (2) Series terminator, if used, should be located closest to the Device. (3) Center-to-center spacing is allowed to fall to minimum 2w for up to 500 mils of routed length to accommodate BGA escape and routing congestion. (4) This is the longest routing length of the CK and ADDR_CTRL net classes. (5) Length of A should be maximized. DDR2 Device DDR2 Device Figure 8-56 shows the topology and routing for the DQS and DQ net classes; the routes are point to point. Skew matching across bytes is not needed nor recommended. E2 E3 E0 E1 DDR2 Controller PCB_DDR2_7 Figure 8-56. DQS and DQ Routing and Topology Table 8-41. DQS and DQ Routing Specification NO. PARAMETER MIN MAX UNIT 5 ps RSDQ21 Center-to-center DQS-DQSn spacing in E0|E1|E2|E3 RSDQ22 DQS-DQSn skew in E0|E1|E2|E3 2w RSDQ23 Center-to-center DQS to other DDR2 trace spacing(1) RSDQ24 DQS/DQ trace length (2)(3)(4) 325 ps RSDQ25 DQ-to-DQS skew mismatch(2)(3)(4) 10 ps RSDQ26 DQ-to-DQ skew mismatch(2)(3)(4) 10 ps 1 Vias 25 ps 4w (2)(3)(4) RSDQ27 DQ-to-DQ/DQS via count mismatch RSDQ28 Center-to-center DQ to other DDR2 trace spacing(1)(5) 4w RSDQ29 Center-to-center DQ to other DQ trace spacing(1)(6)(7) 3w RSDQ210 DQ/DQS E skew mismatch(2)(3)(4) 410 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (1) Center-to-center spacing is allowed to fall to minimum 2w for up to 500 mils of routed length to accommodate BGA escape and routing congestion. (2) A 16-bit DDR memory system has two sets of data net classes; one for data byte 0, and one for data byte 1, each with an associated DQS (2 DQSs) per DDR EMIF used. (3) A 32-bit DDR memory system has four sets of data net classes; one each for data bytes 0 through 3, and each associated with a DQS (4 DQSs) per DDR EMIF used. (4) There is no need, and it is not recommended, to skew match across data bytes; that is, from DQS0 and data byte 0 to DQS1 and data byte 1. (5) DQs from other DQS domains are considered other DDR2 trace. (6) DQs from other data bytes are considered other DDR2 trace. (7) This is the longest routing distance of each of the DQS and DQ net classes. 8.7.3 DDR3 Board Design and Layout Guidelines 8.7.3.1 Board Designs TI only supports board designs using DDR3 memory that follow the guidelines in this document. The switching characteristics and timing diagram for the DDR3 memory controller are shown in Table 8-42 and Figure 8-57. Table 8-42. Switching Characteristics Over Recommended Operating Conditions for DDR3 Memory Controller NO. 1 PARAMETER tc(DDR_CLK) Cycle time, DDR_CLK MIN MAX UNIT 1.875 2.5(1) ns (1) This is the absolute maximum the clock period can be. Actual maximum clock period may be limited by DDR3 speed grade and operating frequency (see the DDR3 memory device data sheet). 1 DDR_CLK Figure 8-57. DDR3 Memory Controller Clock Timing 8.7.3.1.1 DDR3 versus DDR2 This specification only covers device PCB designs that use DDR3 memory. Designs using DDR2 memory should use the PCB design specifications for DDR2 memory . While similar, the two memory systems have different requirements. It is currently not possible to design one PCB that covers both DDR2 and DDR3. 8.7.3.2 DDR3 EMIFs The processor contains two separate DDR3 EMIFs. This specification covers one of these EMIFs (ddr1_*) and, thus, needs to be implemented twice, once for each EMIF. The PCB layout generally turns out to be a semi-mirror with ddr2_* being a flipped version of ddr1_*; the only exception being the DDR3 devices themselves are not flipped unless mounted on opposite sides of the PCB. Requirements are identical between the two EMIFs. 8.7.3.3 DDR3 Device Combinations Because there are several possible combinations of device counts and single- or dual-side mounting, Table 8-43 summarizes the supported device configurations. Table 8-43. Supported DDR3 Device Combinations(1) NUMBER OF DDR3 DEVICES DDR3 DEVICE WIDTH (BITS) MIRRORED? DDR3 EMIF WIDTH (BITS) 1 16 N 16 2 8 Y(2) 16 Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 411 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-43. Supported DDR3 Device Combinations(1) (continued) NUMBER OF DDR3 DEVICES DDR3 DEVICE WIDTH (BITS) MIRRORED? DDR3 EMIF WIDTH (BITS) 2 16 N 32 2 16 3 16 N 32 4 8 N 32 4 8 5 8 Y (2) Y (3) N 32 32 32 (1) This table is per EMIF. (2) Two DDR3 devices are mirrored when one device is placed on the top of the board and the second device is placed on the bottom of the board. (3) This is two mirrored pairs of DDR3 devices. 8.7.3.4 DDR3 Interface Schematic 8.7.3.4.1 32-Bit DDR3 Interface The DDR3 interface schematic varies, depending upon the width of the DDR3 devices used and the width of the bus used (16 or 32 bits). General connectivity is straightforward and very similar. 16-bit DDR devices look like two 8-bit devices. Figure 8-58 and Figure 8-59 show the schematic connections for 32-bit interfaces using x16 devices. 8.7.3.4.2 16-Bit DDR3 Interface Note that the 16-bit wide interface schematic is practically identical to the 32-bit interface (see Figure 8-58 and Figure 8-59); only the high-word DDR memories are removed and the unused DQS inputs are tied off. When not using all of part of a DDR interface, the proper method of handling the unused pins is to tie off the ddrx_dqsi pins to ground via a 1k-Ω resistor and to tie off the ddrx_dqsni pins to the corresponding vdds_ddrx supply via a 1k-Ω resistor. This needs to be done for each byte not used. Although these signals have internal pullups and pulldowns, external pullups and pulldowns provide additional protection against external electrical noise causing activity on the signals. The vdds_ddrx and ddrx_vref0 power supply pins need to be connected to their respective power supplies even if ddrx is not being used. All other DDR interface pins can be left unconnected. Note that the supported modes for use of the DDR EMIF are 32-bits wide, 16-bits wide, or not used. 412 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Figure 8-58. 32-Bit, One-Bank DDR3 Interface Schematic Using Two 16-Bit DDR3 Devices Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 413 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Figure 8-59. 32-Bit, One-Bank DDR3 Interface Schematic Using Four 8-Bit DDR3 Devices 414 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 8.7.3.5 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Compatible JEDEC DDR3 Devices Table 8-44 shows the parameters of the JEDEC DDR3 devices that are compatible with this interface. Generally, the DDR3 interface is compatible with DDR3-1066 devices in the x8 or x16 widths. Table 8-44. Compatible JEDEC DDR3 Devices (Per Interface) N O. 1 PARAMETER CONDITION JEDEC DDR3 device speed grade(1) MIN MAX DDR clock rate = 400MHz DDR3-800 DDR3-1600 400MHz< DDR clock rate ≤ 533MHz DDR3-1066 DDR3-1600 UNIT 2 JEDEC DDR3 device bit width x8 x16 Bits 3 JEDEC DDR3 device count(2) 2 4 Devices (1) Refer to Table 8-42 Switching Characteristics Over Recommended Operating Conditions for DDR3 Memory Controller for the range of supported DDR clock rates. (2) For valid DDR3 device configurations and device counts, see Section 8.7.3.4, Figure 8-58, and Figure 8-59. 8.7.3.6 PCB Stackup The minimum stackup for routing the DDR3 interface is a six-layer stack up as shown in Table 8-45. Additional layers may be added to the PCB stackup to accommodate other circuitry, enhance SI/EMI performance, or to reduce the size of the PCB footprint. Complete stackup specifications are provided in Table 8-46. Table 8-45. Six-Layer PCB Stackup Suggestion LAYER TYPE DESCRIPTION 1 Signal Top routing mostly vertical 2 Plane Ground 3 Plane Split power plane 4 Plane Split power plane or Internal routing 5 Plane Ground 6 Signal Bottom routing mostly horizontal Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 415 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-46. PCB Stackup Specifications NO. PARAMETER MIN PS1 PCB routing/plane layers 6 PS2 Signal routing layers 3 PS3 Full ground reference layers under DDR3 routing region(1) TYP MAX 1 (1) PS4 Full 1.5-V power reference layers under the DDR3 routing region PS5 Number of reference plane cuts allowed within DDR routing region(2) 0 PS6 Number of layers between DDR3 routing layer and reference plane(3) 0 PS7 PCB routing feature size 4 PS8 PCB trace width, w 4 PS9 Single-ended impedance, Zo PS10 UNIT (5) Impedance control 1 50 Z-5 Z Mils Mils 75 Ω Z+5 Ω (1) Ground reference layers are preferred over power reference layers. Be sure to include bypass caps to accommodate reference layer return current as the trace routes switch routing layers. (2) No traces should cross reference plane cuts within the DDR routing region. High-speed signal traces crossing reference plane cuts create large return current paths which can lead to excessive crosstalk and EMI radiation. (3) Reference planes are to be directly adjacent to the signal plane to minimize the size of the return current loop. (4) An 18-mil pad assumes Via Channel is the most economical BGA escape. A 20-mil pad may be used if additional layers are available for power routing. An 18-mil pad is required for minimum layer count escape. (5) Z is the nominal singled-ended impedance selected for the PCB specified by PS9. 8.7.3.7 Placement Figure 8-60 shows the required placement for the processor as well as the DDR3 devices. The dimensions for this figure are defined in Table 8-47. The placement does not restrict the side of the PCB on which the devices are mounted. The ultimate purpose of the placement is to limit the maximum trace lengths and allow for proper routing space. For a 16-bit DDR memory system, the high-word DDR3 devices are omitted from the placement. 416 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 x3 x2 x1 y1 y2 y2 DDR3 Controller y2 y2 y2 PCB_DDR3_3 Figure 8-60. Placement Specifications Table 8-47. Placement Specifications DDR3 NO. PARAMETER MIN MAX UNIT KOD31 X1 500 Mils KOD32 X2 600 Mils KOD33 X3 600 Mils KOD34 Y1 1800 Mils KOD35 Y2 600 Mils KOD36 DDR3 keepout region (1) KOD37 Clearance from non-DDR3 signal to DDR3 keepout region (2) (3) 4 W Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 417 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com (1) DDR3 keepout region to encompass entire DDR3 routing area. (2) Non-DDR3 signals allowed within DDR3 keepout region provided they are separated from DDR3 routing layers by a ground plane. (3) If a device has more than one DDR controller, the signals from the other controller(s) are considered non-DDR3 and should be separated by this specification. 8.7.3.8 DDR3 Keepout Region The region of the PCB used for DDR3 circuitry must be isolated from other signals. The DDR3 keepout region is defined for this purpose and is shown in Figure 8-61. The size of this region varies with the placement and DDR routing. Additional clearances required for the keepout region are shown in Table 847. Non-DDR3 signals should not be routed on the DDR signal layers within the DDR3 keepout region. Non-DDR3 signals may be routed in the region, provided they are routed on layers separated from the DDR signal layers by a ground layer. No breaks should be allowed in the reference ground layers in this region. In addition, the 1.5-V DDR3 power plane should cover the entire keepout region. Also note that the two signals from the DDR3 controller should be separated from each other by the specification in Table 847, (see KOD37). DDR3 Keepout Region DDR3 Controller PCB_DDR3_4 Figure 8-61. DDR3 Keepout Region 8.7.3.9 Bulk Bypass Capacitors Bulk bypass capacitors are required for moderate speed bypassing of the DDR3 and other circuitry. Table 8-48 contains the minimum numbers and capacitance required for the bulk bypass capacitors. Note that this table only covers the bypass needs of the DDR3 controllers and DDR3 devices. Additional bulk bypass capacitance may be needed for other circuitry. 418 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Table 8-48. Bulk Bypass Capacitors NO. PARAMETER MIN MAX UNIT 1 vdds_ddrx bulk bypass capacitor count(1) 1 Devices 2 vdds_ddrx bulk bypass total capacitance 22 μF (1) These devices should be placed near the devices they are bypassing, but preference should be given to the placement of the highspeed (HS) bypass capacitors and DDR3 signal routing. 8.7.3.10 High-Speed Bypass Capacitors High-speed (HS) bypass capacitors are critcal for proper DDR3 interface operation. It is particularly important to minimize the parasitic series inductance of the HS bypass capacitors, processor/DDR power, and processor/DDR ground connections. Table 8-49 contains the specification for the HS bypass capacitors as well as for the power connections on the PCB. Generally speaking, it is good to: 1. Fit as many HS bypass capacitors as possible. 2. Minimize the distance from the bypass cap to the pins/balls being bypassed. 3. Use the smallest physical sized capacitors possible with the highest capacitance readily available. 4. Connect the bypass capacitor pads to their vias using the widest traces possible and using the largest hole size via possible. 5. Minimize via sharing. Note the limites on via sharing shown in Table 8-49. Table 8-49. High-Speed Bypass Capacitors NO. PARAMETER MIN 1 HS bypass capacitor package size(1) 2 Distance, HS bypass capacitor to processor being bypassed(2)(3)(4) 3 processor HS bypass capacitor count per vdds_ddrx rail (12) 4 processor HS bypass capacitor total capacitance per vdds_ddrx rail (12) TYP MAX UNIT 0201 0402 10 Mils 400 See Table 8-3 and (11) Mils Devices See Table 8-3 and (11) μF (5) 5 Number of connection vias for each device power/ground ball 6 Trace length from device power/ground ball to connection via(2) 7 Distance, HS bypass capacitor to DDR device being bypassed 8 DDR3 device HS bypass capacitor count(7) 9 DDR3 device HS bypass capacitor total capacitance(7) Vias 35 (6) (8)(9) 10 Number of connection vias for each HS capacitor 11 Trace length from bypass capacitor connect to connection via(2)(9) 12 Number of connection vias for each DDR3 device power/ground ball(10) 13 Trace length from DDR3 device power/ground ball to connection via(2)(8) 70 Mils 150 Mils 12 Devices 0.85 μF 2 Vias 35 100 1 Mils Vias 35 60 Mils (1) LxW, 10-mil units, that is, a 0402 is a 40x20-mil surface-mount capacitor. (2) Closer/shorter is better. (3) Measured from the nearest processor power/ground ball to the center of the capacitor package. (4) Three of these capacitors should be located underneath the processor, between the cluster of DDR_1V5 balls and ground balls, between the DDR interfaces on the package. (5) See the Via Channel™ escape for the processor package. (6) Measured from the DDR3 device power/ground ball to the center of the capacitor package. (7) Per DDR3 device. (8) An additional HS bypass capacitor can share the connection vias only if it is mounted on the opposite side of the board. No sharing of vias is permitted on the same side of the board. (9) An HS bypass capacitor may share a via with a DDR device mounted on the same side of the PCB. A wide trace should be used for the connection and the length from the capacitor pad to the DDR device pad should be less than 150 mils. (10) Up to a total of two pairs of DDR power/ground balls may share a via. (11) The capacitor recommendations in this data manual reflect only the needs of this processor. Please see the memory vendor’s guidelines for determining the appropriate decoupling capacitor arrangement for the memory device itself. (12) For more information, see Section 8.3, Core Power Domains Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 419 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.7.3.10.1 Return Current Bypass Capacitors Use additional bypass capacitors if the return current reference plane changes due to DDR3 signals hopping from one signal layer to another. The bypass capacitor here provides a path for the return current to hop planes along with the signal. As many of these return current bypass capacitors should be used as possible. Because these are returns for signal current, the signal via size may be used for these capacitors. 8.7.3.11 Net Classes Table 8-50 lists the clock net classes for the DDR3 interface. Table 8-51 lists the signal net classes, and associated clock net classes, for signals in the DDR3 interface. These net classes are used for the termination and routing rules that follow. Table 8-50. Clock Net Class Definitions CLOCK NET CLASS CK processor PIN NAMES ddrx_ck/ddrx_nck DQS0 ddrx_dqs0 / ddrx_dqsn0 DQS1 ddrx_dqs1 / ddrx_dqsn1 (1) ddrx_dqs2 / ddrx_dqsn2 DQS3(1) ddrx_dqs3 / ddrx_dqsn3 DQS2 (1) Only used on 32-bit wide DDR3 memory systems. Table 8-51. Signal Net Class Definitions SIGNAL NET CLASS ASSOCIATED CLOCK NET CLASS ADDR_CTRL CK DQ0 DQS0 ddrx_d[7:0], ddrx_dqm0 DQ1 DQS1 ddrx_d[15:8], ddrx_dqm1 DQ2(1) DQS2 ddrx_d[23:16], ddrx_dqm2 DQ3(1) DQS3 ddrx_d[31:24], ddrx_dqm3 processor PIN NAMES ddrx_ba[2:0], ddrx_a[14:0], ddrx_csnj, ddrx_casn, ddrx_rasn, ddrx_wen, ddrx_cke, ddrx_odti (1) Only used on 32-bit wide DDR3 memory systems. 8.7.3.12 DDR3 Signal Termination Signal terminators are required for the CK and ADDR_CTRL net classes. The data lines are terminated by ODT and, thus, the PCB traces should be unterminated. Detailed termination specifications are covered in the routing rules in the following sections. 8.7.3.13 VREF_DDR Routing ddrx_vref0 (VREF) is used as a reference by the input buffers of the DDR3 memories as well as the processor. VREF is intended to be half the DDR3 power supply voltage and is typically generated with the DDR3 VDDS and VTT power supply. It should be routed as a nominal 20-mil wide trace with 0.1 µF bypass capacitors near each device connection. Narrowing of VREF is allowed to accommodate routing congestion. 8.7.3.14 VTT Like VREF, the nominal value of the VTT supply is half the DDR3 supply voltage. Unlike VREF, VTT is expected to source and sink current, specifically the termination current for the ADDR_CTRL net class Thevinen terminators. VTT is needed at the end of the address bus and it should be routed as a power sub-plane. VTT should be bypassed near the terminator resistors. 420 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 8.7.3.15 CK and ADDR_CTRL Topologies and Routing Definition The CK and ADDR_CTRL net classes are routed similarly and are length matched to minimize skew between them. CK is a bit more complicated because it runs at a higher transition rate and is differential. The following subsections show the topology and routing for various DDR3 configurations for CK and ADDR_CTRL. The figures in the following subsections define the terms for the routing specification detailed in Table 8-52. 8.7.3.15.1 Four DDR3 Devices Four DDR3 devices are supported on the DDR EMIF consisting of four x8 DDR3 devices arranged as one bank (CS). These four devices may be mounted on a single side of the PCB, or may be mirrored in two pairs to save board space at a cost of increased routing complexity and parts on the backside of the PCB. 8.7.3.15.1.1 CK and ADDR_CTRL Topologies, Four DDR3 Devices Figure 8-62 shows the topology of the CK net classes and Figure 8-63 shows the topology for the corresponding ADDR_CTRL net classes. + – + – + – + – AS+ AS- AS+ AS- AS+ AS- AS+ AS- DDR Differential CK Input Buffers Clock Parallel Terminator DDR_1V5 Rcp A1 Processor Differential Clock Output Buffer A2 A3 A3 A4 AT Cac + – Rcp A1 A2 A3 A3 A4 0.1 µF AT Routed as Differential Pair Figure 8-62. CK Topology for Four x8 DDR3 Devices Processor Address and Control Output Buffer A1 A2 A3 A4 AS AS AS AS DDR Address and Control Input Buffers A3 Address and Control Terminator Rtt Vtt AT Figure 8-63. ADDR_CTRL Topology for Four x8 DDR3 Devices 8.7.3.15.1.2 CK and ADDR_CTRL Routing, Four DDR3 Devices Figure 8-64 shows the CK routing for four DDR3 devices placed on the same side of the PCB. Figure 8-65 shows the corresponding ADDR_CTRL routing. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 421 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com A1 A1 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DDR_1V5 A3 A3 = A3 A3 A4 A4 Rcp Cac Rcp 0.1 µF AT AT AS+ AS- A2 A2 A1 Figure 8-64. CK Routing for Four Single-Side DDR3 Devices Rtt A3 = A4 A3 AT Vtt AS A2 Figure 8-65. ADDR_CTRL Routing for Four Single-Side DDR3 Devices To save PCB space, the four DDR3 memories may be mounted as two mirrored pairs at a cost of increased routing and assembly complexity. Figure 8-66 and Figure 8-67 show the routing for CK and ADDR_CTRL, respectively, for four DDR3 devices mirrored in a two-pair configuration. 422 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 A1 A1 www.ti.com DDR_1V5 A3 A3 = A3 A3 A4 A4 Rcp Cac Rcp 0.1 µF AT AT AS+ AS- A2 A2 A1 Figure 8-66. CK Routing for Four Mirrored DDR3 Devices Rtt = A4 A3 AT Vtt AS A3 A2 Figure 8-67. ADDR_CTRL Routing for Four Mirrored DDR3 Devices 8.7.3.15.2 Two DDR3 Devices Two DDR3 devices are supported on the DDR EMIF consisting of two x8 DDR3 devices arranged as one bank (CS), 16 bits wide, or two x16 DDR3 devices arranged as one bank (CS), 32 bits wide. These two devices may be mounted on a single side of the PCB, or may be mirrored in a pair to save board space at a cost of increased routing complexity and parts on the backside of the PCB. 8.7.3.15.2.1 CK and ADDR_CTRL Topologies, Two DDR3 Devices Figure 8-68 shows the topology of the CK net classes and Figure 8-69 shows the topology for the corresponding ADDR_CTRL net classes. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 423 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com + – + – AS+ AS- AS+ AS- DDR Differential CK Input Buffers Clock Parallel Terminator DDR_1V5 Rcp A1 Processor Differential Clock Output Buffer A2 A3 AT Cac + – Rcp A1 A2 A3 0.1 µF AT Routed as Differential Pair Figure 8-68. CK Topology for Two DDR3 Devices Processor Address and Control Output Buffer A1 A2 AS AS DDR Address and Control Input Buffers A3 Address and Control Terminator Rtt Vtt AT Figure 8-69. ADDR_CTRL Topology for Two DDR3 Devices 8.7.3.15.2.2 CK and ADDR_CTRL Routing, Two DDR3 Devices Figure 8-70 shows the CK routing for two DDR3 devices placed on the same side of the PCB. Figure 8-71 shows the corresponding ADDR_CTRL routing. 424 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 A1 A1 www.ti.com DDR_1V5 A3 A3 = Rcp Cac Rcp 0.1 µF AT AT AS+ AS- A2 A2 A1 Figure 8-70. CK Routing for Two Single-Side DDR3 Devices Rtt A3 = AT Vtt AS A2 Figure 8-71. ADDR_CTRL Routing for Two Single-Side DDR3 Devices To save PCB space, the two DDR3 memories may be mounted as a mirrored pair at a cost of increased routing and assembly complexity. Figure 8-72 and Figure 8-73 show the routing for CK and ADDR_CTRL, respectively, for two DDR3 devices mirrored in a single-pair configuration. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 425 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com A1 A1 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DDR_1V5 A3 A3 = Rcp Cac Rcp 0.1 µF AT AT AS+ AS- A2 A2 A1 Figure 8-72. CK Routing for Two Mirrored DDR3 Devices Rtt = AT Vtt AS A3 A2 Figure 8-73. ADDR_CTRL Routing for Two Mirrored DDR3 Devices 8.7.3.15.3 One DDR3 Device A single DDR3 device is supported on the DDR EMIF consisting of one x16 DDR3 device arranged as one bank (CS), 16 bits wide. 8.7.3.15.3.1 CK and ADDR_CTRL Topologies, One DDR3 Device Figure 8-74 shows the topology of the CK net classes and Figure 8-75 shows the topology for the corresponding ADDR_CTRL net classes. 426 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DDR Differential CK Input Buffer AS+ AS- + – Clock Parallel Terminator DDR_1V5 Rcp A1 Processor Differential Clock Output Buffer A2 AT Cac + – Rcp A1 A2 0.1 µF AT Routed as Differential Pair Figure 8-74. CK Topology for One DDR3 Device AS DDR Address and Control Input Buffers Processor Address and Control Output Buffer A1 A2 Address and Control Terminator Rtt AT Vtt Figure 8-75. ADDR_CTRL Topology for One DDR3 Device 8.7.3.15.3.2 CK and ADDR/CTRL Routing, One DDR3 Device Figure 8-76 shows the CK routing for one DDR3 device placed on the same side of the PCB. Figure 8-77 shows the corresponding ADDR_CTRL routing. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 427 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com A1 A1 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DDR_1V5 Rcp Cac Rcp 0.1 µF AT AT = AS+ AS- A2 A2 A1 Figure 8-76. CK Routing for One DDR3 Device Rtt AT = Vtt AS A2 Figure 8-77. ADDR_CTRL Routing for One DDR3 Device 8.7.3.16 Data Topologies and Routing Definition No matter the number of DDR3 devices used, the data line topology is always point to point, so its definition is simple. Care should be taken to minimize layer transitions during routing. If a layer transition is necessary, it is better to transition to a layer using the same reference plane. If this cannot be accommodated, ensure there are nearby ground vias to allow the return currents to transition between reference planes if both reference planes are ground or vdds_ddr. Ensure there are nearby bypass capacitors to allow the return currents to transition between reference planes if one of the reference planes is ground. The goal is to minimize the size of the return current loops. 8.7.3.16.1 DQS and DQ/DM Topologies, Any Number of Allowed DDR3 Devices DQS lines are point-to-point differential, and DQ/DM lines are point-to-point singled ended. Figure 8-78 and Figure 8-79 show these topologies. 428 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Processor DQS IO Buffer DDR DQS IO Buffer DQSn+ DQSnRouted Differentially n = 0, 1, 2, 3 Figure 8-78. DQS Topology Processor DQ and DM IO Buffer DDR DQ and DM IO Buffer Dn n = 0, 1, 2, 3 Figure 8-79. DQ/DM Topology 8.7.3.16.2 DQS and DQ/DM Routing, Any Number of Allowed DDR3 Devices Figure 8-80 and Figure 8-81 show the DQS and DQ/DM routing. DQSn+ DQSn- DQS Routed Differentially n = 0, 1, 2, 3 Figure 8-80. DQS Routing With Any Number of Allowed DDR3 Devices Dn DQ and DM n = 0, 1, 2, 3 Figure 8-81. DQ/DM Routing With Any Number of Allowed DDR3 Devices Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 429 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 8.7.3.17 Routing Specification 8.7.3.17.1 CK and ADDR_CTRL Routing Specification Skew within the CK and ADDR_CTRL net classes directly reduces setup and hold margin and, thus, this skew must be controlled. The only way to practically match lengths on a PCB is to lengthen the shorter traces up to the length of the longest net in the net class and its associated clock. A metric to establish this maximum length is Manhattan distance. The Manhattan distance between two points on a PCB is the length between the points when connecting them only with horizontal or vertical segments. A reasonable trace route length is to within a percentage of its Manhattan distance. CACLM is defined as Clock Address Control Longest Manhattan distance. Given the clock and address pin locations on the processor and the DDR3 memories, the maximum possible Manhattan distance can be determined given the placement. Figure 8-82 and Figure 8-83 show this distance for four loads and two loads, respectively. It is from this distance that the specifications on the lengths of the transmission lines for the address bus are determined. CACLM is determined similarly for other address bus configurations; that is, it is based on the longest net of the CK/ADDR_CTRL net class. For CK and ADDR_CTRL routing, these specifications are contained in Table 8-52. (A) A1 A8 CACLMY CACLMX A8 (A) A8 (A) A8 (A) A8 (A) Rtt A3 = A. A4 A3 AT Vtt AS A2 It is very likely that the longest CK/ADDR_CTRL Manhattan distance will be for Address Input 8 (A8) on the DDR3 memories. CACLM is based on the longest Manhattan distance due to the device placement. Verify the net class that satisfies this criteria and use as the baseline for CK/ADDR_CTRL skew matching and length control. The length of shorter CK/ADDR_CTRL stubs as well as the length of the terminator stub are not included in this length calculation. Non-included lengths are grayed out in the figure. Assuming A8 is the longest, CALM = CACLMY + CACLMX + 300 mils. The extra 300 mils allows for routing down lower than the DDR3 memories and returning up to reach A8. Figure 8-82. CACLM for Four Address Loads on One Side of PCB 430 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 (A) A1 A8 CACLMY CACLMX A8 (A) A8 (A) Rtt A3 = A. AT Vtt AS A2 It is very likely that the longest CK/ADDR_CTRL Manhattan distance will be for Address Input 8 (A8) on the DDR3 memories. CACLM is based on the longest Manhattan distance due to the device placement. Verify the net class that satisfies this criteria and use as the baseline for CK/ADDR_CTRL skew matching and length control. The length of shorter CK/ADDR_CTRL stubs as well as the length of the terminator stub are not included in this length calculation. Non-included lengths are grayed out in the figure. Assuming A8 is the longest, CALM = CACLMY + CACLMX + 300 mils. The extra 300 mils allows for routing down lower than the DDR3 memories and returning up to reach A8. Figure 8-83. CACLM for Two Address Loads on One Side of PCB Table 8-52. CK and ADDR_CTRL Routing Specification(2)(3) MAX UNIT CARS31 NO. A1+A2 length PARAMETER MIN TYP 500(1) ps CARS32 A1+A2 skew 29 ps CARS33 A3 length 125 ps CARS34 (4) A3 skew 6 ps CARS35 A3 skew(5) 6 ps CARS36 A4 length 125 ps CARS37 A4 skew 6 ps CARS38 AS length 5(1) 17 ps CARS39 AS skew 1.3(1) 14 ps CARS310 AS+/AS- length 5 12 ps CARS311 AS+/AS- skew 1 ps CARS312 AT length(6) 75 ps CARS313 AT skew(7) 14 ps CARS314 (8) AT skew CARS315 CK/ADDR_CTRL trace length CARS316 Vias per trace CARS317 Via count difference 1 (9) CARS318 Center-to-center CK to other DDR3 trace spacing CARS319 Center-to-center ADDR_CTRL to other DDR3 trace spacing(9)(10) 4w CARS320 Center-to-center ADDR_CTRL to other ADDR_CTRL trace spacing(9) 3w CARS321 CK center-to-center spacing(11)(12) ps 3(1) vias 1(15) vias 4w Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated ps 1020 431 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 8-52. CK and ADDR_CTRL Routing Specification(2)(3) (continued) NO. PARAMETER CARS322 CK spacing to other net(9) CARS323 Rcp(13) CARS324 Rtt(13)(14) MIN TYP MAX UNIT Zo-1 Zo Zo+1 Ω Zo-5 Zo Zo+5 Ω 4w (1) Max value is based upon conservative signal integrity approach. This value could be extended only if detailed signal integrity analysis of rice time and fall time confirms desired operation. (2) The use of vias should be minimized. (3) Additional bypass capacitors are required when using the DDR_1V5 plane as the reference plane to allow the return current to jump between the DDR_1V5 plane and the ground plane when the net class switches layers at a via. (4) Non-mirrored configuration (all DDR3 memories on same side of PCB). (5) Mirrored configuration (one DDR3 device on top of the board and one DDR3 device on the bottom). (6) While this length can be increased for convenience, its length should be minimized. (7) ADDR_CTRL net class only (not CK net class). Minimizing this skew is recommended, but not required. (8) CK net class only. (9) Center-to-center spacing is allowed to fall to minimum 2w for up to 1250 mils of routed length. (10) The ADDR_CTRL net class of the other DDR EMIF is considered other DDR3 trace spacing. (11) CK spacing set to ensure proper differential impedance. (12) The most important thing to do is control the impedance so inadvertent impedance mismatches are not created. Generally speaking, center-to-center spacing should be either 2w or slightly larger than 2w to achieve a differential impedance equal to twice the singleended impedance, Zo. (13) Source termination (series resistor at driver) is specifically not allowed. (14) Termination values should be uniform across the net class. (15) Via count difference may increase by 1 only if accurate 3-D modeling of the signal flight times – including accurately modeled signal propagation through vias – has been applied to ensure all segment skew maximums are not exceeded. 8.7.3.17.2 DQS and DQ Routing Specification Skew within the DQS and DQ/DM net classes directly reduces setup and hold margin and thus this skew must be controlled. The only way to practically match lengths on a PCB is to lengthen the shorter traces up to the length of the longest net in the net class and its associated clock. As with CK and ADDR_CTRL, a reasonable trace route length is to within a percentage of its Manhattan distance. DQLMn is defined as DQ Longest Manhattan distance n, where n is the byte number. For a 32-bit interface, there are four DQLMs, DQLM0-DQLM3. Likewise, for a 16-bit interface, there are two DQLMs, DQLM0-DQLM1. NOTE It is not required, nor is it recommended, to match the lengths across all bytes. Length matching is only required within each byte. Given the DQS and DQ/DM pin locations on the processor and the DDR3 memories, the maximum possible Manhattan distance can be determined given the placement. Figure 8-84 shows this distance for four loads. It is from this distance that the specifications on the lengths of the transmission lines for the data bus are determined. For DQS and DQ/DM routing, these specifications are contained in Table 8-53. 432 Applications, Implementation, and Layout Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 DQLMX0 DB0 DB1 DQ[0:7]/DM0/DQS0 DQ[8:15]/DM1/DQS1 DQLMX1 DQ[16:23]/DM2/DQS2 DB2 DQLMY0 DQLMX2 DQLMY3 DQLMY2 DB3 DQLMY1 DQ[23:31]/DM3/DQS3 DQLMX3 3 2 1 0 DB0 - DB3 represent data bytes 0 - 3. There are four DQLMs, one for each byte (32-bit interface). Each DQLM is the longest Manhattan distance of the byte; therefore: DQLM0 = DQLMX0 + DQLMY0 DQLM1 = DQLMX1 + DQLMY1 DQLM2 = DQLMX2 + DQLMY2 DQLM3 = DQLMX3 + DQLMY3 Figure 8-84. DQLM for Any Number of Allowed DDR3 Devices Table 8-53. Data Routing Specification(2) MAX UNIT DRS31 NO. DB0 length PARAMETER MIN 340 ps DRS32 DB1 length 340 ps DRS33 DB2 length 340 ps DRS34 DB3 length 340 ps DRS35 DBn skew(3) 5 ps DRS36 DQSn+ to DQSn- skew 1 ps DRS37 DQSn to DBn skew(3)(4) 5(10) ps DRS38 Vias per trace 2(1) vias DRS39 Via count difference 0(10) vias (6) DRS310 Center-to-center DBn to other DDR3 trace spacing DRS311 Center-to-center DBn to other DBn trace spacing (7) DRS312 DQSn center-to-center spacing(8) (9) DRS313 DQSn center-to-center spacing to other net TYP 4 w(5) 3 w(5) 4 w(5) (1) Max value is based upon conservative signal integrity approach. This value could be extended only if detailed signal integrity analysis of rice time and fall time confirms desired operation. (2) External termination disallowed. Data termination should use built-in ODT functionality. (3) Length matching is only done within a byte. Length matching across bytes is neither required nor recommended. (4) Each DQS pair is length matched to its associated byte. (5) Center-to-center spacing is allowed to fall to minimum 2w for up to 1250 mils of routed length. (6) Other DDR3 trace spacing means other DDR3 net classes not within the byte. (7) This applies to spacing within the net classes of a byte. (8) DQS pair spacing is set to ensure proper differential impedance. (9) The most important thing to do is control the impedance so inadvertent impedance mismatches are not created. Generally speaking, center-to-center spacing should be either 2w or slightly larger than 2w to achieve a differential impedance equal to twice the singleended impedance, Zo. (10) Via count difference may increase by 1 only if accurate 3-D modeling of the signal flight times – including accurately modeled signal propagation through vias – has been applied to ensure DBn skew and DQSn to DBn skew maximums are not exceeded. Applications, Implementation, and Layout Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 433 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com 9 Device and Documentation Support TI offers an extensive line of development tools, including methods to evaluate the performance of the processors, generate code, develop algorithm implementations, and fully integrate and debug software and hardware modules as listed below. 9.1 Device Nomenclature To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all microprocessors (MPUs) and support tools. Each device has one of three prefixes: X, P, or null (no prefix) (for example, DRA7xx). Texas Instruments recommends two of three possible prefix designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of product development from engineering prototypes (TMDX) through fully qualified production devices and tools (TMDS). Device development evolutionary flow: X Experimental device that is not necessarily representative of the final device's electrical specifications and may not use production assembly flow. P Prototype device that is not necessarily the final silicon die and may not necessarily meet final electrical specifications. null Production version of the silicon die that is fully qualified. Support tool development evolutionary flow: TMDX Development-support product that has not yet completed Texas Instruments internal qualification testing. TMDS Fully-qualified development-support product. X and P devices and TMDX development-support tools are shipped against the following disclaimer: "Developmental product is intended for internal evaluation purposes." Production devices and TMDS development-support tools have been characterized fully, and the quality and reliability of the device have been demonstrated fully. TI's standard warranty applies. Predictions show that prototype devices (X or P) have a greater failure rate than the standard production devices. Texas Instruments recommends that these devices not be used in any production system because their expected end-use failure rate still is undefined. Only qualified production devices are to be used. For orderable part numbers of DRA7xx devices in the ABC package type, see the Package Option Addendum of this document, the TI website (www.ti.com), or contact your TI sales representative. For additional description of the device nomenclature markings on the die, see the Silicon Errata (literature number SPRZ398). 434 Device and Documentation Support Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 9.1.1 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 Standard Package Symbolization JACINTO aBBBBBBrzYyPPPQ1 XXXXXXX PIN ONE INDICATOR 842 PPP G1 O SWPS857_PACK_01 Figure 9-1. Printed Device Reference NOTE Some devices have a cosmetic circular marking visible on the top of the device package which results from the production test process. These markings are cosmetic only with no reliability impact. 9.1.2 Device Naming Convention Table 9-1. Nomenclature Description FIELD PARAMETER a BBBBBB r z FIELD DESCRIPTION Device evolution stage(1) Base production part number Device revision Device Speed VALUE DESCRIPTION X Prototype P Preproduction (production test flow, no reliability data) BLANK Production DRA744 J6 Low Tier DRA745 J6 Mid Tier DRA746 J6 High Tier DRA750 J6EP Low Tier DRA751 J6EP Mid Tier DRA752 J6EP High Tier DRA754 J6EX Low Tier DRA755 J6EX Mid Tier DRA756 J6EX High Tier BLANK SR 1.0 A SR 1.1 B SR 2.0 P High speed grade L Overdrive speed grade J Nominal speed grade OTHER Alternate speed grade Device and Documentation Support Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 435 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 www.ti.com Table 9-1. Nomenclature Description (continued) FIELD PARAMETER Yy FIELD DESCRIPTION Device type PPP Package designator Q1 Automotive Designator VALUE General purpose (Prototype and Production) E Emulation (E) devices D High security prototype devices with TI Development keys (D) Yn Letter followed by number indicates HS Device with customer key ABC BLANK Q1 XXXXXXX 842 DESCRIPTION G ABC S-PBGA-N760 (23mm x 23mm) Package not meeting automotive qualification meeting Q100 equal requirements, with exceptions as specified in DM. Lot Trace Code Production Code, For TI use only O Pin one designator G1 ECAT—Green package designator (1) To designate the stages in the product development cycle, TI assigns prefixes to the part numbers. These prefixes represent evolutionary stages of product development from engineering prototypes through fully qualified production devices. Prototype devices are shipped against the following disclaimer: “This product is still in development and is intended for internal evaluation purposes.” Notwithstanding any provision to the contrary, TI makes no warranty expressed, implied, or statutory, including any implied warranty of merchantability of fitness for a specific purpose, of this device. NOTE BLANK in the symbol or part number is collapsed so there are no gaps between characters. 9.2 Tools and Software The following products support development for DRA7xx platforms: DRA75xx Pad Configuration Tool is an interactive pad-configuration tool that allows the user to visualize the device pad configuration state on power-on reset and then customize the configuration of the pads for the specific use-case and identify the device register settings associated to that configuration. DRA7xx Register Descriptor Tool is an interactive device register configuration tool that allows users to visualize the register state on power-on reset, and then customize the configuration of the device for the specific use-case. DRA7xx Clock Tree Tool is interactive clock tree configuration software that allows the user to visualize the device clock tree, interact with clock tree elements and view the effect on PRCM registers, interact with the PRCM registers and view the effect on the device clock tree, and view a trace of all the device registers affected by the user interaction with the clock tree. For a complete listing of development-support tools for the processor platform, visit the Texas Instruments website at www.ti.com. For information on pricing and availability, contact the nearest TI field sales office or authorized distributor. 9.3 Documentation Support The following documents describe the DRA75x/DRA74x devices. 436 TRM SPRUHI2DRA75x, DRA74x Infotainment Applications Processor Technical Reference Manual Details the integration, the environment, the functional description, and the programming models for each peripheral and subsystem in the DRA7xx family of devices. Errata DRA75x, DRA74x Silicon Errata Describes known advisories on silicon and provides workarounds. Device and Documentation Support Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com 9.3.1 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 FCC Warning This equipment is intended for use in a laboratory test environment only. It generates, uses, and can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to subpart J of part 15 of FCC rules, which are designed to provide reasonable protection against radio frequency interference. Operation of this equipment in other environments may cause interference with radio communications, in which case the user at his own expense will be required to take whatever measures may be required to correct this interference. 9.3.2 Information About Cautions and Warnings This book may contain cautions and warnings. CAUTION This is an example of a caution statement. A caution statement describes a situation that could potentially damage your software or equipment. WARNING This is an example of a warning statement. A warning statement describes a situation that could potentially cause harm to you. The information in a caution or a warning is provided for your protection. Please read each caution and warning carefully. 9.4 Receiving Notification of Documentation Updates To receive notification of documentation updates — including silicon errata — go to the product folder for your device on www.ti.com. In the upper right-hand corner, click the "Alert me" button. This registers you to receive a weekly digest of product information that has changed (if any). For change details, check the revision history of any revised document. 9.5 Related Links The table below lists quick access links. Categories include technical documents, support and community resources, tools and software, and quick access to sample or buy. Table 9-2. Related Links PARTS PRODUCT FOLDER SAMPLE & BUY TECHNICAL DOCUMENTS TOOLS & SOFTWARE SUPPORT & COMMUNITY DRA744 Click here Click here Click here Click here Click here DRA745 Click here Click here Click here Click here Click here DRA746 Click here Click here Click here Click here Click here DRA750 Click here Click here Click here Click here Click here DRA751 Click here Click here Click here Click here Click here DRA752 Click here Click here Click here Click here Click here DRA754 Click here Click here Click here Click here Click here DRA755 Click here Click here Click here Click here Click here DRA756 Click here Click here Click here Click here Click here Device and Documentation Support Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 437 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 9.6 www.ti.com Community Resources The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. TI Embedded Processors Wiki Texas Instruments Embedded Processors Wiki. Established to help developers get started with Embedded Processors from Texas Instruments and to foster innovation and growth of general knowledge about the hardware and software surrounding these devices. 9.7 Trademarks C66x, ICEPick and SmartReflex are trademarks of Texas Instruments Incorporated. ARM is a registered trademark of ARM Limited. ETB, ARM9, CoreSight, Cortex, and Neon are trademarks of ARM Limited. HDMI is a trademark of HDMI Licensing, LLC. HDQ is a trademark of Benchmarq. 1-Wire is a registered trademark of Dallas Semiconductor. POWERVR and SGX544 are trademarks or registered trademarks of Imagination Technologies Ltd. SD is a registered trademark of Toshiba Corporation. MMC and eMMC are trademarks of MultiMediaCard Association. JTAG is a registered trademark of JTAG Technologies, Inc. PCI-Express is a registered trademark of PCI-SIG. MediaLB is a trademark of Standard Microsystems Corporation. Vivante is a registered trademark of Vivante Corporation. All other trademarks are the property of their respective owners. 9.8 Electrostatic Discharge Caution This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. 9.9 Export Control Notice Recipient agrees to not knowingly export or re-export, directly or indirectly, any product or technical data (as defined by the U.S., EU, and other Export Administration Regulations) including software, or any controlled product restricted by other applicable national regulations, received from disclosing party under nondisclosure obligations (if any), or any direct product of such technology, to any destination to which such export or re-export is restricted or prohibited by U.S. or other applicable laws, without obtaining prior authorization from U.S. Department of Commerce and other competent Government authorities to the extent required by those laws. 9.10 Glossary TI Glossary This glossary lists and explains terms, acronyms, and definitions. 438 Device and Documentation Support Copyright © 2015–2016, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 DRA744, DRA745, DRA746 DRA750, DRA751, DRA752 DRA754, DRA755, DRA756 www.ti.com SPRS950A – DECEMBER 2015 – REVISED APRIL 2016 10 Mechanical Packaging and Orderable Information The following pages include mechanical packaging and orderable information. This information is the most current data available for the designated devices. This data is subject to change without notice and revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation. 10.1 Mechanical Data Figure 10-1. Mechanical Package Mechanical Packaging and Orderable Information Submit Documentation Feedback Product Folder Links: DRA744 DRA745 DRA746 DRA750 DRA751 DRA752 DRA754 DRA755 DRA756 Copyright © 2015–2016, Texas Instruments Incorporated 439 PACKAGE OPTION ADDENDUM www.ti.com 22-Jul-2016 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan Lead/Ball Finish MSL Peak Temp (2) (6) (3) Op Temp (°C) Device Marking (4/5) DRA744BJGABCQ1 PREVIEW FCBGA ABC 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR DRA744BJGABCQ1 JACINTOTM DRA744BJGABCRQ1 PREVIEW FCBGA ABC 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR DRA744BJGABCQ1 JACINTOTM DRA745BLGABCQ1 PREVIEW XCEPT BGA 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR -40 to 125 DRA745BLGABCQ1 JACINTOTM DRA745BLGABCRQ1 PREVIEW XCEPT BGA 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR -40 to 125 DRA745BLGABCQ1 JACINTOTM DRA746APGABCQ1 ACTIVE FCBGA ABC 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR DRA746APGABCQ1 JACINTO DRA746BPGABCQ1 PREVIEW FCBGA ABC 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR DRA746BPGABCQ1 JACINTOTM DRA746BPGABCRQ1 PREVIEW FCBGA ABC 760 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR DRA746BPGABCQ1 JACINTOTM DRA750BJGABCQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA750BJGABCRQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA752BPGABCQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA752BPGABCRQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA754BJGABCQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA754BJGABCRQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA755BLGABCQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA755BLGABCRQ1 PREVIEW XCEPT BGA 760 TBD Call TI Call TI -40 to 125 DRA756 ACTIVE TBD Call TI Call TI DRA756BPGABCQ1 PREVIEW FCBGA ABC 760 60 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR -40 to 125 DRA756BPGABCQ1 JACINTOTM DRA756BPGABCRQ1 PREVIEW FCBGA ABC 760 250 Green (RoHS & no Sb/Br) SNAGCU Level-3-250C-168 HR -40 to 125 DRA756BPGABCQ1 JACINTOTM (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. Addendum-Page 1 Samples PACKAGE OPTION ADDENDUM www.ti.com 22-Jul-2016 (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. (4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device. (5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation of the previous line and the two combined represent the entire Device Marking for that device. (6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish value exceeds the maximum column width. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release. 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