Freescale Semiconductor Data Sheet: Technical Data Document Number: MCIMX35SR2AEC Rev. 10, 06/2012 IMX35 i.MX35 Applications Processors for Automotive Products 1 Introduction The i.MX35 Auto Application Processor family is designed for automotive infotainment and navigation applications. These processors are AECQ100 Grade 3 qualified and rated for ambient operating temperatures up to 85 °C. Based on an ARM11 microprocessor core running at up to 532 MHz, the device offers the following features and optimized system cost for the target applications. • Audio connectivity and telematics: — Compressed audio playback from storage devices (CD, USB, HDD or SD card) — PlayFromDevice (1-wire and 2-wire support) for portable media players — iPod/iPhone control and playback — High-speed CD ripping to USB, SD/MMC or HDD for virtual CD changer — Audio processing for hands-free telephony: Bluetooth, AEC/NS, and microphone beam forming — Speech recognition © Freescale Semiconductor, Inc., 2010. All rights reserved. Package Information Plastic Package Case 5284 17 x 17 mm, 0.8 mm Pitch Ordering Information See Table 1 on page 3 for ordering information. 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.1. Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.2 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . 3 1.3. Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2 Functional Description and Application Information. . . . . . 4 2.1. Application Processor Domain Overview . . . . . . . . . 5 2.2. Shared Domain Overview . . . . . . . . . . . . . . . . . . . . 6 2.3. Advanced Power Management Overview . . . . . . . . 6 2.4. ARM11 Microprocessor Core. . . . . . . . . . . . . . . . . . 6 2.5. Module Inventory . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3. Signal Descriptions: Special Function Related Pins . . . . 12 4. Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 13 4.1. i.MX35 Chip-Level Conditions . . . . . . . . . . . . . . . . 13 4.2. Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 4.3. Supply Power-Up/Power-Down Requirements and Restrictions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 4.4. Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 4.5. Power Characteristics . . . . . . . . . . . . . . . . . . . . . . 19 4.6. Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . 20 4.7. I/O Pin DC Electrical Characteristics . . . . . . . . . . . 21 4.8. I/O Pin AC Electrical Characteristics . . . . . . . . . . . 24 4.9. Module-Level AC Electrical Specifications . . . . . . . 30 5. Package Information and Pinout . . . . . . . . . . . . . . . . . . 131 5.1. MAPBGA Production Package 1568-01, 17 × 17 mm, 0.8 Pitch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132 5.2. MAPBGA Signal Assignments . . . . . . . . . . . . . . . 133 6. Product Documentation . . . . . . . . . . . . . . . . . . . . . . . . . 145 7. Revision History. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146 • A/V connectivity and navigation: — Includes audio connectivity and telematics features — Map display and route calculation — QVGA video decode, WVGA video display — Sophisticated graphical user interface The i.MX35 processor takes advantage of the ARM1136JF-S™ core running at 532 MHz that is boosted by a multilevel cache system, and features peripheral devices such as an autonomous image processing unit, a vector floating point (VFP11) co-processor, and a RISC-based DMA controller. The i.MX35 supports connections to various types of external memories, such as SDRAM, mobile DDR and DDR2, SLC and MLC NAND Flash, NOR Flash and SRAM. The device can be connected to a variety of external devices such as high-speed USB2.0 OTG, ATA, MMC/SDIO, and Compact Flash. 1.1 Features The i.MX35 is designed for automotive infotainment video-enabled applications. It provides low-power solutions for applications demanding high-performance multimedia and graphics. The i.MX35 is based on the ARM1136 platform, which has the following features: • ARM1136JF-S processor, version r1p3 • 16-Kbyte L1 instruction cache • 16-Kbyte L1 data cache • 128-Kbyte L2 cache, version r0p4 • 128 Kbytes of internal SRAM • Vector floating point unit (VFP11) To boost multimedia performance, the following hardware accelerators are integrated: • Image processing unit (IPU) • OpenVG 1.1 graphics processing unit (GPU) (not available for the MCIMX351) The MCIMX35 provides the following interfaces to external devices (some of these interfaces are muxed and not available simultaneously): • 2 controller area network (CAN) interfaces • 2 SDIO/MMC interfaces, 1 SDIO/CE-ATA interface (CE-ATA is not available for the MCIMX351) • 32-bit mobile DDR, DDR2 (4-bank architecture), and SDRAM (up to 133 MHz) • 2 configurable serial peripheral interfaces (CSPI) (up to 52 Mbps each) • Enhanced serial audio interface (ESAI) • 2 synchronous serial interfaces (SSI) • Ethernet MAC 10/100 Mbps • 1 USB 2.0 host with ULPI interface or internal full-speed PHY. Up to 480 Mbps if external HS PHY is used. • 1 USB 2.0 OTG (up to 480 Mbps) controller with internal high-speed OTG PHY i.MX35 Applications Processors for Automotive Products, Rev. 10 2 Freescale Semiconductor • • • • • • • • • • • • • • 1.2 Flash controller—MLC/SLC NAND and NOR GPIO with interrupt capabilities 3 I2C modules (up to 400 Kbytes each) JTAG Key pin port Media local bus (MLB) interface Asynchronous sample rate converter (ASRC) 1-Wire Parallel camera sensor (4/8/10/16-bit data port for video color models: YCC, YUV, 30 Mpixels/s) Parallel display (primary up to 24-bit, 1024 x 1024) Parallel ATA (up to 66 Mbytes) (not available for the MCIMX351) PWM SPDIF transceiver 3 UART (up to 4.0 Mbps each) Ordering Information Table 1 provides the ordering information for the i.MX35 processors for automotive applications. Table 1. Ordering Information 1 2 Description Part Number Silicon Revision Package1 Speed Operating Temperature Range (°C) Signal Ball Map Locations Ball Map i.MX351 MCIMX351AVM4B 2.0 5284 400 MHz –40 to 85 Table 94 Table 96 i.MX351 MCIMX351AVM5B 2.0 5284 532 MHz2 –40 to 85 Table 94 Table 96 i.MX355 MCIMX355AVM4B 2.0 5284 400 MHz –40 to 85 Table 94 Table 96 i.MX355 MCIMX355AVM5B 2.0 5284 532 MHz2 –40 to 85 Table 94 Table 96 i.MX356 MCIMX356AVM4B 2.0 5284 400 MHz –40 to 85 Table 94 Table 96 i.MX356 MCIMX356AVM5B 2.0 5284 532 MHz2 –40 to 85 Table 94 Table 96 i.MX351 MCIMX351AJQ4C 2.1 5284 400MHz -40 to 85 Table 95 Table 97 i.MX351 MCIMX351AJQ5C 2.1 5284 532MHz2 -40 to 85 Table 95 Table 97 i.MX355 MCIMX355AJQ4C 2.1 5284 400MHz -40 to 85 Table 95 Table 97 i.MX355 MCIMX355AJQ5C 2.1 5284 532MHz2 -40 to 85 Table 95 Table 97 i.MX356 MCIMX356AJQ4C 2.1 5284 400MHz -40 to 85 Table 95 Table 97 i.MX356 MCIMX356AJQ5C 2.1 5284 532MHz2 -40 to 85 Table 95 Table 97 i.MX356 SCIMX356BVMB 2 5284 532MHz -40 to 85 Table 94 Table 96 Case 5284 is RoHS-compliant, lead-free, MSL = 3, 1. 532 MHz rated devices meet all specifications of 400 MHz rated devices. A 532 MHz device can be substituted in place of a 400 MHz device. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 3 The ball map for silicon revision 2.1 is different than the ballmap for silicon revision 2.0. The layout for each revision is not compatible, so it is important that the correct ballmap be used to implement the layout. See Section 5, “Package Information and Pinout.” Table 2 shows the functional differences between the different parts in the i.MX35 family. Table 2. Functional Differences in the i.MX35 Parts Module MCIMX351 MCIMX353 MCIMX355 MCIMX356 MCIMX357 I2C (3) Yes Yes Yes Yes Yes CSPI (2) Yes Yes Yes Yes Yes SSI/I2S (2) Yes Yes Yes Yes Yes ESAI Yes Yes Yes Yes Yes SPDIF I/O Yes Yes Yes Yes Yes USB HS Host Yes Yes Yes Yes Yes USB OTG Yes Yes Yes Yes Yes FlexCAN (2) Yes Yes Yes Yes Yes MLB Yes Yes Yes Yes Yes Ethernet Yes Yes Yes Yes Yes 1-Wire Yes Yes Yes Yes Yes KPP Yes Yes Yes Yes Yes SDIO/MMC (2) Yes Yes Yes Yes Yes SDIO/Memory Stick Yes Yes Yes Yes Yes External Memory Controller (EMC) Yes Yes Yes Yes Yes JTAG Yes Yes Yes Yes Yes PATA — Yes Yes Yes Yes CE-ATA — Yes Yes Yes Yes Image Processing Unit (IPU) (inversion and rotation, pre- and post-processing, camera interface, blending, display controller) — Yes Yes Yes Yes Open VG graphics acceleration (GPU) — Yes — Yes Yes i.MX35 Applications Processors for Automotive Products, Rev. 10 4 Freescale Semiconductor 1.3 Block Diagram Figure 1 is the i.MX35 simplified interface block diagram. NOR Flash/ PSRAM DDR2/SDDR RAM NAND Flash Camera Sensor External Memory Interface (EMI) Smart DMA Image Processing Unit (IPU) ARM11 Platform ARM1136JF-S SPBA LCD Display 1 External Graphics Accelerator LCD Display 2 VFP ARM1136 Platform Peripherals SSI HS USBOTG HS USBOTGPHY AUDMUX HS USBHost FS USBPHY L1 I/D cache Peripherals ESAI MSHC SPDIF SSI ASRC L2 cache I2C(3) AVIC UART(2) MAX CSPI AIPS (2) ATA eSDHC(3) ETM UART CSPI GPU 2D Internal Memory FEC CAN(2) ECT MLB IOMUX IIM RTICv3 GPIO(3) RNGC EPIT SCC PWM Timers RTC WDOG OWIRE GPT KPP 3 FuseBox Audio/Power Management JTAG Bluetooth MMC/SDIO or WLAN Keypad Connectivity Access Figure 1. i.MX35 Simplified Interface Block Diagram 2 Functional Description and Application Information The i.MX35 consists of the following major subsystems: • ARM1136 Platform—AP domain • SDMA Platform and EMI—Shared domain 2.1 Application Processor Domain Overview The applications processor (AP) and its domain are responsible for running the operating system and applications software, providing the user interface, and supplying access to integrated and external peripherals. The AP domain is built around an ARM1136JF-S core with 16-Kbyte instruction and data L1 caches, an MMU, a 128-Kbyte L2 cache, a multiported crossbar switch, and advanced debug and trace interfaces. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 5 The i.MX35 core is intended to operate at a maximum frequency of 532 MHz to support the required multimedia use cases. Furthermore, an image processing unit (IPU) is integrated into the AP domain to offload the ARM11 core from performing functions such as color space conversion, image rotation and scaling, graphics overlay, and pre- and post-processing. The functionality of AP Domain peripherals includes the user interface; the connectivity, display, security, and memory interfaces; and 128 Kbytes of multipurpose SRAM. 2.2 Shared Domain Overview The shared domain is composed of the shared peripherals, a smart DMA engine (SDMA) and a number of miscellaneous modules. For maximum flexibility, some peripherals are directly accessible by the SDMA engine. The i.MX35 has a hierarchical memory architecture including L1 caches and a unified L2 cache. This reduces the bandwidth demands for the external bus and external memory. The external memory subsystem supports a flexible external memory system, including support for SDRAM (SDR, DDR2 and mobile DDR) and NAND Flash. 2.3 Advanced Power Management Overview To address the continuing need to reduce power consumption, the following techniques are incorporated in the i.MX35: • Clock gating • Power gating • Power-optimized synthesis • Well biasing The insertion of gating into the clock paths allows unused portions of the chip to be disabled. Because static CMOS logic consumes only leakage power, significant power savings can be realized. “Well biasing” is applying a voltage that is greater than VDD to the nwells, and one that is lower than VSS to the pwells. The effect of applying this well back bias voltage reduces the subthreshold channel leakage. For the 90-nm digital process, it is estimated that the subthreshold leakage is reduced by a factor of ten over the nominal leakage. Additionally, the supply voltage for internal logic can be reduced from 1.4 V to 1.22 V. 2.4 ARM11 Microprocessor Core The CPU of the i.MX35 is the ARM1136JF-S core, based on the ARM v6 architecture. This core supports the ARM Thumb® instruction sets, features Jazelle® technology (which enables direct execution of Java byte codes) and a range of SIMD DSP instructions that operate on 16-bit or 8-bit data values in 32-bit registers. The ARM1136JF-S processor core features are as follows: • Integer unit with integral EmbeddedICE™ logic • Eight-stage pipeline i.MX35 Applications Processors for Automotive Products, Rev. 10 6 Freescale Semiconductor • • • • • • • • • • Branch prediction with return stack Low-interrupt latency Instruction and data memory management units (MMUs), managed using micro TLB structures backed by a unified main TLB Instruction and data L1 caches, including a non-blocking data cache with hit-under-miss Virtually indexed/physically addressed L1 caches 64-bit interface to both L1 caches Write buffer (bypassable) High-speed Advanced Micro Bus Architecture (AMBA)™ L2 interface Vector floating point co-processor (VFP) for 3D graphics and hardware acceleration of other floating-point applications ETM™ and JTAG-based debug support Table 3 summarizes information about the i.MX35 core. Table 3. i.MX35 Core Core Acronym ARM11 or ARM1136 2.5 Core Name ARM1136 Platform Brief Description Integrated Memory Features The ARM1136™ platform consists of the ARM1136JF-S core, the ETM real-time debug modules, a 6 × 5 multi-layer AHB crossbar switch (MAX), and a vector floating processor (VFP). The i.MX35 provides a high-performance ARM11 microprocessor core and highly integrated system functions. The ARM Application Processor (AP) and other subsystems address the needs of the personal, wireless, and portable product market with integrated peripherals, advanced processor core, and power management capabilities. • 16-Kbyte instruction cache • 16-Kbyte data cache • 128-Kbyte L2 cache • 32-Kbyte ROM • 128-Kbyte RAM Module Inventory Table 4 shows an alphabetical listing of the modules in the MCIMX35. For extended descriptions of the modules, see the MCIMX35 reference manual. Table 4. Digital and Analog Modules Block Mnemonic 1-WIRE ASRC Block Name Domain1 Subsystem Brief Description 1-Wire interface ARM ARM1136 platform peripherals 1-Wire provides the communication line to a 1-Kbit add-only memory. the interface can send or receive 1 bit at a time. Asynchronous sample rate converter SDMA Connectivity peripherals The ASRC is designed to convert the sampling rate of a signal associated to an input clock into a signal associated to a different output clock. It supports a concurrent sample rate conversion of about –120 dB THD+N. The sample rate conversion of each channel is associated to a pair of incoming and outgoing sampling rates. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 7 Table 4. Digital and Analog Modules (continued) Block Mnemonic Block Name Domain1 Subsystem Brief Description ATA ATA module SDMA Connectivity peripherals The ATA block is an AT attachment host interface. Its main use is to interface with IDE hard disk drives and ATAPI optical disk drives. It interfaces with the ATA device over a number of ATA signals. AUDMUX Digital audio mux ARM Multimedia peripherals The AUDMUX is a programmable interconnect for voice, audio, and synchronous data routing between host serial interfaces (SSIs) and peripheral serial interfaces (audio codecs). The AUDMUX has two sets of interfaces: internal ports to on-chip peripherals and external ports to off-chip audio devices. Data is routed by configuring the appropriate internal and external ports. CAN(2) CAN module ARM Connectivity peripherals The CAN protocol is primarily designed to be used as a vehicle serial data bus running at 1 Mbps. CCM Clock control module ARM Clocks This block generates all clocks for the peripherals in the SDMA platform. The CCM also manages ARM1136 platform low-power modes (WAIT, STOP), disabling peripheral clocks appropriately for power conservation, and provides alternate clock sources for the ARM1136 and SDMA platforms. CSPI(2) Configurable serial peripheral interface SDMA, ARM Connectivity peripherals This module is a serial interface equipped with data FIFOs; each master/slave-configurable SPI module is capable of interfacing to both serial port interface master and slave devices. The CSPI ready (SPI_RDY) and slave select (SS) control signals enable fast data communication with fewer software interrupts. ECT Embedded cross trigger SDMA, ARM Debug ECT (embedded cross trigger) is an IP for real-time debug purposes. It is a programmable matrix allowing several subsystems to interact with each other. ECT receives signals required for debugging purposes (from cores, peripherals, buses, external inputs, and so on) and propagates them (propagation programmed through software) to the different debug resources available within the SoC. EMI External memory interface SDMA External memory interface The EMI module provides access to external memory for the ARM and other masters. It is composed of the following main submodules: M3IF—provides arbitration between multiple masters requesting access to the external memory. SDRAM CTRL—interfaces to mDDR, DDR2 (4-bank architecture type), and SDR interfaces. NANDFC—provides an interface to NAND Flash memories. WEIM—interfaces to NOR Flash and PSRAM. Enhanced periodic interrupt timer ARM Timer peripherals Each EPIT is a 32-bit “set-and-forget” timer that starts counting after the EPIT is enabled by software. It is capable of providing precise interrupts at regular intervals with minimal processor intervention. It has a 12-bit prescaler to adjust the input clock frequency to the required time setting for the interrupts, and the counter value can be programmed on the fly. EPIT(2) i.MX35 Applications Processors for Automotive Products, Rev. 10 8 Freescale Semiconductor Table 4. Digital and Analog Modules (continued) Block Mnemonic ESAI eSDHCv2 (3) FEC GPIO(3) Block Name Domain1 Subsystem Brief Description Enhanced serial audio interface SDMA Connectivity peripherals The enhanced serial audio interface (ESAI) provides a full-duplex serial port for serial communication with a variety of serial devices, including industry-standard codecs, SPDIF transceivers, and other DSPs. The ESAI consists of independent transmitter and receiver sections, each section with its own clock generator. Enhanced secure digital host controller ARM Connectivity peripherals The eSDHCv2 consists of four main modules: CE-ATA, MMC, SD and SDIO. CE-ATA is a hard drive interface that is optimized for embedded applications of storage. The MultiMediaCard (MMC) is a universal, low-cost, data storage and communication media to applications such as electronic toys, organizers, PDAs, and smart phones. The secure digital (SD) card is an evolution of MMC and is specifically designed to meet the security, capacity, performance, and environment requirements inherent in emerging audio and video consumer electronic devices. SD cards are categorized into Memory and I/O. A memory card enables a copyright protection mechanism that complies with the SDMI security standard. SDIO cards provide high-speed data I/O (such as wireless LAN via SDIO interface) with low power consumption. Note: CE-ATA is not available for the MCIMX351. Ethernet SDMA Connectivity peripherals The Ethernet media access controller (MAC) is designed to support both 10 and 100 Mbps Ethernet/IEEE 802.3 networks. An external transceiver interface and transceiver function are required to complete the interface to the media General purpose I/O modules ARM Pins Used for general purpose input/output to external ICs. Each GPIO module supports 32 bits of I/O. GPT General ARM purpose timers Timer peripherals Each GPT is a 32-bit free-running or set-and-forget mode timer with a programmable prescaler and compare and capture registers. A timer counter value can be captured using an external event and can be configured to trigger a capture event on either the leading or trailing edges of an input pulse. When the timer is configured to operate in set-and-forget mode, it is capable of providing precise interrupts at regular intervals with minimal processor intervention. The counter has output compare logic to provide the status and interrupt at comparison. This timer can be configured to run either on an external clock or on an internal clock. GPU2D Graphics ARM processing unit 2Dv1 Multimedia peripherals This module accelerates OpenVG and GDI graphics. Note: Not available for the MCIMX351. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 9 Table 4. Digital and Analog Modules (continued) Block Mnemonic Block Name Domain1 Subsystem Brief Description I2C(3) I2C module ARM ARM1136 platform peripherals Inter-integrated circuit (I2C) is an industry-standard, bidirectional serial bus that provides a simple, efficient method of data exchange, minimizing the interconnection between devices. I2C is suitable for applications requiring occasional communications over a short distance among many devices. The interface operates at up to 100 kbps with maximum bus loading and timing. The I2C system is a true multiple-master bus, with arbitration and collision detection that prevent data corruption if multiple devices attempt to control the bus simultaneously. This feature supports complex applications with multiprocessor control and can be used for rapid testing and alignment of end products through external connections to an assembly-line computer. IIM IC identification module ARM Security modules The IIM provides the primary user-visible mechanism for interfacing with on-chip fuse elements. Among the uses for the fuses are unique chip identifiers, mask revision numbers, cryptographic keys, and various control signals requiring a fixed value. IOMUX External ARM signals and pin multiplexing Pins Each I/O multiplexer provides a flexible, scalable multiplexing solution with the following features: • Up to eight output sources multiplexed per pin • Up to four destinations for each input pin • Unselected input paths held at constant levels for reduced power consumption IPUv1 Image ARM processing unit Multimedia peripherals The IPU supports video and graphics processing functions. It also provides the interface for image sensors and displays. The IPU performs the following main functions: • Preprocessing of data from the sensor or from the external system memory • Postprocessing of data from the external system memory • Post-filtering of data from the system memory with support of the MPEG-4 (both deblocking and deringing) and H.264 post-filtering algorithms • Displaying video and graphics on a synchronous (dumb or memory-less) display • Displaying video and graphics on an asynchronous (smart) display • Transferring data between IPU sub-modules and to/from the system memory with flexible pixel reformatting KPP Keypin port ARM Connectivity peripherals Can be used for either keypin matrix scanning or general purpose I/O. MLB Media local bus ARM Connectivity peripherals The MLB is designed to interface to an automotive MOST ring. OSCAUD OSC audio reference oscillator Analog Clock The OSCAUDIO oscillator provides a stable frequency reference for the PLLs. This oscillator is designed to work in conjunction with an external 24.576-MHz crystal. i.MX35 Applications Processors for Automotive Products, Rev. 10 10 Freescale Semiconductor Table 4. Digital and Analog Modules (continued) Block Mnemonic Block Name Domain1 Subsystem Brief Description OSC24M 24-MHz reference oscillator Analog Clock The signal from the external 24-MHz crystal is the source of the CLK24M signal fed into USB PHY as the reference clock and to the real time clock (RTC). MPLL PPLL Digital phase-locked loops SDMA Clocks DPLLs are used to generate the clocks: MCU PLL (MPLL)—programmable Peripheral PLL (PPLL)—programmable PWM Pulse-width modulator ARM ARM1136 platform peripherals The pulse-width modulator (PWM) is optimized to generate sound from stored sample audio images; it can also generate tones. RTC Real-time clock ARM Clocks Provides the ARM1136 platform with a clock function (days, hours, minutes, seconds) and includes alarm, sampling timer, and minute stopwatch capabilities. Smart DMA engine SDMA System controls The SDMA provides DMA capabilities inside the processor. It is a shared module that implements 32 DMA channels and has an interface to connect to the ARM1136 platform subsystem, EMI interface, and the peripherals. SJC Secure JTAG controller ARM Pins The secure JTAG controller (SJC) provides debug and test control with maximum security. SPBA SDMA peripheral bus arbiter SDMA System controls The SPBA controls access to the SDMA peripherals. It supports shared peripheral ownership and access rights to an owned peripheral. S/PDIF Serial audio interface SDMA Connectivity peripherals Sony/Philips digital transceiver interface SSI(2) Synchronous SDMA, serial interface ARM(2) Connectivity peripherals The SSI is a full-duplex serial port that allows the processor connected to it to communicate with a variety of serial protocols, including the Freescale Semiconductor SPI standard and the I2C sound (I2S) bus standard. The SSIs interface to the AUDMUX for flexible audio routing. OSC24M SDMA UART(3) Universal asynchronous receiver/trans mitters ARM Connectivity (UART1,2) peripherals SDMA (UART3) Each UART provides serial communication capability with external devices through an RS-232 cable using the standard RS-232 non-return-to-zero (NRZ) encoding format. Each module transmits and receives characters containing either 7 or 8 bits (program-selectable). Each UART can also provide low-speed IrDA compatibility through the use of external circuitry that converts infrared signals to electrical signals (for reception) or transforms electrical signals to signals that drive an infrared LED (for transmission). i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 11 Table 4. Digital and Analog Modules (continued) Block Mnemonic 1 Block Name Domain1 Subsystem Brief Description USBOH High-speed SDMA USB on-the-go Connectivity peripherals The USB module provides high performance USB on-the-go (OTG) functionality (up to 480 Mbps), compliant with the USB 2.0 specification, the OTG supplement, and the ULPI 1.0 low pin count specification. The module has DMA capabilities handling data transfer between internal buffers and system memory. WDOG Watchdog modules Timer peripherals Each module protects against system failures by providing a method of escaping from unexpected events or programming errors. Once activated, the timer must be serviced by software on a periodic basis. If servicing does not take place, the watchdog times out and then either asserts a system reset signal or an interrupt request signal, depending on the software configuration. ARM ARM = ARM1136 platform, SDMA = SDMA platform 3 Signal Descriptions: Special Function Related Pins Some special functional requirements are supported in the device. The details about these special functions and the corresponding pin names are listed in Table 5. Table 5. Special Function Related Pins Function Name Pin Name Mux Mode EXT_ARMCLK ALT0 External clock input for ARM clock. External Peripheral Clock I2C1_CLK ALT6 External peripheral clock source. External 32-kHz Clock CAPTURE ALT4 CSPI1_SS1 ALT2 External clock input of 32 kHz, used when the internal 24M Oscillator is powered off, which could be configured either from CAPTURE or CSPI1_SS1. CLKO ALT0 Clock-out pin from CCM, clock source is controllable and can also be used for debug. GPIO1_0 ALT1 TX1 ALT1 PMIC power-ready signal, which can be configured either from GPIO1_0 or TX1. GPIO1_1 ALT6 External ARM Clock Clock Out Power Ready Tamper Detect Detailed Description Tamper-detect logic is used to issue a security violation. This logic is activated if the tamper-detect input is asserted. Tamper-detect logic is enabled by the bit of IOMUXC_GPRA[2]. After enabling the logic, it is impossible to disable it until the next reset. i.MX35 Applications Processors for Automotive Products, Rev. 10 12 Freescale Semiconductor 4 Electrical Characteristics The following sections provide the device-level and module-level electrical characteristics for the i.MX35 processor. 4.1 i.MX35 Chip-Level Conditions This section provides the device-level electrical characteristics for the IC. See Table 6 for a quick reference to the individual tables and sections. Table 6. i.MX35 Chip-Level Conditions Characteristics Table/Location Absolute Maximum Ratings Table 7 on page 13 i.MX35 Operating Ranges Table 8 on page 14 Interface Frequency Table 9 on page 15 CAUTION Stresses beyond those listed in Table 7 may cause permanent damage to the device. These are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated in Table 8 is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. Table 7. Absolute Maximum Ratings Parameter Symbol Min. Max. Units Supply voltage (core) VDDmax1 –0.5 1.47 V Supply voltage (I/O) NVCCmax –0.5 3.6 V Input voltage range VImax –0.5 3.6 V Tstorage –40 125 oC Human Body Model (HBM) — 20002 Charge Device Model (CDM) — 5003 Storage temperature ESD damage immunity: V Vesd 1 VDD is also known as QVCC. HBM ESD classification level according to the AEC-Q100-002 standard 3 Corner pins max. 750 V 2 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 13 4.1.1 i.MX35 Operating Ranges Table 8 provides the recommended operating ranges. The term NVCC in this section refers to the associated supply rail of an input or output. Table 8. i.MX35 Operating Ranges Parameter Min. Typical Max. Units 1.22 — 1.47 V Core Operating Voltage 0 < fARM < 532 MHz 1.33 — 1.47 V State Retention Voltage 1 — — V Core Operating Voltage 0 < fARM < 400 MHz Symbol VDD EMI1 NVCC_EMI1,2,3 1.7 — 3.6 V WTDG, Timer, CCM, CSPI1 NVCC_CRM 1.75 — 3.6 V NANDF NVCC_NANDF 1.75 — 3.6 V ATA, USB generic NVCC_ATA 1.75 — 3.6 V eSDHC1 NVCC_SDIO 1.75 — 3.6 V CSI, SDIO2 NVCC_CSI 1.75 — 3.6 V JTAG NVCC_JTAG 1.75 — 3.6 V LCDC, TTM, I2C1 NVCC_LCDC 1.75 — 3.6 V I2Sx2,ESAI, I2C2, UART2, UART1, FEC NVCC_MISC 1.75 — 3.6 V MLB NVCC_MLB 2 1.75 — 3.6 V USB OTG PHY PHY1_VDDA 3.17 3.3 3.43 V USB OTG PHY USBPHY1_VDDA_BIAS 3.17 3.3 3.43 V USB OTG PHY USBPHY1_UPLLVDD 3.17 3.3 3.43 V USB HOST PHY PHY2_VDD 3.0 3.3 3.6 V OSC24M OSC24M_VDD 3.0 3.3 3.6 V OSC_AUDIO OSC_AUDIO_VDD 3.0 3.3 3.6 V MPLL MVDD 1.4 — 1.65 V PPLL PVDD 1.4 — 1.65 V 3.0 3.6 3.6 V 3 Fusebox program supply voltage FUSE_VDD Operating ambient temperature range TA –40 — 85 oC Junction temperature range TJ –40 — 105 oC 1 EMI I/O interface power supply should be set up according to external memory. For example, if using SDRAM then NVCC_EMI1,2,3 should all be set at 3.3 V (typ.). If using MDDR or DDR2, NVC_EMI1,2,3 must be set at 1.8 V (typ.). 2 MLB interface I/O pads can be programmed to function as GPIO by setting NVCC_MLB to 1.8 or 3.3 V, but if used as MLB pads, NVCC_MLB must be set to 2.5 V in order to be compliant with external MOST devices. NVCC_MLB may be left floating. 3 The Fusebox read supply is connected to supply of the full speed USB PHY. FUSE_VDD is only used for programming. It is recommended that FUSE_VDD be connected to ground when not being used for programming. FUSE_VDD should be supplied by following the power up sequence given in Section 4.3.1, “Powering Up.” i.MX35 Applications Processors for Automotive Products, Rev. 10 14 Freescale Semiconductor 4.1.2 Interface Frequency Limits Table 9 provides information on interface frequency limits. Table 9. Interface Frequency ID 1 4.2 Parameter Symbol Min. Typ. Max. Units fJTAG DC 5 10 MHz JTAG TCK Frequency Power Modes Table 10 provides descriptions of the power modes of the i.MX35 processor. Table 10. i.MX35 Power Modes Power Mode Wait Doze Description QVCC (ARM/L2 Peripheral) MVDD/PVDD OSC24M_VDD OSC_AUDO_VDD Typ. Max. Typ. Max. Typ. Max. VDD1,2,3,4 = 1.1 V (min.) ARM is in wait for interrupt mode. MAX is active. L2 cache is kept powered. MCU PLL is on (400 MHz) PER PLL is off (can be configured) (default: 300 MHz) Module clocks are gated off (can be configured by CGR register). OSC 24M is ON. OSC audio is off (can be configured). RNGC internal osc is off. 16 mA 170 mA 7.2 mA 14 mA 1.2 mA 3 mA VDD1,2,3,4 = 1.1 V (min.) ARM is in wait for interrupt mode. MAX is halted. L2 cache is kept powered. L2 cache control logic off. AWB enabled. MCU PLL is on(400 MHz) PER PLL is off (can be configured). (300 Mhz). Module clocks are gated off (can be configured by CGR register). OSC 24M is ON. OSC audio is off (can be configured) RNGC internal osc is off 12.4 mA 105 mA 7.2 mA 14 mA 1.2 mA 3 mA i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 15 Table 10. i.MX35 Power Modes (continued) Power Mode Stop Static Description QVCC (ARM/L2 Peripheral) MVDD/PVDD OSC24M_VDD OSC_AUDO_VDD Typ. Max. Typ. Max. Typ. Max. VDD1,2,3,4 = 1.1 V (min.) ARM is in wait for interrupt mode. MAX is halted L2 cache is kept powered. L2 cache control logic off. AWB enabled. MCU PLL is off. PER PLL is off. All clocks are gated off. OSC 24 MHz is on OSC audio is off RNGC internal osc is off 1.1 mA 77 mA 400 µA 2.2 mA 1.2 mA 2.2 mA VDD1,2,3,4 = 1.1 V (min.) ARM is in wait for interrupt mode. MAX is halted L2 cache is kept powered. L2 cache control logic off. AWB enabled. MCU PLL is off. PER PLL is off. All clocks are gated off. OSC 24MHz is on OSC audio is off RNGC internal osc is off 820 µA 72 mA 50 µA 1.7 mA 24 µA 35 µA Note: Typical column: TA = 25 °C Note: Maximum column: TA = 85 °C 4.3 Supply Power-Up/Power-Down Requirements and Restrictions This section provides power-up and power-down sequence guidelines for the i.MX35 processor. CAUTION Any i.MX35 board design must comply with the power-up and power-down sequence guidelines as described in this section to guarantee reliable operation of the device. Any deviation from these sequences can result in irreversible damage to the i.MX35 processor (worst-case scenario). i.MX35 Applications Processors for Automotive Products, Rev. 10 16 Freescale Semiconductor NOTE Deviation from these sequences may also result in one or more of the following: • • • 4.3.1 Excessive current during power-up phase Prevent the device from booting Programming of unprogrammed fuses Powering Up The power-up sequence should be completed as follows: 1. Assert Power on Reset (POR). 2. Turn on digital logic domain and IO power supply: VDDn, NVCCx 3. Wait until VDDn and NVCCx power supplies are stable + 32 μs. 4. Turn on all other power supplies: PHY1_VDDA, USBPHY1_VDDA_BIAS, PHY2_VDD, USBPHY1_UPLLVDD, OSC24M_VDD, OSC_AUDIO_VDD, MVDD, PVDD, FUSEVDD. (Always FUSE_VDD should be connected to ground, except when eFuses are to be programmed.) 5. Wait until PHY1_VDDA, USBPHY1_VDDA_BIAS, PHY2_VDD, USBPHY1_UPLLVDD, OSC24M_VDD, OSC_AUDIO_VDD, MVDD, PVDD, (FUSEVDD, optional). Power supplies are stable + 100 μs. 6. Deassert the POR signal. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 17 Figure 2 shows the power-up sequence and timing. Figure 2. i.MX35 Power-Up Sequence and Timing 4.3.2 Powering Down The power-up sequence in reverse order is recommended for powering down. However, all power supplies can be shut down at the same time. 4.4 Reset Timing There are two ways of resetting the i.MX35 using external pins: • Power On Reset (using the POR_B pin) • System Reset (using the RESET_IN_B pin) 4.4.1 Power On Reset POR_B is normally connected to a power management integrated circuit (PMIC). The PMIC asserts POR_B while the power supplies are turned on and negates POR_B after the power up sequence is finished. See Figure 2. i.MX35 Applications Processors for Automotive Products, Rev. 10 18 Freescale Semiconductor Assuming the i.MX35 chip is already fully powered; it is still possible to reset all of the modules to their default reset by asserting POR_B for at least 4 CKIL cycles and later de-asserting POR_B. This method of resetting the i.MX35 can also be supported by tying the POR_B and RESET_IN_B pins together. POR_B At least 4 CKIL cycles CKIL Figure 3. Timing Between POR_B and CKIL for Complete Reset of i.MX35 4.4.2 System Reset System reset can be achieved by asserting RESET_IN_B for at least 4 CKIL cycles and later negating RESET_IN_B. The following modules are not reset upon system reset: RTC, PLLs, CCM, and IIM. POR_B pin must be deasserted all the time. RESET_IN_B At least 4 CKIL cycles CKIL Figure 4. Timing Between RESET_IN_B and CKIL for i.MX35 System Reboot 4.5 Power Characteristics The table shows values representing maximum current numbers for the i.MX35 under worst case voltage and temperature conditions. These values are derived from the i.MX35 with core clock speeds up to 532 MHz. Common supplies have been bundled according to the i.MX35 power-up sequence requirements. Peak numbers are provided for system designers so that the i.MX35 power supply requirements will be satisfied during startup and transient conditions. Freescale recommends that system current measurements be taken with customer-specific use-cases to reflect normal operating conditions in the end system. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 19 Table 11. Power Consumption Power Supply Voltage (V) Max Current (mA) QVCC 1.47 400 MVDD, PVDD 1.65 20 NVCC_EMI1, NVCC_EMI2, NVCC_EMI3, NVCC_LCDC, NVCC_NFC 1.9 90 FUSE_VDD1 3.6 62 NVCC_MISC, NVCC_CSI, NVCC_SDIO, NVCC_CRM, NVCC_ATA, NVCC_MLB, NVCC_JTAG 3.6 60 OSC24M_VDD, OSC_AUDIO_VDD, PHY1_VDDA, PHY2_VDD, USBPHY1_UPLLVDD, USBPHY1_VDDA_BIAS 3.6 25 1 This rail is connected to ground; it only needs a voltage if eFuses are to be programmed. FUSE_VDD should be supplied by following the power up sequence given in Section 4.3.1, “Powering Up.” The method for obtaining max current is as follows: 1. Measure worst case power consumption on individual rails using directed test on i.MX35. 2. Correlate worst case power consumption power measurements with worst case power consumption simulations. 3. Combine common voltage rails based on power supply sequencing requirements 4. Guard band worst case numbers for temperature and process variation. Guard band is based on process data and correlated with actual data measured on i.MX35. 5. The sum of individual rails is greater than real world power consumption, as a real system does not typically maximize power consumption on all peripherals simultaneously. 4.6 Thermal Characteristics The thermal resistance characteristics for the device are given in Table 12. These values were measured under the following conditions: • Two-layer substrate • Substrate solder mask thickness: 0.025 mm • Substrate metal thicknesses: 0.016 mm • Substrate core thickness: 0.200 mm • Core via I.D: 0.168 mm, Core via plating 0.016 mm. • Full array map design, but nearly all balls under die are power or ground. • Die Attach: 0.033 mm non-conductive die attach, k = 0.3 W/m K • Mold compound: k = 0.9 W/m K Table 12. Thermal Resistance Data Rating Condition Symbol Value Unit Junction to ambient1 natural convection Single layer board (1s) ReJA 53 ºC/W 1 Four layer board (2s2p) ReJA 30 ºC/W Junction to ambient natural convection i.MX35 Applications Processors for Automotive Products, Rev. 10 20 Freescale Semiconductor Table 12. Thermal Resistance Data (continued) Rating Condition Symbol Value Unit Junction to ambient1 (at 200 ft/min) Single layer board (1s) ReJMA 44 ºC/W Junction to ambient1 (at 200 ft/min) Four layer board (2s2p) ReJMA 27 ºC/W — ReJB 19 ºC/W — ReJCtop 10 ºC/W Natural convection ΨJT 2 ºC/W Junction to boards 2 Junction to case (top)3 Junction to package top4 1 Junction-to-ambient thermal resistance determined per JEDC JESD51-3 and JESD51-6. Thermal test board meets JEDEC specification for this package. 2 Junction-to-board thermal resistance determined per JEDC JESD51-8. Thermal test board meets JEDEC specification for this package. 3 Junction-to-case at the top of the package determined using MIL-STD 883 Method 1012.1. The cold plate temperature is used for the case temperature. Reported value includes the thermal resistance of the interface layer. 4 Thermal characterization parameter indicating the temperature difference between the package top and the junction temperature per JEDEC JESD51-2. When Greek letters are not available, this thermal characterization parameter is written as Psi-JT. 4.7 I/O Pin DC Electrical Characteristics I/O pins are of two types: GPIO and DDR. DDR pins can be configured in three different drive strength modes: mobile DDR, SDRAM, and DDR2. The SDRAM and mobile DDR modes can be further customized at three drive strength levels: normal, high, and max. Table 13 shows currents for the different DDR pin drive strength modes. Table 13. DDR Pin Drive Strength Mode Current Levels Drive Mode Normal High Max. 3.6 mA 7.2 mA 10.8 mA SDRAM (1.8 V) — — 6.5 mA SDRAM (3.3 V) 4 mA 8 mA 12 mA — — 13.4 mA Mobile DDR (1.8 V) DDR2 (1.8 V) i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 21 Table 14 shows the DC electrical characteristics for GPIO, DDR2, mobile DDR, and SDRAM pins. The term NVCC refers to the power supply voltage that feeds the I/O of the module in question. For example, NVCC for the SD/MMC interface refers to NVCC_SDIO. Table 14. I/O Pin DC Electrical Characteristics Pin GPIO DC Electrical Characteristics Symbol Test Condition Min. Typ. Max. Unit High-level output voltage Voh Ioh = –1 mA Ioh = specified drive NVCC – 0.15 0.8 × NVCC — — V Low-level output voltage Vol Iol = 1 mA Iol = specified drive — — 0.15 0.2 × NVCC V High-level output current for slow mode (Voh = 0.8 × NVCC) Ioh Standard drive High drive Max. drive –2.0 –4.0 –8.0 — — mA High-level output current for fast mode (Voh = 0.8 × NVCC) Ioh Standard drive High drive Max. drive –4.0 –6.0 –8.0 — — mA Low-level output current for slow mode (Voh = 0.2 × NVCC) Iol Standard drive High drive Max. drive 2.0 4.0 8.0 — — mA Low-level output current for fast mode (Voh = 0.2 × NVCC) Iol Standard drive High drive Max. drive 4.0 6.0 8.0 — — mA High-level DC Input Voltage with 1.8 V, 3.3 V NVCC (for digital cells in input mode) VIH — 0.7 × NVCC — NVCC V Low-level DC Input Voltage with 1.8 V, 3.3 V NVCC (for digital cells in input mode VIL — –0.3 V — 0.3 × NVCC V VHYS OVDD = 3.3 V OVDD = 1.8 V — 410 330 — mV Schmitt trigger VT+ VT+ — 0.5 × NVCC — Schmitt trigger VT– VT– — — — 0.5 × NVCC V Pull-up resistor (22 kΩ PU) Rpu Vi = 0 — 22 — kΩ Pull-up resistor (47 kΩ PU) Rpu Vi = 0 — 47 — kΩ Pull-up resistor (100 kΩ PU) Rpu Vi = 0 — 100 — kΩ Pull-down resistor (100 kΩ PD) Rpd Vi = NVCC — 100 — kΩ External resistance to pull keeper up when enabled Rkpu Ipu > 620 μA @ min Vddio = 3.0 V — — 4.8 kΩ External resistance to pull keeper down when enabled Rkpd Ipu > 510 μA @min Vddio = 3.0 V — — 5.9 kΩ Input Hysteresis V i.MX35 Applications Processors for Automotive Products, Rev. 10 22 Freescale Semiconductor Table 14. I/O Pin DC Electrical Characteristics (continued) Pin DDR2 DC Electrical Characteristics Symbol Min. Typ. Max. Unit NVCC – 0.28 — — V — 0.28 V High-level output voltage Voh — Low-level output voltage Vol — Output min. source current Ioh — –13.4 — — mA Output min. sink current Iol — 13.4 — — mA DC input logic high VIH(dc) — NVCC ÷ 2 + 0.125 — NVCC + 0.3 V DC input logic low VIL(dc) — –0.3 V — NVCC ÷ 2 – 0.125 V DC input signal voltage (for differential signal) Vin(dc) — –0.3 — NVCC + 0.3 V DC differential input voltage Vid(dc) — 0.25 — NVCC + 0.6 V Termination voltage Vtt — NVCC ÷ 2 – 0.04 NV CC ÷2 NVCC ÷ 2 + 0.04 V Input current (no pull-up/down) IIN — — — ±1 μA Icc – N VCC — — — ±1 μA High-level output voltage — IOH = –1mA IOH = specified drive NVCC – 0.08 0.8 × NVCC — — V Low-level output voltage — IOL = 1mA IOL = specified drive — — 0.08 0.2 × NVCC V High-level output current (Voh = 0.8 × NVCCV) — Standard drive High drive Max. drive –3.6 –7.2 –10.8 — — mA Low-level output current (Vol = 0.2 × NVCCV) — Standard Drive High Drive Max. Drive 3.6 7.2 10.8 — — mA High-Level DC CMOS input voltage VIH — 0.7 × NVCC — NVCC + 0.3 V Low-Level DC CMOS input voltage VIL — –0.3 — 0.2 × NVCC V Differential receiver VTH+ VTH+ — — — 100 mV Differential receiver VTH– VTH– — –100 — IIN VI = 0 VI = NVCC — — ±1 μA Icc – N VCC VI = NVCC or 0 — — ±1 μA Tri-state I/O supply current Mobile DDR Test Condition Input current (no pull-up/down) Tri-state I/O supply current mV i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 23 Table 14. I/O Pin DC Electrical Characteristics (continued) Pin DC Electrical Characteristics Symbol Test Condition Min. Typ. Max. Unit SDR High-level output voltage (1.8 V) Low-level output voltage Voh loh = 5.7 mA OVDD – 0.28 — — V Vol loh = 5.7 mA — — 0.4 V High-level output current Ioh Max. drive 5.7 — — mA Low-level output current Iol Max. drive 7.3 — — mA High-level DC Input Voltage VIH — 1.4 — 1.98 V Low-level DC Input Voltage VIL — –0.3 — 0.8 V Input current (no pull-up/down) IIN VI = 0 VI=NVCC — — 150 80 μA Tri-state I/O supply current Icc (NVCC) VI = OVDD or 0 — — 1180 μA Tri-state core supply current Icc (NVCC) VI = VDD or 0 — — 1220 μA SDR High-level output voltage (3.3 V) Voh Ioh=specified drive (Ioh = –4, –8, –12, –16 mA) 2.4 — — V Low-level output voltage Vol Ioh=specified drive (Ioh = 4, 8, 12, 16 mA) — — 0.4 V High-level output current Ioh Standard drive High drive Max. drive –4.0 –8.0 –12.0 — — mA Low-level output current Iol Standard drive High drive Max. drive 4.0 8.0 12.0 — — mA High-level DC Input Voltage VIH — 2.0 — 3.6 V Low-level DC Input Voltage VIL — –0.3V — 0.8 V Input current (no pull-up/down) IIN VI = 0 — — ±1 μA — — ±1 μA VI = NVCC Tri-state I/O supply current 4.8 Icc (NVCC) VI = NVCC or 0 I/O Pin AC Electrical Characteristics Figure 5 shows the load circuit for output pins. From Output Under Test Test Point CL CL includes package, probe and jig capacitance Figure 5. Load Circuit for Output Pin i.MX35 Applications Processors for Automotive Products, Rev. 10 24 Freescale Semiconductor Figure 6 shows the output pin transition time waveform. NVCC 80% 80% 20% 0V 20% Output (at pin) PA1 PA1 Figure 6. Output Pin Transition Time Waveform 4.8.1 AC Electrical Test Parameter Definitions AC electrical characteristics in Table 16 through Table 21 are not applicable for the output open drain pull-down driver. The dI/dt parameters are measured with the following methodology: • The zero voltage source is connected between pin and load capacitance. • The current (through this source) derivative is calculated during output transitions. Table 15. AC Requirements of I/O Pins Parameter Symbol Min. Max. Units AC input logic high VIH(ac) NVCC ÷ 2 + 0.25 NVCC + 0.3 V AC input logic low VIL(ac) –0.3 NVCC ÷ 2 – 0.25 V Table 16. AC Electrical Characteristics of GPIO Pins in Slow Slew Rate Mode [NVCC = 3.0 V–3.6 V] Symbol Test Condition Min. Rise/Fall Typ. Rise/Fall Max. Rise/Fall Units Fduty — 40 — 60 % Output pin slew rate (max. drive) tps 25 pF 50 pF 0.79/1.12 0.49/0.73 1.30/1.77 0.84/1.23 2.02/2.58 1.19/1.58 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.48/0.72 0.27/0.42 0.76/1.10 0.41/0.62 1.17/1.56 0.63/0.86 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.25/0.40 0.14/0.21 0.40/0.59 0.21/0.32 0.60/0.83 0.32/0.44 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 15 16 36 38 76 80 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 8 9 20 21 45 47 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 4 4 10 10 22 23 mA/ns Parameter Duty cycle i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 25 Table 17. AC Electrical Characteristics of GPIO Pins in Slow Slew Rate Mode [NVCC = 1.65 V–1.95 V] Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units Fduty — 40 — 60 % Output pin slew rate (max. drive) tps 25 pF 50 pF 0.30/0.42 0.20/0.29 0.54/0.73 0.35/0.50 0.91/1.20 0.60/0.80 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.19/0.28 0.12/0.18 0.34/0.49 0.34/0.49 0.58/0/79 0.36/0.49 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.12/0.18 0.07/0.11 0.20/0.30 0.11/0.17 0.34/0.47 0.20/0.27 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 7 7 21 22 56 58 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 5 5 14 15 38 40 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 2 2 7 7 18 19 mA/ns Parameter Duty cycle Table 18. AC Electrical Characteristics of GPIO Pins in Fast Slew Rate Mode for [NVCC = 3.0 V–3.6 V] Symbol Test Condition Min. rise/fall Typ. Max. Rise/Fall Units Fduty — 40 — 60 % Output pin slew rate (max. drive) tps 25 pF 50 pF 0.96/1.40 0.54/0.83 1.54/2.10 0.85/1.24 2.30/3.00 1.26/1.70 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.76/1.10 0.41/0.64 1.19/1.71 0.63/0.95 1.78/2.39 0.95/1.30 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.52/0.78 0.28/0.44 0.80/1.19 0.43/0.64 1.20/1.60 0.63/0.87 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 46 49 108 113 250 262 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 35 37 82 86 197 207 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 22 23 52 55 116 121 mA/ns Parameter Duty cycle i.MX35 Applications Processors for Automotive Products, Rev. 10 26 Freescale Semiconductor Table 19. AC Electrical Characteristics, GPIO Pins in Fast Slew Rate Mode [NVCC = 1.65 V–1.95 V] Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units Fduty — 40 — 60 % Output pin slew rate (max. drive) tps 25 pF 50 pF 0.40/0.57 0.25/0.36 0.72/0.97 0.43/0.61 1.2/1.5 0.72/0.95 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.38/0.48 0.20/0.30 0.59/0.81 0.34/0.50 0.98/1.27 0.56/0.72 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.23/0.32 0.13/0.20 0.40/0.55 0.23/0.34 0.66/0.87 0.38/0.52 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 7 7 43 46 112 118 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 11 12 31 33 81 85 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 9 10 27 28 71 74 mA/ns Parameter Duty cycle Table 20. AC Electrical Characteristics of GPIO Pins in Slow Slew Rate Mode [NVCC = 2.25 V–2.75 V] Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units Fduty — 40 — 60 % Output pin slew rate (max. drive) tps 25 pF 40 pF 50 pF 0.63/0.85 0.52/0.67 0.41/0.59 1.10/1.40 0.90/1.10 0.73/0.99 1.86/2.20 1.53/1.73 1.20/1.50 V/ns Output pin slew rate (high drive) tps 25 pF 40 pF 50 pF 0.40/0.58 0.33/0.43 0.25/0.37 0.71/0.98 0.56/0.70 0.43/0.60 1.16/1.40 0.93/1.07 0.68/0.90 V/ns Output pin slew rate (standard drive) tps 25 pF 40 pF 50 pF 0.24/0.36 0.19/0.25 0.13/0.21 0.41/0.59 0.32/0.35 0.23/0.33 0.66/0.87 0.51/0.59 0.36/0.48 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 22 23 62 65 148 151 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 15 16 42 44 102 107 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 7 8 21 22 52 54 mA/ns Parameter Duty cycle i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 27 Table 21. AC Electrical Characteristics of GPIO Pins in Fast Slew Rate Mode [NVCC = 2.25 V–2.75 V] Parameter Symbol Duty cycle Test Min. Condition Rise/Fall Fduty — Output pin slew rate (max. drive) tps 25 pF 40 pF 50 pF Output pin slew rate (high drive) tps Output pin slew rate (standard drive) Max. Units Notes Rise/Fall Typ. % — 0.84/1.10 1.45/1.80 2.40/2.80 0.68/0.83 1.14/1.34 1.88/2.06 0.58/0.72 0.86/1.10 1.40/1.70 V/ns 2 25 pF 40 pF 50 pF 0.69/0.96 1.18/1.50 1.90/2.30 0.55/0.69 0.92/1.10 1.49/1.67 0.40/0.59 0.67/0.95 1.10/1.30 V/ns tps 25 pF 40 pF 50 pF 0.24/0.36 0.80/1.00 1.30/1.60 0.37/0.47 0.62/0.76 1.00/1.14 0.13/0.21 0.45/0.65 0.70/0.95 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 46 49 124 131 310 324 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 33 35 89 94 290 304 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 28 29 75 79 188 198 mA/ns 4.8.2 40 — 60 3 AC Electrical Characteristics for DDR Pins (DDR2, Mobile DDR, and SDRAM Modes) Table 22. AC Electrical Characteristics of DDR Type IO Pins in DDR2 Mode Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units Fduty — 45 50 55 % f — — 133 — MHz Output pin slew rate tps 25 pF 50 pF 0.86/0.98 0.46/054 1.35/1.5 0.72/0.81 2.15/2.19 1.12/1.16 V/ns Output pin di/dt tdit 25 pF 50 pF 65 70 157 167 373 396 mA/ns Parameter Duty cycle Clock frequency Table 23. AC Requirements of DDR2 Pins Parameter1 Symbol Min. Max. AC input logic high VIH(ac) NVCC ÷ 2 + 0.25 NVCC + 0.3 V AC input logic low VIL(ac) –0.3 NVCC ÷ 2 – 0.25 V AC differential cross point voltage for output2 Vox(ac) NVCC ÷ 2 – 0.125 NVCC ÷ 2 + 0.125 V 1 Units The Jedec SSTL_18 specification (JESD8-15a) for an SSTL interface for class II operation supersedes any specification in this document. i.MX35 Applications Processors for Automotive Products, Rev. 10 28 Freescale Semiconductor 2 The typical value of Vox(ac) is expected to be about 0.5 × NVCC and Vox(ac) is expected to track variation in NVCC. Vox(ac) indicates the voltage at which the differential output signal must cross. Cload = 25 pF. Table 24. AC Electrical Characteristics of DDR Type IO Pins in mDDR Mode Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units Fduty — 45 50 55 % f — — 133 — MHz Output pin slew rate (max. drive) tps 25 pF 50 pF 0.80/0.92 0.43/0.50 1.35/1.50 0.72/0.81 2.23/2.27 1.66/1.68 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.37/0.43 0.19/0.23 0.62/0.70 0.33/0.37 1.03/1.05 0.75/0.77 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.18/0.22 0.10/0.12 0.31/0.35 0.16/0.18 0.51/0.53 0.38/0.39 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 64 69 171 183 407 432 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 37 39 100 106 232 246 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 18 20 50 52 116 123 mA/ns Parameter Duty cycle Clock frequency Table 25. AC Electrical Characteristics of DDR Type IO Pins in SDRAM Mode Symbol Test Condition Min. Rise/Fall Min. Clock Frequency Max. Rise/Fall Units f — — 125 — MHz Output pin slew rate (max. drive) tps 25 pF 50 pF 1.11/1.20 0.97/0.65 1.74/1.75 0.92/0.94 2.42/2.46 1.39/1.30 V/ns Output pin slew rate (high drive) tps 25 pF 50 pF 0.76/0.80 0.40/0.43 1.16/1.19 0.61/0.63 1.76/1.66 0.93/0.87 V/ns Output pin slew rate (standard drive) tps 25 pF 50 pF 0.38/0.41 0.20/0.22 0.59/0.60 0.31/0.32 0.89/0.82 0.47/0.43 V/ns Output pin di/dt (max. drive) tdit 25 pF 50 pF 89 94 198 209 398 421 mA/ns Output pin di/dt (high drive) tdit 25 pF 50 pF 59 62 132 139 265 279 mA/ns Output pin di/dt (standard drive) tdit 25 pF 50 pF 29 31 65 69 132 139 mA/ns Parameter Clock frequency i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 29 Table 26. AC Electrical Characteristics of DDR Type IO Pins in SDRAM Mode Max Drive (1.8 V) Symbol Test Condition Min. Rise/Fall Typ. Max. Rise/Fall Units f — 125 — — MHz Output pin slew rate (max. drive) tps 25 pF 50 pF 2.83/2.68 1.59/1.49 1.84/1.85 1.03/1.05 1.21/1.40 0.70/0.75 V/ns Output pin di/dt (max. drive)2 didt 25 pF 50 pF 89 95 202 213 435 456 mA/ns Input pin transition times3 trfi 1.0 pF 0.07/0.08 0.11/0.12 0.16/0.20 ns Input pin propagation delay, 50%–50% tpi 1.0 pF 0.35/1.17 0.63/1.53 1.16/2.04 ns Input pin propagation delay, 40%–60% tpi 1.0 pF 1.18/1.99 1.45/2.35 1.97/2.85 ns Parameter Clock frequency 1 1 Min. condition for tps: wcs model, 1.1 V, IO 1.65 V, and 105 °C. tps is measured between VIL to VIH for rising edge and between VIH to VIL for falling edge. 2 Max. condition for tdit: bcs model, 1.3 V, IO 1.95 V, and –40 °C. 3 Max. condition for tpi and trfi: wcs model, 1.1 V, IO 1.65 V and 105 °C. Min. condition for tpi and trfi: bcs model, 1.3 V, IO 1.95 V and –40 °C. Input transition time from pad is 5 ns (20%–80%). 4.9 Module-Level AC Electrical Specifications This section contains the AC electrical information (including timing specifications) for the modules of the i.MX35. The modules are listed in alphabetical order. 4.9.1 AUDMUX Electrical Specifications The AUDMUX provides a programmable interconnect logic for voice, audio and data routing between internal serial interfaces (SSI) and external serial interfaces (audio and voice codecs). The AC timing of AUDMUX external pins is hence governed by the SSI module. See the electrical specification for SSI. 4.9.2 CSPI AC Electrical Specifications The i.MX35 provides two CSPI modules. CSPI ports are multiplexed in the i.MX35 with other pins. See the “External Signals and Multiplexing” chapter of the reference manual for more details. i.MX35 Applications Processors for Automotive Products, Rev. 10 30 Freescale Semiconductor Figure 7 and Figure 8 depict the master mode and slave mode timings of the CSPI, and Table 27 lists the timing parameters. SPI_RDY CS11 SSn[3:0] CS1 CS3 CS2 CS6 CS5 CS3 CS4 SCLK CS2 CS7 CS8 MOSI CS9 CS10 MISO Figure 7. CSPI Master Mode Timing Diagram SSn[3:0] CS1 CS3 CS2 CS5 CS6 CS4 SCLK CS9 CS3 CS10 CS2 MISO CS8 CS7 MOSI Figure 8. CSPI Slave Mode Timing Diagram Table 27. CSPI Interface Timing Parameters ID Parameter Symbol Min. Max. Units CS1 SCLK cycle time tclk 60 — ns CS2 SCLK high or low time tSW 30 — ns CS3 SCLK rise or fall tRISE/FALL — 7.6 ns CS4 SSn[3:0] pulse width tCSLH 30 — ns CS5 SSn[3:0] lead time (CS setup time) tSCS 30 — ns CS6 SSn[3:0] lag time (CS hold time) tHCS 30 — ns CS7 MOSI setup time tSmosi 5 — ns CS8 MOSI hold time tHmosi 5 — ns CS9 MISO setup time tSmiso 5 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 31 Table 27. CSPI Interface Timing Parameters (continued) ID Parameter Symbol Min. Max. Units CS10 MISO hold time tHmiso 5 — ns CS11 SPI_RDY setup time tSDRY 5 — ns 4.9.3 DPLL Electrical Specifications There are three PLLs inside the i.MX35, all based on the same PLL design. The reference clock for these PLLs is normally generated from an external 24-MHz crystal connected to an internal oscillator via EXTAL24M and XTAL24 pins. It is also possible to connect an external 24-MHz clock directly to EXTAL24M, bypassing the internal oscillator. DPLL specifications are listed in Table 28. Table 28. DPLL Specifications Parameter Min. Typ. Max. Unit Comments Reference clock frequency 10 24 100 Max. allowed reference clock phase noise — — 0.03 2 Tdck1 Fmodulation < 50 kHz 0.01 50 kHz < Fmodulation 300 Hz 0.15 Fmodulation > 300 KHz Frequency lock time (FOL mode or non-integer MF) — — 80 μs — Phase lock time — — 100 μs — Max. allowed PL voltage ripple — — 150 100 150 mV 1 MHz Fmodulation < 50 kHz 50 kHz < Fmodulation 300 Hz Fmodulation > 300 KHz There are two PLL are used in the i.MX35, MPLL and PPLL. Both are based on same DPLL design. If crystals are used instead of external oscillators, they should meed the following specifications: Table 29. Clock Input Tolerance Parameters OSC24M OSC_AUDIO Normal Frequency 24 MHz 25.576 MHz Frequency Tolerance 30 ppm 20 ppm (high quality) ESR <80 Ω <80 Ω Load Capacitance 8 pF-12 pF 8 pF-12 pF Shunt capacitance <7 pF <7 pF Level of drive >150 μW >150 μW i.MX35 Applications Processors for Automotive Products, Rev. 10 32 Freescale Semiconductor 4.9.4 Embedded Trace Macrocell (ETM) Electrical Specifications ETM is an ARM protocol. The timing specifications in this section are given as a guide for a test point access (TPA) that supports TRACECLK frequencies up to 133 MHz. Figure 9 depicts the TRACECLK timings of ETM, and Table 30 lists the timing parameters. Figure 9. ETM TRACECLK Timing Diagram Table 30. ETM TRACECLK Timing Parameters ID Parameter Min. Max. Unit Frequency dependent — ns Tcyc Clock period Twl Low pulse width 2 — ns Twh High pulse width 2 — ns Tr Clock and data rise time — 3 ns Tf Clock and data fall time — 3 ns Figure 10 depicts the setup and hold requirements of the trace data pins with respect to TRACECLK, and Table 31 lists the timing parameters. Figure 10. Trace Data Timing Diagram Table 31. ETM Trace Data Timing Parameters ID Parameter Min. Max. Unit Ts Data setup 2 — ns Th Data hold 1 — ns 4.9.4.1 Half-Rate Clocking Mode When half-rate clocking is used, the trace data signals are sampled by the TPA on both the rising and falling edges of TRACECLK, where TRACECLK is half the frequency of the clock shown in Figure 10. The same Ts and Th parameters from Table 31 still apply with respect to the falling edge of the TRACECLK signal. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 33 4.9.5 EMI Electrical Specifications This section provides electrical parametrics and timing for the EMI module. 4.9.5.1 NAND Flash Controller Interface (NFC) The i.MX35 NFC supports normal timing mode, using two flash clock cycles for one access of RE and WE. AC timings are provided as multiplications of the clock cycle and fixed delay. Figure 11, Figure 12, Figure 13, and Figure 14 depict the relative timing requirements among different signals of the NFC at module level for normal mode. Table 32 lists the timing parameters. NFCLE NF2 NF1 NF3 NF4 NFCE NF5 NFWE NF6 NF7 NFALE NF8 NF9 Command NFIO[7:0] Figure 11. Command Latch Cycle Timing DIagram NFCLE NF1 NF4 NF3 NFCE NF10 NF11 NF5 NFWE NF7 NF6 NFALE NF8 NF9 NFIO[7:0] Address Figure 12. Address Latch Cycle Timing DIagram i.MX35 Applications Processors for Automotive Products, Rev. 10 34 Freescale Semiconductor NFCLE NF1 NF3 NFCE NF10 NF11 NF5 NFWE NF7 NF6 NFALE NF8 NF9 NFIO[15:0] Data to NF Figure 13. Write Data Latch Cycle Timing DIagram NFCLE NFCE NF14 NF15 NF13 NFRE NF16 NF17 NFRB NF12 NFIO[15:0] Data from NF Figure 14. Read Data Latch Cycle Timing DIagram Table 32. NFC Timing Parameters1 ID Parameter Symbol Timing T = NFC Clock Cycle2 Example Timing for NFC Clock ≈ 33 MHz T = 30 ns Min. Max. Min. Max. Unit NF1 NFCLE setup time tCLS T – 4.0 ns — 26 — ns NF2 NFCLE hold time tCLH T – 5.0 ns — 25 — ns NF3 NFCE setup time tCS T – 2.0 ns — 28 — ns NF4 NFCE hold time tCH T – 1.0 ns — 29 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 35 Table 32. NFC Timing Parameters1 (continued) ID Parameter Symbol Timing T = NFC Clock Cycle2 Min. Max. Example Timing for NFC Clock ≈ 33 MHz T = 30 ns Min. Max. NF5 NF_WP pulse width tWP NF6 NFALE setup time tALS T – 4.0 ns — 26 — ns NF7 NFALE hold time tALH T – 4.5 ns — 25.5 — ns NF8 Data setup time tDS T – 2.0 ns — 28 — ns NF9 Data hold time tDH T – 5.0 ns — 25 — ns NF10 Write cycle time tWC 2T – 3.0 ns 57 ns NF11 NFWE hold time tWH T – 5.0 ns 25 ns NF12 Ready to NFRE low tRR 6T — 180 — ns NF13 NFRE pulse width tRP 1.5T – 1.0 ns — 44 — ns NF14 READ cycle time tRC 2T – 5.5 ns — 54.5 — ns NF15 NFRE high hold time tREH 0.5T – 4.0 ns 11 — ns NF16 Data setup on READ tDSR N/A 9 — ns NF17 Data hold on READ tDHR N/A 0 — ns 1 2 T – 1.0 ns Unit 29 ns The flash clock maximum frequency is 50 MHz. Subject to DPLL jitter specification listed in Table 28, "DPLL Specifications," on page 32. NOTE High is defined as 80% of signal value and low is defined as 20% of signal value. Timing for HCLK is 133 MHz and internal NFC clock (flash clock) is approximately 33 MHz (30 ns). All timings are listed according to this NFC clock frequency (multiples of NFC clock phases), except NF16 and NF17, which are not NFC clock related. 4.9.5.2 Wireless External Interface Module (WEIM) All WEIM output control signals may be asserted and deasserted by internal clocks related to the BCLK rising edge or falling edge according to the corresponding assertion or negation control fields. The address always begins related to BCLK falling edge but may be ended both on rising and falling edge in muxed mode according to control register configuration. Output data begins related to BCLK rising edge except in muxed mode where both rising and falling edge may be used according to control register configuration. i.MX35 Applications Processors for Automotive Products, Rev. 10 36 Freescale Semiconductor Input data, ECB and DTACK all captured according to BCLK rising edge time. Figure 15 depicts the timing of the WEIM module, and Table 33 lists the timing parameters. WEIM Output Timing WE2 WE3 WE1 BCLK ... WE4 WE5 WE6 WE7 WE8 WE9 WE10 WE11 WE12 WE13 WE14 WE15 WE16 WE17 Address CSx_B RW_B OE_B EBy_B LBA_B Output Data WEIM Input Timing BCLK WE18 Input Data WE20 WE22 ECB_B WE24 WE26 DTACK_B WE27 Figure 15. WEIM Bus Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 37 Table 33. WEIM Bus Timing Parameters1 ID Parameter Min. Max. Unit 14.5 — ns WE1 BCLK cycle time2 WE2 BCLK low-level width2 7 — ns WE3 BCLK high-level width2 7 — ns WE4 Address valid to Clock rise/fall 15 21 ns WE5 Clock rise/fall to address invalid 22 25 ns WE6 Clock rise/fall to CSx_B valid 15 19 ns WE7 Clock rise/fall to CSx_B invalid 3.6 5 ns WE8 Clock rise/fall to RW_B valid 8 12 ns WE9 Clock rise/fall to RW_B invalid 3 8 ns WE10 Clock rise/fall to OE_B valid 7 12 ns WE11 Clock rise/fall to OE_B invalid 3.8 5.5 ns WE12 Clock rise/fall to EBy_B valid 6 11.5 ns WE13 Clock rise/fall to EBy_B invalid 6 10 ns WE14 Clock rise/fall to LBA_B valid 17.5 20 ns WE15 Clock rise/fall to LBA_B invalid 0 1 ns WE16 Clock rise/fall to Output Data valid 5 10 ns WE17 Clock rise to Output Data invalid 0 2.5 ns WE18 Input Data Valid to Clock rise3 1 — ns WE19 Input Data Valid to Clock rise, FCE=0 (in the case there is ECB_B asserted during access) (BCLK/2) + 3.01 — ns WE19 Input Data Valid to Clock rise, FCE=0 (in the case there is NO ECB_B asserted during access) 6.9 — ns WE20 Clock rise to Input Data invalid3 1 — ns WE22 ECB_B setup time3 5 — ns WE24 ECB_B hold time3 0 — ns WE26 DTACK_B setup time 5.4 — ns WE27 DTACK_B hold time –3.2 — ns 1 “High” is defined as 80% of signal value, and “low” is defined as 20% of signal value. BCLK parameters are measured from the 50% point. For example, “high” is defined as 50% of signal value and “low” is defined as 50% of signal value. 3 Parameters W18, W20, W22, and W24 are tested when FCE=1. i.MX35 does not support FCE=0. 2 NOTE Test conditions: load capacitance, 25 pF. Recommended drive strength for all controls, address, and BCLK is set to maximum drive. i.MX35 Applications Processors for Automotive Products, Rev. 10 38 Freescale Semiconductor Recommended drive strength for all controls, address and BCLK is set to maximum drive. Figure 16 through Figure 21 depict some examples of basic WEIM accesses to external memory devices with the timing parameters mentioned in Table 33 for specific control parameter settings. BCLK WE5 WE4 ADDR V1 Last Valid Address Next Address WE6 WE7 WE14 WE15 WE10 WE11 WE12 WE13 CS[x] RW LBA OE EB[y] WE20, WE21 V1 DATA WE18, WE 19 Figure 16. Synchronous Memory Timing Diagram for Read Access—WSC = 1 BCLK WE5 WE4 ADDR Last Valid Address CS[x] RW WE6 WE7 WE8 WE9 WE14 LBA Next Address V1 WE15 OE WE12 EB[y] WE13 WE17 DATA V1 WE16 Figure 17. Synchronous Memory Timing Diagram for Write Access— WSC = 1, EBWA = 1, EBWN = 1, LBN = 1 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 39 BCLK WE4 WE5 ADDR Last Valid Addr Address V1 Address V2 WE7 WE6 CS[x] RW WE14 LBA WE15 WE11 WE10 OE WE13 WE12 EB[y] WE24, WE25 WE24, WE25 ECB WE22, WE23 WE20, WE21 WE22, WE23 WE20, WE21 V1 V1+2 Halfword Halfword DATA WE18, WE19 V2 Halfword V2+2 Halfword WE18, WE19 Figure 18. Synchronous Memory Timing Diagram for Two Non-Sequential Read Accesses— WSC = 2, SYNC = 1, DOL = 0 BCLK WE5 WE4 ADDR Last Valid Addr CS[x] RW LBA Address V1 WE6 WE7 WE8 WE9 WE14 WE15 OE EB[y] WE13 WE12 WE24, WE25 ECB WE22, WE23 WE17 V1+4 V1+8 V1+12 V1 DATA WE16 WE17 WE16 Figure 19. Synchronous Memory TIming Diagram for Burst Write Access— BCS = 1, WSC = 4, SYNC = 1, DOL = 0, PSR = 1 i.MX35 Applications Processors for Automotive Products, Rev. 10 40 Freescale Semiconductor BCLK WE4 ADDR/ Last Valid Addr M_DATA CS[x] RW WE17 WE5 Write Data Address V1 WE16 WE6 WE7 WE8 WE9 Write WE14 WE15 LBA OE EB[y] WE12 WE13 Figure 20. Muxed A/D Mode Timing Diagram for Synchronous Write Access— WSC = 7, LBA = 1, LBN = 1, LAH = 1 BCLK WE4 ADDR/ Last Valid Addr M_DATA WE6 CS[x] WE5 WE20, WE21 Address V1 Read Data WE18, WE19 WE7 RW WE14 WE15 LBA WE10 OE EB[y] WE12 WE11 WE13 Figure 21. Muxed A/D Mode Timing Diagram for Synchronous Read Access— WSC = 7, LBA = 1, LBN = 1, LAH = 1, OEA = 7 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 41 Figure 22 through Figure 26, and Table 34 help to determine timing parameters relative chip select (CS) state for asynchronous and DTACK WEIM accesses with corresponding WEIM bit fields and the timing parameters mentioned above. CS [x] WE31 ADDR Last Valid Address WE32 Next Address Address V1 RW WE39 WE40 WE35 WE36 WE37 WE38 LBA OE EB[y] WE44 DATA V1 WE43 Figure 22. Asynchronous Memory Read Access CS[x] MAXDI WE31 D(V1) Addr. V1 ADDR/ M_DATA WE32A WE WE44 WE40 WE39 LBA WE35A WE36 OE WE37 WE38 BE[y] MAXCO Figure 23. Asynchronous A/D muxed Read Access (RWSC = 5) i.MX35 Applications Processors for Automotive Products, Rev. 10 42 Freescale Semiconductor CS[x] WE31 ADDR Last Valid Address WE33 WE32 Next Address Address V1 WE34 RW WE39 WE40 WE45 WE46 LBA OE BE[y] WE42 DATA D(V1) WE41 Figure 24. Asynchronous Memory Write Access CS[x] WE41 WE31 ADDR/ Addr. V1 M_DATA WE32A WE33 D(V1) WE34 WE42 RW WE40A LBA WE39 OE WE45 WE46 BE[y] WE42 Figure 25. Asynchronous A/D Mux Write Access i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 43 CS [x] WE31 ADDR WE32 Last Valid Address Next Address Address V1 RW WE39 WE40 WE35 WE36 WE37 WE38 LBA OE EB[y] WE44 DATA V1 WE43 WE48 DATA WE47 Figure 26. DTACK Read Access Table 34. WEIM Asynchronous Timing Parameters Relative Chip Select Table Ref No. Parameter Determination By Synchronous Measured Parameters1 Min Max (If 133 MHz is supported by SoC) Unit WE31 CS[x] valid to Address valid WE4 – WE6 – CSA2 — 3 – CSA ns WE32 Address invalid to CS[x] invalid WE7 – WE5 – CSN3 — 3 – CSN ns WE32A( muxed A/D CS[x] valid to address invalid — ns WE33 CS[x] valid to WE valid WE8 – WE6 + (WEA – CSA) — 3 + (WEA – CSA) ns WE34 WE invalid to CS[x] invalid WE7 – WE9 + (WEN – CSN) — 3 – (WEN_CSN) ns WE35 CS[x] valid to OE valid WE10 – WE6 + (OEA – CSA) — 3 + (OEA – CSA) ns WE35A (muxed A/D) CS[x] valid to OE valid WE10 – WE6 + (OEA + RLBN + RLBA + ADH + 1 – CSA) –3 + (OEA + RLBN + RLBA + ADH + 1 – CSA) 3 + (OEA + RLBN + RLBA + ADH + 1 – CSA) ns WE36 OE invalid to CS[x] invalid WE7 – WE11 + (OEN – CSN) — 3 – (OEN – CSN) ns CS[x] valid to BE[y] valid (read WE12 – WE6 + (RBEA – CSA) access) — 3 + (RBEA4 – CSA) ns WE37 WE4 – WE7 + (LBN + LBA + 1 –3 + (LBN + LBA + – CSA2) 1 – CSA) WE38 BE[y] invalid to CS[x] invalid (read access) WE7 – WE13 + (RBEN – CSN) — 3 – (RBEN5 – CSN) ns WE39 CS[x] valid to LBA valid WE14 – WE6 + (LBA – CSA) — 3 + (LBA – CSA) ns WE40 LBA invalid to CS[x] invalid WE7 – WE15 – CSN — 3 – CSN ns i.MX35 Applications Processors for Automotive Products, Rev. 10 44 Freescale Semiconductor Table 34. WEIM Asynchronous Timing Parameters Relative Chip Select Table (continued) Ref No. Parameter WE40A (muxed A/D) CS[x] valid to LBA invalid WE41 CS[x] valid to Output Data valid WE41A CS[x] valid to Output Data valid (muxed A/D) WE42 WE43 WE44 WE45 Output Data invalid to CS[x] Invalid Determination By Synchronous Measured Parameters1 Max (If 133 MHz is supported by SoC) WE14 – WE6 + (LBN + LBA + 1 –3 + (LBN + LBA + 3 + (LBN + LBA + 1 – – CSA) 1 – CSA) CSA) Unit ns WE16 – WE6 – WCSA — 3 – WCSA ns WE16 – WE6 + (WLBN + WLBA + ADH + 1 – WCSA) — 3 + (WLBN + WLBA + ADH + 1 – WCSA) ns WE17 – WE7 – CSN — 3 – CSN ns MAXCO6 – MAXCSO7 + MAXDI8 — ns 0 — ns — 3 + (WBEA – CSA) ns Input Data valid to CS[x] invalid MAXCO – MAXCSO + MAXDI CS[x] invalid to Input Data invalid Min 0 CS[x] valid to BE[y] valid (write WE12 – WE6 + (WBEA – CSA) access) WE46 BE[y] invalid to CS[x] invalid (write access) WE7 – WE13 + (WBEN – CSN) — –3 + (WBEN – CSN) ns WE47 DTACK valid to CS[x] invalid MAXCO – MAXCSO + MAXDTI MAXCO6 – MAXCSO7 + MAXDTI9 — ns WE48 CS[x] Invalid to DTACK invalid 0 0 — ns 1 For the value of parameters WE4–WE21, see column BCD = 0 in Table 33. CS Assertion. This bit field determines when the CS signal is asserted during read/write cycles. 3 CS Negation. This bit field determines when the CS signal is negated during read/write cycles. 4 BE Assertion. This bit field determines when the BE signal is asserted during read cycles. 5 BE Negation. This bit field determines when the BE signal is negated during read cycles. 6 Output maximum delay from internal driving ADDR/control FFs to chip outputs. 7 Output maximum delay from CS[x] internal driving FFs to CS[x] out. 8 DATA maximum delay from chip input data to its internal FF. 9 DTACK maximum delay from chip dtack input to its internal FF. Note: All configuration parameters (CSA, CSN, WBEA, WBEN, LBA, LBN, OEN, OEA, RBEA, and RBEN) are in cycle units. 2 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 45 4.9.5.3 ESDCTL Electrical Specifications Figure 27 through Figure 35 depict the timings pertaining to the ESDCTL module, which interfaces with mobile DDR or SDR SDRAM. Table 35 through Table 45 list the timing parameters. SD1 SDCLK SDCLK SD2 SD3 SD4 CS SD5 RAS SD4 SD5 SD4 CAS SD4 SD5 SD5 WE SD6 SD7 ADDR ROW/BA COL/BA SD8 SD10 SD9 DQ Data SD4 DQM Note: CKE is high during the read/write cycle. SD5 Figure 27. SDRAM Read Cycle Timing Diagram Table 35. DDR/SDR SDRAM Read Cycle Timing Parameters ID Parameter Symbol Min. Max. Unit SD1 SDRAM clock high-level width tCH 3.4 4.1 ns SD2 SDRAM clock low-level width tCL 3.4 4.1 ns SD3 SDRAM clock cycle time tCK 7.0 — ns SD4 CS, RAS, CAS, WE, DQM, CKE setup time tCMS 2.0 — ns SD5 CS, RAS, CAS, WE, DQM, CKE hold time tCMH 1.8 — ns SD6 Address setup time tAS 2.0 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 46 Freescale Semiconductor Table 35. DDR/SDR SDRAM Read Cycle Timing Parameters (continued) ID 1 Parameter SD7 Address hold time SD8 SDRAM access time Symbol Min. Max. Unit tAH 1.8 — ns tAC — 6.47 ns SD9 1 Data out hold time tOH 1.2 — ns SD10 Active to read/write command period tRC 10 — clock Timing parameters are relevant only to SDR SDRAM. For the specific DDR SDRAM data related timing parameters, see Table 44 and Table 45. NOTE SDR SDRAM CLK parameters are measured from the 50% point—that is, high is defined as 50% of signal value and low is defined as 50% of signal value. SD1 + SD2 does not exceed 7.5 ns for 133 MHz. The timing parameters are similar to the ones used in SDRAM data sheets—that is, Table 35 indicates SDRAM requirements. All output signals are driven by the ESDCTL at the negative edge of SDCLK and the parameters are measured at maximum memory frequency. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 47 SD1 SDCLK SDCLK SD2 SD3 SD4 CS SD5 RAS SD4 CAS SD5 SD4 SD4 WE SD5 SD5 SD7 SD6 ADDR BA COL/BA ROW / BA SD13 DQ SD14 DATA DQM Figure 28. SDR SDRAM Write Cycle Timing Diagram Table 36. SDR SDRAM Write Timing Parameters ID Parameter Symbol Min. Max. Unit SD1 SDRAM clock high-level width tCH 0.45 0.55 ns SD2 SDRAM clock low-level width tCL 0.45 0.55 ns SD3 SDRAM clock cycle time tCK 7.0 — ns SD4 CS, RAS, CAS, WE, DQM, CKE setup time tCMS 2.4 — ns SD5 CS, RAS, CAS, WE, DQM, CKE hold time tCMH 1.4 — ns SD6 Address setup time tAS 2.4 — ns SD7 Address hold time tAH 1.4 — ns SD13 Data setup time tDS 2.4 — ns SD14 Data hold time tDH 1.4 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 48 Freescale Semiconductor NOTE Test conditions are: pin voltage 1.7 V–1.95 V, capacitance 15 pF for all pins (both DDR and non-DDR pins), drive strength is high (7.2 mA). “High” is defined as 80% of signal value and “low” is defined as 20% of signal value. SDR SDRAM CLK parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value, and “low” is defined as 50% of signal value. tCH + tCL will not exceed 7.5 ns for 133 MHz. DDR SDRAM CLK parameters are measured at the crossing point of SDCLK and SDCLK (inverted clock). The timing parameters are similar to the ones used in SDRAM data sheets. Table 36 indicates SDRAM requirements. All output signals are driven by the ESDCTL at the negative edge of SDCLK, and the parameters are measured at maximum memory frequency. SD1 SDCLK SDCLK SD2 SD3 CS RAS SD11 CAS SD10 SD10 WE SD7 SD6 ADDR BA ROW/BA Figure 29. SDRAM Refresh Timing Diagram Table 37. SDRAM Refresh Timing Parameters ID Parameter Symbol Min. Max. Unit SD1 SDRAM clock high-level width tCH 3.4 4.1 ns SD2 SDRAM clock low-level width tCL 3.4 4.1 ns SD3 SDRAM clock cycle time tCK 7.5 — ns SD6 Address setup time tAS 1.8 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 49 Table 37. SDRAM Refresh Timing Parameters (continued) ID Parameter SD7 Address hold time SD10 Precharge cycle period1 SD11 1 Auto precharge command period 1 Symbol Min. Max. Unit tAH 1.8 — ns tRP 1 4 clock tRC 2 20 clock SD10 and SD11 are determined by SDRAM controller register settings. NOTE SDR SDRAM CLK parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value and “low” is defined as 50% of signal value. The timing parameters are similar to the ones used in SDRAM data sheets. Table 37 indicates SDRAM requirements. All output signals are driven by the ESDCTL at the negative edge of SDCLK, and the parameters are measured at maximum memory frequency. SDCLK CS RAS CAS WE ADDR BA SD16 CKE SD16 Don’t care Figure 30. SDRAM Self-Refresh Cycle Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 50 Freescale Semiconductor NOTE The clock will continue to run unless both CKEs are low. Then the clock will be stopped in low state. Table 38. SDRAM Self-Refresh Cycle Timing Parameters ID Parameter SD16 CKE output delay time Symbol Min. Max. Unit tCKS 1.8 — ns DDR1 SDCLK SDCLK DDR2 DDR4 DDR3 CS DDR5 DDR4 RAS DDR5 DDR4 CAS DDR4 DDR5 DDR5 WE CKE DDR4 DDR6 ADDR DDR7 ROW/BA COL/BA Figure 31. DDR2 SDRAM Basic Timing Parameters Table 39. DDR2 SDRAM Timing Parameter Table DDR2-400 ID PARAMETER Symbol Unit Min Max DDR1 SDRAM clock high-level width tCH 0.45 0.55 tCK DDR2 SDRAM clock low-level width tCL 0.45 0.55 tCK DDR3 SDRAM clock cycle time tCK 7.0 8.0 ns DDR4 CS, RAS, CAS, CKE, WE setup time tIS1 1.5 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 51 Table 39. DDR2 SDRAM Timing Parameter Table DDR2-400 ID DDR5 PARAMETER CS, RAS, CAS, CKE, WE hold time Symbol tIH1 Unit Min Max 1.25 — ns 1 1.5 — ns 1.5 — ns DDR6 Address output setup time tIS DDR7 Address output hold time tIH1 NOTE These values are for command/address slew rate of 1 V/ns and SDCLK, SDCLK_B differential slew rate of 2 V/ns. For different values, use the derating table. Table 40. Derating Values for DDR2–400, DDR2–533 i.MX35 Applications Processors for Automotive Products, Rev. 10 52 Freescale Semiconductor SDCLK SDCLK_B DDR21 DDR22 DQS (output) DDR18 DDR17 DQ (output) DDR20 DDR23 DDR17 DDR19 DDR18 Data Data Data Data Data Data Data Data DM DM DM DM DM DM DM DM DQM (output) DDR17 DDR18 DDR17 DDR18 Figure 32. DDR2 SDRAM Write Cycle Timing Diagram Table 41. DDR2 SDRAM Write Cycle Parameters DDR2-400 ID PARAMETER Symbol Unit Min Max DDR17 DQ and DQM setup time to DQS (single-ended strobe) tDS1(base) 0.5 — ns DDR18 DQ and DQM hold time to DQS (single-ended strobe) tDH1(base) 0.5 — ns DDR19 Write cycle DQS falling edge to SDCLK output setup time. tDSS 0.2 — tCK DDR20 Write cycle DQS falling edge to SDCLK output hold time. tDSH 0.2 — tCK DDR21 DQS latching rising transitions to associated clock edges tDQSS –0.25 0.25 tCK DDR22 DQS high level width tDQSH 0.35 — tCK DDR23 DQS low level width tDQSL 0.35 — tCK NOTE These values are for DQ/DM slew rate of 1 V/ns and DQS slew rate of 1 V/ns. For different values use the derating table. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 53 Table 42. DDR Single-ended Slew Rate NOTE SDR SDRAM CLK parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value and “low” is defined as 50% of signal value. DDR SDRAM CLK parameters are measured at the crossing point of SDCLK and SDCLK (inverted clock). Test conditions are: Capacitance 15 pF for DDR PADS. Recommended drive strength is Medium for SDCLK and High for Address and controls. SDCLK SDCLK_B DQS (input) DDR26 DDR25 DDR24 DQ (input) DATA DATA DATA DATA DATA DATA DATA DATA Figure 33. DDR2 SDRAM DQ vs. DQS and SDCLK READ Cycle Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 54 Freescale Semiconductor Table 43. DDR2 SDRAM Read Cycle Parameter Table DDR2-400 ID PARAMETER Symbol DDR24 DQS – DQ Skew (defines the Data valid window in read cycles related to DQS). DDR25 DQS DQ in HOLD time from DQS1 DDR26 DQS output access time from SDCLK posedge Unit Min Max tDQSQ — 0.35 ns tQH 2.925 — ns tDQSCK –0.5 0.5 ns 1 The value was calculated for an SDCLK frequency of 133 MHz by the formula tQH = tHP – tQHS = min (tCL,tCH) – tQHS = 0.45 × tCK – tQHS = 0.45 × 7.5 – 0.45 = 2.925 ns. NOTE SDRAM CLK and DQS-related parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value and “low” is defined as 50% of signal value. DDR SDRAM CLK parameters are measured at the crossing point of SDCLK and SDCLK (inverted clock). Test conditions are: Capacitance 15 pF for DDR PADS. Recommended drive strength is Medium for SDCLK and High for Address and controls. SDCLK SDCLK SD19 DQS (output) SD18 SD17 DQ (output) DQM (output) SD17 SD20 SD18 Data Data Data Data Data Data Data Data DM DM DM DM DM DM DM DM SD17 SD17 SD18 SD18 Figure 34. Mobile DDR SDRAM Write Cycle Timing Diagram Table 44. Mobile DDR SDRAM Write Cycle Timing Parameters1 ID 1 Parameter Symbol Min. Max. Unit SD17 DQ and DQM setup time to DQS tDS 0.95 — ns SD18 DQ and DQM hold time to DQS tDH 0.95 — ns SD19 Write cycle DQS falling edge to SDCLK output delay time. tDSS 1.8 — ns SD20 Write cycle DQS falling edge to SDCLK output hold time. tDSH 1.8 — ns Test condition: Measured using delay line 5 programmed as follows: ESDCDLY5[15:0] = 0x0703. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 55 NOTE SDRAM CLK and DQS-related parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value and “low” is defined as 50% of signal value. The timing parameters are similar to the ones used in SDRAM data sheets. Table 44 indicates SDRAM requirements. All output signals are driven by the ESDCTL at the negative edge of SDCLK, and the parameters are measured at maximum memory frequency. SDCLK SDCLK SD23 DQS (input) SD22 SD21 DQ (input) Data Data Data Data Data Data Data Data Figure 35. Mobile DDR SDRAM DQ versus DQS and SDCLK Read Cycle Timing Diagram Table 45. Mobile DDR SDRAM Read Cycle Timing Parameters ID Parameter SD21 DQS – DQ Skew (defines the Data valid window in read cycles related to DQS). Symbol tDQSQ — 0.85 ns tQH 2.3 — ns tDQSCK — 6.7 ns SD22 DQS DQ HOLD time from DQS SD23 DQS output access time from SDCLK posedge Min. Max. Unit NOTE SDRAM CLK and DQS-related parameters are measured from the 50% point—that is, “high” is defined as 50% of signal value, and “low” is defined as 50% of signal value. The timing parameters are similar to the ones used in SDRAM data sheets. Table 45 indicates SDRAM requirements. All output signals are driven by the ESDCTL at the negative edge of SDCLK, and the parameters are measured at maximum memory frequency. i.MX35 Applications Processors for Automotive Products, Rev. 10 56 Freescale Semiconductor 4.9.6 Enhanced Serial Audio Interface (ESAI) Timing Specifications The ESAI consists of independent transmitter and receiver sections, each section with its own clock generator. Table 46 shows the interface timing values. The number field in the table refers to timing signals found in Figure 36 and Figure 37. Table 46. Enhanced Serial Audio Interface Timing Characteristics1,2 No. Symbol Expression2 Min. Max. Condition3 Unit tSSICC 4 × Tc 4 × Tc 30.0 30.0 — — i ck i ck 62 Clock cycle4 63 Clock high period • For internal clock — 2 × Tc − 9.0 6 — — • For external clock — 2 × Tc 15 — — Clock low period • For internal clock — 2 × Tc − 9.0 6 — — • For external clock — 2 × Tc 15 — — 65 SCKR rising edge to FSR out (bl) high — — — — — — 17.0 7.0 x ck i ck a ns 66 SCKR rising edge to FSR out (bl) low — — — — — — 17.0 7.0 x ck i ck a ns 67 SCKR rising edge to FSR out (wr) high5 — — — — — — 19.0 9.0 x ck i ck a ns 68 SCKR rising edge to FSR out (wr) low5 — — — — — — 19.0 9.0 x ck i ck a ns 69 SCKR rising edge to FSR out (wl) high — — — — — — 16.0 6.0 x ck i ck a ns 70 SCKR rising edge to FSR out (wl) low — — — — — — 17.0 7.0 x ck i ck a ns 71 Data in setup time before SCKR (SCK in synchronous mode) falling edge — — — — 12.0 19.0 — — x ck i ck ns 72 Data in hold time after SCKR falling edge — — — — 3.5 9.0 — — x ck i ck ns 73 FSR input (bl, wr) high before SCKR falling edge5 — — — — 2.0 12.0 — — x ck i ck a ns 74 FSR input (wl) high before SCKR falling edge — — — — 2.0 12.0 — — x ck i ck a ns 75 FSR input hold time after SCKR falling edge — — — — 2.5 8.5 — — x ck i ck a ns 78 SCKT rising edge to FST out (bl) high — — — — — — 18.0 8.0 x ck i ck ns 79 SCKT rising edge to FST out (bl) low — — — — — — 20.0 10.0 x ck i ck ns 64 ns ns ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 57 Table 46. Enhanced Serial Audio Interface Timing (continued) No. Characteristics1,2 Symbol Expression2 Min. Max. Condition3 Unit 80 SCKT rising edge to FST out (wr) high5 — — — — — — 20.0 10.0 x ck i ck ns 81 SCKT rising edge to FST out (wr) low5 — — — — — — 22.0 12.0 x ck i ck ns 82 SCKT rising edge to FST out (wl) high — — — — — — 19.0 9.0 x ck i ck ns 83 SCKT rising edge to FST out (wl) low — — — — — — 20.0 10.0 x ck i ck ns 84 SCKT rising edge to data out enable from high impedance — — — — — — 22.0 17.0 x ck i ck ns 86 SCKT rising edge to data out valid — — — — — — 18.0 13.0 x ck i ck ns 87 SCKT rising edge to data out high impedance 67 — — — — — — 21.0 16.0 x ck i ck ns 89 FST input (bl, wr) setup time before SCKT falling edge5 — — — — 2.0 18.0 — — x ck i ck ns 90 FST input (wl) setup time before SCKT falling edge — — — — 2.0 18.0 — — x ck i ck ns 91 FST input hold time after SCKT falling edge — — — — 4.0 5.0 — — x ck i ck ns 1 2 3 4 5 6 i ck = internal clock x ck = external clock i ck a = internal clock, asynchronous mode (asynchronous implies that SCKT and SCKR are two different clocks) i ck s = internal clock, synchronous mode (synchronous implies that SCKT and SCKR are the same clock) bl = bit length wl = word length wr = word length relative SCKT(SCKT pin) = transmit clock SCKR(SCKR pin) = receive clock FST(FST pin) = transmit frame sync FSR(FSR pin) = receive frame sync HCKT(HCKT pin) = transmit high frequency clock HCKR(HCKR pin) = receive high frequency clock For the internal clock, the external clock cycle is defined by Icyc and the ESAI control register. The word-relative frame sync signal waveform relative to the clock operates in the same manner as the bit-length frame sync signal waveform, but it spreads from one serial clock before the first bit clock (like the bit length frame sync signal), until the second-to-last bit clock of the first word in the frame. Periodically sampled and not 100% tested. i.MX35 Applications Processors for Automotive Products, Rev. 10 58 Freescale Semiconductor 62 63 64 SCKT (Input/Output) 78 79 FST (Bit) Out 82 FST (Word) Out 83 86 86 84 87 First Bit Data Out Last Bit 89 91 FST (Bit) In 90 91 FST (Word) In Figure 36. ESAI Transmitter Timing i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 59 62 63 64 SCKR (Input/Output) 65 66 FSR (Bit) Out 69 70 FSR (Word) Out 72 71 Data In First Bit Last Bit 75 73 FSR (Bit) In 74 75 FSR (Word) In Figure 37. ESAI Receiver Timing 4.9.7 eSDHCv2 AC Electrical Specifications Figure 38 depicts the timing of eSDHCv2, and Table 47 lists the eSDHCv2 timing characteristics. The following definitions apply to values and signals described in Table 47: • LS: low-speed mode. Low-speed card can tolerate a clock up to 400 kHz. • FS: full-speed mode. For a full-speed MMC card, the card clock can reach 20 MHz; a full-speed SD/SDIO card can reach 25 MHz. • HS: high-speed mode. For a high-speed MMC card, the card clock can reach 52 MHz; SD/SDIO can reach 50 MHz. i.MX35 Applications Processors for Automotive Products, Rev. 10 60 Freescale Semiconductor SD4 SD2 SD1 SD5 SDHCx_CLK SD3 output from eSDHCv2 to card SDHCx_CMD SDHCx_DAT_0 SDHCx_DAT_1 SD6 SDHCx_DAT_7 SD7 output from card to eSDHCv2 SD8 SDHCx_CMD SDHCx_DAT_0 SDHCx_DAT_1 SDHCx_DAT_7 Figure 38. eSDHCv2 Timing Table 47. eSDHCv2 Interface Timing Specification ID Parameter Symbols Min. Max. Unit Card Input Clock fPP1 0 Clock frequency (SD/SDIO Full Speed/High Speed) fPP2 0 25/50 MHz Clock frequency (MMC Full Speed/High Speed) fPP3 0 20/52 MHz Clock frequency (Identification Mode) fOD 100 400 kHz SD2 Clock Low time tWL 7 — ns SD3 Clock high time tWH 7 — ns SD4 Clock rise time tTLH — 3 ns SD5 Clock fall time tTHL — 3 ns tOD –3 3 ns SD7 eSDHC input setup time tISU 5 — ns SD8 eSDHC input hold time tIH4 2.5 — ns SD1 Clock frequency (Low Speed) 400 kHz eSDHC Output/Card Inputs CMD, DAT (Reference to CLK) SD6 eSDHC output delay eSDHC Input/Card Outputs CMD, DAT (Reference to CLK) 1 2 3 4 In low-speed mode, the card clock must be lower than 400 kHz, voltage ranges from 2.7 to 3.6 V. In normal-speed mode for the SD/SDIO card, clock frequency can be any value between 0–25 MHz. In high-speed mode, clock frequency can be any value between 0–50 MHz. In normal-speed mode for MMC card, clock frequency can be any value between 0 and 20 MHz. In high-speed mode, clock frequency can be any value between 0–52 MHz. To satisfy hold timing, the delay difference between clock input and cmd/data input must not exceed 2 ns. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 61 4.9.8 Fast Ethernet Controller (FEC) AC Electrical Specifications This section describes the electrical information of the FEC module. The FEC is designed to support both 10- and 100-Mbps Ethernet networks. An external transceiver interface and transceiver function are required to complete the interface to the media. The FEC supports the 10/100 Mbps Media Independent Interface (MII) using a total of 18 pins. The 10-Mbps 7-wire interface that is restricted to a 10-Mbps data rate uses seven of the MII pins for connection to an external Ethernet transceiver. 4.9.8.1 FEC AC Timing This section describes the AC timing specifications of the FEC. The MII signals are compatible with transceivers operating at a voltage of 3.3 V. 4.9.8.2 MII Receive Signal Timing The MII receive timing signals consist of FEC_RXD[3:0], FEC_RX_DV, FEC_RX_ER, and FEC_RX_CLK. The receiver functions correctly up to a FEC_RX_CLK maximum frequency of 25 MHz + 1%. There is no minimum frequency requirement. Additionally, the processor clock frequency must exceed twice the FEC_RX_CLK frequency. Table 48 lists MII receive channel timings. Table 48. MII Receive Signal Timing Characteristic1 Num. Min. Max. Unit M1 FEC_RXD[3:0], FEC_RX_DV, FEC_RX_ER to FEC_RX_CLK setup 5 — ns M2 FEC_RX_CLK to FEC_RXD[3:0], FEC_RX_DV, FEC_RX_ER hold 5 — ns M3 FEC_RX_CLK pulse width high 35% 65% FEC_RX_CLK period M4 FEC_RX_CLK pulse width low 35% 65% FEC_RX_CLK period 1 FEC_RX_DV, FEC_RX_CLK, and FEC_RXD0 have the same timing when in 10 Mbps 7-wire interface mode. Figure 39 shows the MII receive signal timings listed in Table 48. M3 FEC_RX_CLK (input) M4 FEC_RXD[3:0] (inputs) FEC_RX_DV FEC_RX_ER M1 M2 Figure 39. MII Receive Signal Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 62 Freescale Semiconductor 4.9.8.3 MII Transmit Signal Timing The transmitter timing signals consist of FEC_TXD[3:0], FEC_TX_EN, FEC_TX_ER, and FEC_TX_CLK. The transmitter functions correctly up to a FEC_TX_CLK maximum frequency of 25 MHz + 1%. There is no minimum frequency requirement. Additionally, the processor clock frequency must exceed twice the FEC_TX_CLK frequency. Table 49 lists MII transmit channel timings. Table 49. MII Transmit Signal Timing Characteristic1 Num Min. Max. Unit M5 FEC_TX_CLK to FEC_TXD[3:0], FEC_TX_EN, FEC_TX_ER invalid 5 — ns M6 FEC_TX_CLK to FEC_TXD[3:0], FEC_TX_EN, FEC_TX_ER valid — 20 ns M7 FEC_TX_CLK pulse width high 35% 65% FEC_TX_CLK period M8 FEC_TX_CLK pulse width low 35% 65% FEC_TX_CLK period 1 FEC_TX_EN, FEC_TX_CLK, and FEC_TXD0 have the same timing when in 10 Mbps 7-wire interface mode. Figure 40 shows the MII transmit signal timings listed in Table 49. M7 FEC_TX_CLK (input) M5 M8 FEC_TXD[3:0] (outputs) FEC_TX_EN FEC_TX_ER M6 Figure 40. MII Transmit Signal Timing Diagram 4.9.8.4 MII Asynchronous Inputs Signal Timing The MII asynchronous timing signals are FEC_CRS and FEC_COL. Table 50 lists MII asynchronous inputs signal timing. Table 50. MII Asynch Inputs Signal Timing 1 Num Characteristic Min. Max. Unit M91 FEC_CRS to FEC_COL minimum pulse width 1.5 — FEC_TX_CLK period FEC_COL has the same timing in 10 Mbit 7-wire interface mode. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 63 Figure 41 shows MII asynchronous input timings listed in Table 50. FEC_CRS, FEC_COL M9 Figure 41. MII Asynch Inputs Timing Diagram 4.9.8.5 MII Serial Management Channel Timing Serial management channel timing is accomplished using FEC_MDIO and FEC_MDC. The FEC functions correctly with a maximum MDC frequency of 2.5 MHz. Table 51 lists MII serial management channel timings. The MDC frequency should be equal to or less than 2.5 MHz to be compliant with the IEEE 802.3 MII specification. However the FEC can function correctly with a maximum MDC frequency of 15 MHz. Table 51. MII Transmit Signal Timing Num Characteristic Min. Max. Units M10 FEC_MDC falling edge to FEC_MDIO output invalid (minimum propagation delay) 0 — ns M11 FEC_MDC falling edge to FEC_MDIO output valid (max. propagation delay) — 5 ns M12 FEC_MDIO (input) to FEC_MDC rising edge setup 18 — ns M13 FEC_MDIO (input) to FEC_MDC rising edge hold 0 — ns M14 FEC_MDC pulse width high 40% 60% FEC_MDC period M15 FEC_MDC pulse width low 40% 60% FEC_MDC period i.MX35 Applications Processors for Automotive Products, Rev. 10 64 Freescale Semiconductor Figure 42 shows MII serial management channel timings listed in Table 51. M14 M15 FEC_MDC (output) M10 FEC_MDIO (output) M11 FEC_MDIO (input) M12 M13 Figure 42. MII Serial Management Channel Timing Diagram 4.9.9 FIR Electrical Specifications FIR implements asynchronous infrared protocols (FIR, MIR) defined by IrDA® (Infrared Data Association). Refer to the IrDA® website for details on FIR and MIR protocols. 4.9.10 FlexCAN Module AC Electrical Specifications The electrical characteristics are related to the CAN transceiver outside the chip. The i.MX35 has two CAN modules available for systems design. Tx and Rx ports for both modules are multiplexed with other I/O pins. Refer to the IOMUX chapter of the MCIMX35 Multimedia Applications Processor Reference Manual to see which pins expose Tx and Rx pins; these ports are named TXCAN and RXCAN, respectively. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 65 4.9.11 I2C AC Electrical Specifications This section describes the electrical characteristics of the I2C module. 4.9.11.1 I2C Module Timing Figure 43 depicts the timing of the I2C module. Table 52 lists the I2C module timing parameters. I2CLK IC11 IC10 I2DAT IC2 START IC7 IC4 IC8 IC10 IC11 IC6 IC9 IC3 STOP START START IC5 IC1 Figure 43. I2C Bus Timing Diagram Table 52. I2C Module Timing Parameters ID 1 2 3 Standard Mode Fast Mode Min. Max. Min. Max. Parameter Unit IC1 I2CLK cycle time 10 — 2.5 — μs IC2 Hold time (repeated) START condition 4.0 — 0.6 — μs IC3 Set-up time for STOP condition 4.0 — 0.6 — μs IC4 Data hold time 01 3.452 01 0.92 μs IC5 HIGH Period of I2CLK Clock 4.0 — 0.6 — μs IC6 LOW Period of the I2CLK Clock 4.7 — 1.3 — μs IC7 Set-up time for a repeated START condition 4.7 — 0.6 — μs IC8 Data set-up time 250 — 1003 — ns IC9 Bus free time between a STOP and START condition 4.7 — 1.3 — μs IC10 Rise time of both I2DAT and I2CLK signals — 1000 — 300 ns IC11 Fall time of both I2DAT and I2CLK signals — 300 — 300 ns IC12 Capacitive load for each bus line (Cb) — 400 — 400 pF A device must internally provide a hold time of at least 300 ns for the I2DAT signal in order to bridge the undefined region of the falling edge of I2CLK. The maximum hold time has to be met only if the device does not stretch the LOW period (ID IC6) of the I2CLK signal. A fast-mode I2C-bus device can be used in a standard-mode I2C-bus system, but the requirement of set-up time (ID IC7) of 250 ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the I2CLK signal. If such a device does stretch the LOW period of the I2CLK signal, it must output the next data bit to the I2DAT line max_rise_time (ID No IC10) + data_setup_time (ID No IC8) = 1000 + 250 = 1250 ns (according to the Standard-mode I2C-bus specification) before the I2CLK line is released. i.MX35 Applications Processors for Automotive Products, Rev. 10 66 Freescale Semiconductor 4.9.12 IPU—Sensor Interfaces This section contains a list of supported camera sensors, a functional description, and the electrical characteristics. 4.9.12.1 Supported Camera Sensors Table 53 lists the known supported camera sensors at the time of publication. Table 53. Supported Camera Sensors1 Vendor Model Conexant CX11646, CX204902, CX204502 Agilant HDCP–2010, ADCS–10212, ADCS–10212 Toshiba TC90A70 ICMedia ICM202A, ICM1022 iMagic IM8801 Transchip TC5600, TC5600J, TC5640, TC5700, TC6000 Fujitsu MB86S02A Micron MI-SOC–0133 Matsushita MN39980 STMicro W6411, W6500, W65012, W66002, W65522, STV09742 OmniVision OV7620, OV6630, OV2640 Sharp LZ0P3714 (CCD) Motorola MC30300 (Python)2, SCM200142, SCM201142, SCM221142, SCM200272 National Semiconductor LM96182 1 2 Freescale Semiconductor does not recommend one supplier over another and in no way suggests that these are the only camera suppliers. These sensors have not been validated at the time of publication. 4.9.12.2 Functional Description There are three timing modes supported by the IPU. 4.9.12.2.1 Pseudo BT.656 Video Mode Smart camera sensors, which typically include image processing capability, support video mode transfer operations. They use an embedded timing syntax to replace the SENSB_VSYNC and SENSB_HSYNC signals. The timing syntax is defined by the BT.656 standard. This operation mode follows the recommendations of the ITU BT.656 specifications. The only control signal used is SENSB_PIX_CLK. Start-of-frame and active-line signals are embedded in the data stream. An active line starts with a SAV code and ends with an EAV code. In some cases, digital blanking is i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 67 inserted in between EAV and SAV code. The CSI decodes and filters out the timing coding from the data stream, thus recovering SENSB_VSYNC and SENSB_HSYNC signals for internal use. 4.9.12.2.2 Gated Clock Mode The SENSB_VSYNC, SENSB_HSYNC, and SENSB_PIX_CLK signals are used in this mode. See Figure 44. Active Line Start of Frame nth frame n+1th frame SENSB_VSYNC SENSB_HSYNC SENSB_PIX_CLK invalid SENSB_DATA[9:0] invalid 1st byte 1st byte Figure 44. Gated Clock Mode Timing Diagram A frame starts with a rising edge on SENSB_VSYNC (all the timing corresponds to straight polarity of the corresponding signals). Then SENSB_HSYNC goes to high and hold for the entire line. The pixel clock is valid as long as SENSB_HSYNC is high. Data is latched at the rising edge of the valid pixel clocks. SENSB_HSYNC goes to low at the end of the line. Pixel clocks then become invalid and the CSI stops receiving data from the stream. For the next line, the SENSB_HSYNC timing repeats. For the next frame, the SENSB_VSYNC timing repeats. 4.9.12.2.3 Non-Gated Clock Mode The timing is the same as the gated-clock mode (described in Section 4.9.12.2.2, “Gated Clock Mode”), except for the SENSB_HSYNC signal, which is not used. See Figure 45. All incoming pixel clocks are valid and will cause data to be latched into the input FIFO. The SENSB_PIX_CLK signal is inactive (states low) until valid data is going to be transmitted over the bus. Start of Frame nth frame n+1th frame SENSB_VSYNC SENSB_PIX_CLK SENSB_DATA[7:0] invalid invalid 1st byte 1st byte Figure 45. Non-Gated Clock Mode Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 68 Freescale Semiconductor The timing described in Figure 45 is that of a Motorola sensor. Some other sensors may have slightly different timing. The CSI can be programmed to support rising/falling-edge triggered SENSB_VSYNC; active-high/low SENSB_HSYNC; and rising/falling-edge triggered SENSB_PIX_CLK. 4.9.12.3 Electrical Characteristics Figure 46 depicts the sensor interface timing, and Table 54 lists the timing parameters. 1/IP1 SENSB_MCLK (Sensor Input) SENSB_PIX_CLK (Sensor Output) IP3 IP2 1/IP4 SENSB_DATA, SENSB_VSYNC, SENSB_HSYNC Figure 46. Sensor Interface Timing Diagram Table 54. Sensor Interface Timing Parameters ID Parameter Symbol Min. Max. Units IP1 Sensor input clock frequency Fmck 0.01 133 MHz IP2 Data and control setup time Tsu 5 — ns IP3 Data and control holdup time Thd 3 — ns IP4 Sensor output (pixel) clock frequency Fpck 0.01 133 MHz 4.9.13 IPU—Display Interfaces This section describes the following types of display interfaces: • Section 4.9.13.1, “Synchronous Interfaces” • Section 4.9.13.2, “Interface to Sharp HR-TFT Panels” • Section 4.9.13.3, “Synchronous Interface to Dual-Port Smart Displays” • Section 4.9.13.4, “Asynchronous Interfaces” • Section 4.9.13.5, “Serial Interfaces, Functional Description” i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 69 4.9.13.1 Synchronous Interfaces This section discusses the interfaces to active matrix TFT LCD panels, Sharp HR-TFT, and dual-port smart displays. 4.9.13.1.4 Interface to Active Matrix TFT LCD Panels, Functional Description Figure 47 depicts the LCD interface timing for a generic active matrix color TFT panel. In this figure, signals are shown with negative polarity. The sequence of events for active matrix interface timing is as follows: • DISPB_D3_CLK latches data into the panel on its negative edge (when positive polarity is selected). In active mode, DISPB_D3_CLK runs continuously. • DISPB_D3_HSYNC causes the panel to start a new line. • DISPB_D3_VSYNC causes the panel to start a new frame. It always encompasses at least one HSYNC pulse. • DISPB_D3_DRDY acts like an output enable signal to the CRT display. This output enables the data to be shifted to the display. When disabled, the data is invalid and the trace is off. DISPB_D3_VSYNC DISPB_D3_HSYNC LINE 1 LINE 2 LINE 3 LINE 4 LINE n – 1 LINE n DISPB_D3_HSYNC DISPB_D3_DRDY 1 2 3 m–1 m DISPB_D3_CLK DISPB_D3_DATA Figure 47. Interface Timing Diagram for TFT (Active Matrix) Panels 4.9.13.1.5 Interface to Active Matrix TFT LCD Panels, Electrical Characteristics Figure 48 depicts the horizontal timing (timing of one line), including both the horizontal sync pulse and the data. All figure parameters shown are programmable. The timing images correspond to inverse polarity i.MX35 Applications Processors for Automotive Products, Rev. 10 70 Freescale Semiconductor of the DISPB_D3_CLK signal and active-low polarity of the DISPB_D3_HSYNC, DISPB_D3_VSYNC and DISPB_D3_DRDY signals. IP7 IP6 IP9 IP10 IP8 Start of line IP5 DISPB_D3_CLK DISPB_D3_HSYNC DISPB_D3_DRDY DISPB_D3_DATA Figure 48. TFT Panels Timing Diagram—Horizontal Sync Pulse Figure 49 depicts the vertical timing (timing of one frame). All figure parameters shown are programmable. End of frame Start of frame IP13 DISPB_D3_VSYNC DISPB_D3_HSYNC DISPB_D3_DRDY IP11 IP15 IP14 IP12 Figure 49. TFT Panels Timing Diagram—Vertical Sync Pulse Table 55 shows timing parameters of signals presented in Figure 48 and Figure 49. Table 55. Synchronous Display Interface Timing Parameters—Pixel Level ID Parameter Symbol Value Units IP5 Display interface clock period Tdicp Tdicp1 ns IP6 Display pixel clock period Tdpcp (DISP3_IF_CLK_CNT_D + 1) × Tdicp ns IP7 Screen width Tsw (SCREEN_WIDTH + 1) × Tdpcp ns IP8 HSYNC width Thsw (H_SYNC_WIDTH + 1) × Tdpcp ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 71 Table 55. Synchronous Display Interface Timing Parameters—Pixel Level (continued) ID 1 Parameter Symbol Value Units IP9 Horizontal blank interval 1 Thbi1 BGXP × Tdpcp ns IP10 Horizontal blank interval 2 Thbi2 (SCREEN_WIDTH – BGXP – FW) × Tdpcp ns IP11 HSYNC delay Thsd H_SYNC_DELAY × Tdpcp ns IP12 Screen height Tsh (SCREEN_HEIGHT + 1) × Tsw ns IP13 VSYNC width Tvsw if V_SYNC_WIDTH_L = 0 than (V_SYNC_WIDTH + 1) × Tdpcp else (V_SYNC_WIDTH + 1) × Tsw ns IP14 Vertical blank interval 1 Tvbi1 BGYP × Tsw ns IP15 Vertical blank interval 2 Tvbi2 (SCREEN_HEIGHT – BGYP – FH) × Tsw ns Display interface clock period immediate value Display interface clock period average value. DISP3_IF_CLK_PER_WR Tdicp = T HSP_CLK ⋅ -----------------------------------------------------------------HSP_CLK_PERIOD Figure 50 depicts the synchronous display interface timing for access level, and Table 56 lists the timing parameters. The DISP3_IF_CLK_DOWN_WR and DISP3_IF_CLK_UP_WR parameters are set via the DI_DISP3_TIME_CONF Register. IP20 DISPB_D3_VSYNC DISPB_D3_HSYNC DISPB_D3_DRDY other controls DISPB_D3_CLK IP16 IP17 IP19 IP18 DISPB_DATA Figure 50. Synchronous Display Interface Timing Diagram—Access Level i.MX35 Applications Processors for Automotive Products, Rev. 10 72 Freescale Semiconductor Table 56. Synchronous Display Interface Timing Parameters—Access Level ID Parameter Symbol Typ.1 Min. Max. Units IP16 Display interface clock low time Tckl Tdicd – Tdicu – 1.5 Tdicd2 – Tdicu3 Tdicd – Tdicu + 1.5 ns IP17 Display interface clock high time Tckh Tdicp – Tdicd + Tdicu – 1.5 Tdicp – Tdicd + Tdicu Tdicp – Tdicd + Tdicu + 1.5 ns IP18 Data setup time Tdsu Tdicd – 3.5 Tdicu — ns IP19 Data holdup time Tdhd Tdicp – Tdicd – 3.5 Tdicp – Tdicu — ns IP20 Control signals setup time to display interface clock Tcsu Tdicd – 3.5 Tdicu — ns 1 2 The exact conditions have not been finalized, but will likely match the current customer requirement for their specific display. These conditions may be device specific. Display interface clock down time 1 2 ⋅ DISP3_IF_CLK_DOWN_WR Tdicd = --- T HSP_CLK ⋅ ceil --------------------------------------------------------------------------------2 HSP_CLK_PERIOD 3 Display interface clock up time 1 2 ⋅ DISP3_IF_CLK_UP_WR Tdicu = --- T HSP_CLK ⋅ ceil ---------------------------------------------------------------------2 HSP_CLK_PERIOD where CEIL(X) rounds the elements of X to the nearest integers toward infinity. 4.9.13.2 Interface to Sharp HR-TFT Panels Figure 51 depicts the Sharp HR-TFT panel interface timing, and Table 57 lists the timing parameters. The CLS_RISE_DELAY, CLS_FALL_DELAY, PS_FALL_DELAY, PS_RISE_DELAY, REV_TOGGLE_DELAY parameters are defined in the SDC_SHARP_CONF_1 and SDC_SHARP_CONF_2 registers. For other Sharp interface timing characteristics, refer to i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 73 Section 4.9.13.1.5, “Interface to Active Matrix TFT LCD Panels, Electrical Characteristics.” The timing images correspond to straight polarity of the Sharp signals. Horizontal timing DISPB_D3_CLK D1 D2 DISPB_D3_DATA DISPB_D3_SPL IP21 D320 1 DISPB_D3_CLK period DISPB_D3_HSYNC IP23 IP22 DISPB_D3_CLS IP24 DISPB_D3_PS IP25 IP26 DISPB_D3_REV Example is drawn with FW + 1 = 320 pixel/line, FH + 1 = 240 lines. SPL pulse width is fixed and aligned to the first data of the line. REV toggles every HSYNC period. Figure 51. Sharp HR-TFT Panel Interface Timing Diagram—Pixel Level Table 57. Sharp Synchronous Display Interface Timing Parameters—Pixel Level ID Parameter Symbol Value Units IP21 SPL rise time Tsplr (BGXP – 1) × Tdpcp ns IP22 CLS rise time Tclsr CLS_RISE_DELAY × Tdpcp ns IP23 CLS fall time Tclsf CLS_FALL_DELAY × Tdpcp ns IP24 CLS rise and PS fall time Tpsf PS_FALL_DELAY × Tdpcp ns IP25 PS rise time Tpsr PS_RISE_DELAY × Tdpcp ns IP26 REV toggle time Trev REV_TOGGLE_DELAY × Tdpcp ns i.MX35 Applications Processors for Automotive Products, Rev. 10 74 Freescale Semiconductor 4.9.13.3 Synchronous Interface to Dual-Port Smart Displays Functionality and electrical characteristics of the synchronous interface to dual-port smart displays are identical to parameters of the synchronous interface. See Section 4.9.13.1.5, “Interface to Active Matrix TFT LCD Panels, Electrical Characteristics.” 4.9.13.3.6 Interface to a TV Encoder—Functional Description The interface has an 8-bit data bus, transferring a single 8-bit value (Y/U/V) in each cycle. The bits D7–D0 of the value are mapped to bits LD17–LD10 of the data bus, respectively. Figure 52 depicts the interface timing. • The frequency of the clock DISPB_D3_CLK is 27 MHz. • The DISPB_D3_HSYNC, DISPB_D3_VSYNC and DISPB_D3_DRDY signals are active low. • The transition to the next row is marked by the negative edge of the DISPB_D3_HSYNC signal. It remains low for a single clock cycle. • The transition to the next field/frame is marked by the negative edge of the DISPB_D3_VSYNC signal. It remains low for at least one clock cycle. — At a transition to an odd field (of the next frame), the negative edges of DISPB_D3_VSYNC and DISPB_D3_HSYNC coincide. — At a transition to an even field (of the same frame), they do not coincide. • The active intervals—during which data is transferred—are marked by the DISPB_D3_HSYNC signal being high. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 75 DISPB_D3_CLK DISPB_D3_HSYNC DISPB_D3_VSYNC DISPB_D3_DRDY DISPB_DATA Cb Y Cr Y Cb Y Cr Pixel Data Timing DISPB_D3_HSYNC 523 524 525 1 2 3 5 4 6 10 DISPB_D3_DRDY DISPB_D3_VSYNC Even Field 261 262 Odd Field 263 264 265 266 267 268 269 273 DISPB_D3_HSYNC DISPB_D3_DRDY DISPB_D3_VSYNC Even Field Odd Field Line and Field Timing - NTSC DISPB_D3_HSYNC 621 622 623 624 625 1 3 2 4 23 DISPB_D3_DRDY DISPB_D3_VSYNC Even Field 308 309 Odd Field 310 311 312 313 314 315 316 336 DISPB_D3_HSYNC DISPB_D3_DRDY DISPB_D3_VSYNC Even Field Odd Field Line and Field Timing - PAL Figure 52. TV Encoder Interface Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 76 Freescale Semiconductor 4.9.13.3.7 Interface to a TV Encoder, Electrical Characteristics The timing characteristics of the TV encoder interface are identical to the synchronous display characteristics. See Section 4.9.13.1.5, “Interface to Active Matrix TFT LCD Panels, Electrical Characteristics.” 4.9.13.4 Asynchronous Interfaces This section discusses the asynchronous parallel and serial interfaces. 4.9.13.4.8 Parallel Interfaces, Functional Description The IPU supports the following asynchronous parallel interfaces: • System 80 interface — Type 1 (sampling with the chip select signal) with and without byte enable signals. — Type 2 (sampling with the read and write signals) with and without byte enable signals. • System 68k interface — Type 1 (sampling with the chip select signal) with or without byte enable signals. — Type 2 (sampling with the read and write signals) with or without byte enable signals. For each of four system interfaces, there are three burst modes: 1. Burst mode without a separate clock—The burst length is defined by the corresponding parameters of the IDMAC (when data is transferred from the system memory) or by the HBURST signal (when the MCU directly accesses the display via the slave AHB bus). For system 80 and system 68k type 1 interfaces, data is sampled by the CS signal and other control signals change only when transfer direction is changed during the burst. For type 2 interfaces, data is sampled by the WR/RD signals (system 80) or by the ENABLE signal (system 68k), and the CS signal stays active during the whole burst. 2. Burst mode with the separate clock DISPB_BCLK—In this mode, data is sampled with the DISPB_BCLK clock. The CS signal stays active during whole burst transfer. Other controls are changed simultaneously with data when the bus state (read, write or wait) is altered. The CS signals and other controls move to non-active state after burst has been completed. 3. Single access mode—In this mode, slave AHB and DMA burst are broken to single accesses. The data is sampled with CS or other controls according to the interface type as described above. All controls (including CS) become non-active for one display interface clock after each access. This mode corresponds to the ATI single access mode. Both system 80 and system 68k interfaces are supported for all described modes as depicted in Figure 53, Figure 54, Figure 55, and Figure 56. These timing images correspond to active-low DISPB_Dn_CS, DISPB_Dn_WR and DISPB_Dn_RD signals. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 77 Additionally, the IPU allows a programmable pause between two bursts. The pause is defined in the HSP_CLK cycles. It allows the prevention of timing violation between two sequential bursts or two accesses to different displays. The range of this pause is from 4 to 19 HSP_CLK cycles. DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Burst access mode with sampling by CS signal DISPB_BCLK DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Burst access mode with sampling by separate burst clock (BCLK) DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Single access mode (all control signals are not active for one display interface clock after each display access) Figure 53. Asynchronous Parallel System 80 Interface (Type 1) Burst Mode Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 78 Freescale Semiconductor DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Burst access mode with sampling by WR/RD signals DISPB_BCLK DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Burst access mode with sampling by separate burst clock (BCLK) DISPB_D#_CS DISPB_PAR_RS DISPB_WR DISPB_RD DISPB_DATA Single access mode (all control signals are not active for one display interface clock after each display access) Figure 54. Asynchronous Parallel System 80 Interface (Type 2) Burst Mode Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 79 DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Burst access mode with sampling by CS signal DISPB_BCLK DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Burst access mode with sampling by separate burst clock (BCLK) DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Single access mode (all control signals are not active for one display interface clock after each display access) Figure 55. Asynchronous Parallel System 68k Interface (Type 1) Burst Mode Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 80 Freescale Semiconductor DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Burst access mode with sampling by ENABLE signal DISPB_BCLK DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Burst access mode with sampling by separate burst clock (BCLK) DISPB_D#_CS DISPB_PAR_RS DISPB_WR (READ/WRITE) DISPB_RD (ENABLE) DISPB_DATA Single access mode (all control signals are not active for one display interface clock after each display access) Figure 56. Asynchronous Parallel System 68k Interface (Type 2) Burst Mode TIming Diagram Display read operation can be performed with wait states when each read access takes up to 4 display interface clock cycles according to the DISP0_RD_WAIT_ST parameter in the i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 81 DI_DISPn_TIME_CONF_3 registers (n = 0,1,2). Figure 57 shows the timing of the parallel interface with read wait states. WRITE OPERATION READ OPERATION DISP0_RD_WAIT_ST=00 DISPB_D#_CS DISPB_RD DISPB_WR DISPB_PAR_RS DISPB_DATA DISP0_RD_WAIT_ST=01 DISPB_D#_CS DISPB_RD DISPB_WR DISPB_PAR_RS DISPB_DATA DISP0_RD_WAIT_ST=10 DISPB_D#_CS DISPB_RD DISPB_WR DISPB_PAR_RS DISPB_DATA Figure 57. Parallel Interface Timing Diagram—Read Wait States 4.9.13.4.9 Parallel Interfaces, Electrical Characteristics Figure 58, Figure 60, Figure 59, and Figure 61 depict timing of asynchronous parallel interfaces based on the system 80 and system 68k interfaces. Table 58 lists the timing parameters at display access level. All i.MX35 Applications Processors for Automotive Products, Rev. 10 82 Freescale Semiconductor timing images are based on active low control signals (signal polarity is controlled via the DI_DISP_SIG_POL register). IP28, IP27 DISPB_PAR_RS DISPB_RD (READ_L) DISPB_DATA[17] (READ_H) IP35, IP33 IP36, IP34 DISPB_D#_CS DISPB_WR (WRITE_L) DISPB_DATA[16] (WRITE_H) IP31, IP29 IP32, IP30 read point IP38 IP37 DISPB_DATA (Input) Read Data IP40 IP39 DISPB_DATA (Output) IP46,IP44 IP47 IP45, IP43 IP42, IP41 Figure 58. Asynchronous Parallel System 80 Interface (Type 1) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 83 IP28, IP27 DISPB_PAR_RS DISPB_D#_CS IP35, IP33 IP36, IP34 DISPB_RD (READ_L) DISPB_DATA[17] (READ_H) DISPB_WR (WRITE_L) DISPB_DATA[16] (WRITE_H) IP31, IP29 IP32, IP30 read point IP37 DISPB_DATA (Input) IP38 Read Data IP39 IP40 DISPB_DATA (Output) IP46,IP44 IP47 IP45, IP43 IP42, IP41 Figure 59. Asynchronous Parallel System 80 Interface (Type 2) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 84 Freescale Semiconductor IP28, IP27 DISPB_PAR_RS DISPB_RD (ENABLE_L) DISPB_DATA[17] (ENABLE_H) IP35,IP33 IP36, IP34 DISPB_D#_CS DISPB_WR (READ/WRITE) IP31, IP29 IP32, IP30 read point IP37 DISPB_DATA (Input) IP38 Read Data IP39 IP40 DISPB_DATA (Output) IP46,IP44 IP47 IP45, IP43 IP42, IP41 Figure 60. Asynchronous Parallel System 68k Interface (Type 1) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 85 IP28, IP27 DISPB_PAR_RS DISPB_D#_CS IP35,IP33 IP36, IP34 DISPB_RD (ENABLE_L) DISPB_DATA[17] (ENABLE_H) DISPB_WR (READ/WRITE) IP32, IP30 IP31, IP29 read point IP38 IP37 DISPB_DATA (Input) Read Data IP39 IP40 DISPB_DATA (Output) IP46,IP44 IP47 IP45, IP43 IP42, IP41 Figure 61. Asynchronous Parallel System 68k Interface (Type 2) Timing Diagram Table 58. Asynchronous Parallel Interface Timing Parameters—Access Level ID Parameter Symbol IP27 Read system cycle time IP28 Write system cycle time Tcycr Tcycw Min. Typ.1 Tdicpr – 1.5 Tdicpr2 Tdicpw – 1.5 Tdicpw3 Max. 5 Units Tdicpr + 1.5 ns Tdicpw + 1.5 ns Tdicdr – Tdicur + 1.5 ns IP29 Read low pulse width Trl Tdicdr – Tdicur – 1.5 Tdicdr4 IP30 Read high pulse width Trh Tdicpr – Tdicdr + Tdicur – 1.5 Tdicpr – Tdicdr + Tdicpr – Tdicdr + Tdicur Tdicur + 1.5 ns IP31 Write low pulse width Twl Tdicdw – Tdicuw – 1.5 Tdicdw6 – Tdicuw7 ns IP32 Write high pulse width Twh Tdicpw – Tdicdw + Tdicuw – 1.5 Tdicpw – Tdicdw Tdicpw – Tdicdw + + Tdicuw Tdicuw + 1.5 ns – Tdicur Tdicdw – Tdicuw + 1.5 IP33 Controls setup time for read Tdcsr Tdicur – 1.5 Tdicur — ns IP34 Controls hold time for read Tdchr Tdicpr – Tdicdr – 1.5 Tdicpr – Tdicdr — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 86 Freescale Semiconductor Table 58. Asynchronous Parallel Interface Timing Parameters—Access Level (continued) ID Parameter Symbol Typ.1 Min. Max. Units IP35 Controls setup time for write Tdcsw Tdicuw – 1.5 Tdicuw — ns IP36 Controls hold time for write Tdchw Tdicpw – Tdicdw – 1.5 Tdicpw – Tdicdw — ns IP37 Slave device data delay8 Tracc 0 — Tdrp9 – Tlbd10 – Tdicur – 1.5 ns IP38 Slave device data hold time8 Troh Tdrp – Tlbd – Tdicdr + 1.5 — Tdicpr – Tdicdr – 1.5 ns IP39 Write data setup time Tds Tdicdw – 1.5 Tdicdw — ns IP40 Write data hold time Tdh Tdicpw – Tdicdw – 1.5 Tdicpw – Tdicdw — ns Tdicpr – 1.5 Tdicpr Tdicpr + 1.5 ns Tdicpw Tdicpw – 1.5 Tdicpw Tdicpw + 1.5 ns Tdicdr Tdicdr – 1.5 Tdicdr Tdicdr + 1.5 ns Tdicur Tdicur – 1.5 Tdicur Tdicur + 1.5 ns Tdicdw Tdicdw – 1.5 Tdicdw Tdicdw + 1.5 ns Tdicuw Tdicuw – 1.5 Tdicuw Tdicuw + 1.5 ns Tdrp Tdrp + 1.5 ns IP41 Read period2 Tdicpr IP42 Write period3 IP43 Read down time4 5 IP44 Read up time IP45 Write down IP46 Write up time6 time7 IP47 Read time point9 Tdrp Tdrp – 1.5 1The exact conditions have not been finalized, but will likely match the current customer requirement for their specific display. These conditions may be device-specific. 2 Display interface clock period value for read: DISP#_IF_CLK_PER_RD Tdicpr = T HSP_CLK ⋅ ceil ---------------------------------------------------------------HSP_CLK_PERIOD 3 Display interface clock period value for write: DISP#_IF_CLK_PER_WR Tdicpw = T HSP_CLK ⋅ ceil -----------------------------------------------------------------HSP_CLK_PERIOD 4 Display interface clock down time for read: 1 2 ⋅ DISP#_IF_CLK_DOWN_RD Tdicdr = --- T HSP_CLK ⋅ ceil ------------------------------------------------------------------------------2 HSP_CLK_PERIOD 5 Display interface clock up time for read: 1 2 ⋅ DISP#_IF_CLK_UP_RD Tdicur = --- T HSP_CLK ⋅ ceil -------------------------------------------------------------------2 HSP_CLK_PERIOD 6 Display interface clock down time for write: 1 2 ⋅ DISP#_IF_CLK_DOWN_WR Tdicdw = --- T ⋅ ceil --------------------------------------------------------------------------------2 HSP_CLK HSP_CLK_PERIOD 7 Display interface clock up time for write: 1 2 ⋅ DISP#_IF_CLK_UP_WR Tdicuw = --- T HSP_CLK ⋅ ceil ---------------------------------------------------------------------2 HSP_CLK_PERIOD 8 This parameter is a requirement to the display connected to the IPU i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 87 9 Data read point Tdrp = T 10 HSP_CLK DISP#_READ_EN ⋅ ceil -------------------------------------------------HSP_CLK_PERIOD Loopback delay Tlbd is the cumulative propagation delay of read controls and read data. It includes an IPU output delay, a device – level output delay, board delays, a device – level input delay, an IPU input delay. This value is device specific. The following parameters are programmed via the DI_DISP#_TIME_CONF_1, DI_DISP#_TIME_CONF_2, and DI_HSP_CLK_PER registers: • DISP#_IF_CLK_PER_WR, DISP#_IF_CLK_PER_RD • HSP_CLK_PERIOD • DISP#_IF_CLK_DOWN_WR • DISP#_IF_CLK_UP_WR • DISP#_IF_CLK_DOWN_RD • DISP#_IF_CLK_UP_RD • DISP#_READ_EN 4.9.13.5 Serial Interfaces, Functional Description The IPU supports the following types of asynchronous serial interfaces: • 3-wire (with bidirectional data line) • 4-wire (with separate data input and output lines) • 5-wire type 1 (with sampling RS by the serial clock) • 5-wire type 2 (with sampling RS by the chip select signal) Figure 62 depicts timing of the 3-wire serial interface. The timing images correspond to active-low DISPB_D#_CS signal and the straight polarity of the DISPB_SD_D_CLK signal. For this interface, a bidirectional data line is used outside the device. The IPU still uses separate input and output data lines (IPP_IND_DISPB_SD_D and IPP_DO_DISPB_SD_D). The I/O mux connects the internal data lines to the bidirectional external line according to the IPP_OBE_DISPB_SD_D signal provided by the IPU. Each data transfer can be preceded by an optional preamble with programmable length and contents. The preamble is followed by read/write (RW) and address (RS) bits. The order of the these bits is programmable. The RW bit can be disabled. The following data can consist of one word or of a whole burst. The interface parameters are controlled by the DI_SER_DISPn_CONF registers (n = 1, 2). i.MX35 Applications Processors for Automotive Products, Rev. 10 88 Freescale Semiconductor DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D RW RS D7 D6 D5 D4 D3 D2 D1 D0 Input or output data Preamble Figure 62. 3-Wire Serial Interface Timing Diagram Figure 63 depicts timing of the 4-wire serial interface. For this interface, there are separate input and output data lines both inside and outside the device. Write DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW RS D7 D6 D5 Preamble D4 D3 D2 D1 D0 Output data DISPB_SD_D (Input) Read DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW RS Preamble DISPB_SD_D (Input) D7 D6 D5 D4 D3 D2 D1 D0 Input data Figure 63. 4-Wire Serial Interface Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 89 Figure 64 depicts timing of the 5-wire serial interface (Type 1). For this interface, a separate RS line is added. When a burst is transmitted within a single active chip select interval, the RS can be changed at boundaries of words. Write DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW D7 D6 D5 Preamble D4 D3 D2 D1 D0 Output data DISPB_SD_D (Input) DISPB_SER_RS Read DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW Preamble DISPB_SD_D (Input) D7 D6 D5 D4 D3 D2 D1 D0 Input data DISPB_SER_RS Figure 64. 5-Wire Serial Interface (Type 1) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 90 Freescale Semiconductor Figure 65 depicts timing of the 5-wire serial interface (Type 2). For this interface, a separate RS line is added. When a burst is transmitted within a single active chip select interval, the RS can be changed at boundaries of words. Write DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW D7 D6 D5 D4 D3 D2 D1 D0 Output data Preamble DISPB_SD_D (Input) DISPB_SER_RS 1 display IF clock cycle Read DISPB_D#_CS 1 display IF clock cycle 1 display IF clock cycle DISPB_SD_D_CLK DISPB_SD_D (Output) RW Preamble DISPB_SD_D (Input) DISPB_SER_RS D7 1 display IF clock cycle D6 D5 D4 D3 D2 D1 D0 Input data Figure 65. 5-Wire Serial Interface (Type 2) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 91 4.9.13.5.10 Serial Interfaces, Electrical Characteristics Figure 66 depicts timing of the serial interface. Table 59 lists the timing parameters at display access level. IP49, IP48 DISPB_SER_RS IP56,IP54 IP57, IP55 DISPB_SD_D_CLK IP51, IP53 IP50, IP52 read point IP59 IP58 DISPB_DATA (Input) Read Data IP60 IP61 DISPB_DATA (Output) IP67,IP65 IP47 IP64, IP66 IP62, IP63 Figure 66. Asynchronous Serial Interface Timing Diagram Table 59. Asynchronous Serial Interface Timing Parameters—Access Level ID Parameter Symbol IP48 Read system cycle time IP49 Write system cycle time Tcycr Tcycw Min. Typ.1 Max. Units Tdicpr – 1.5 Tdicpr2 Tdicpr + 1.5 ns Tdicpw – 1.5 Tdicpw3 Tdicpw + 1.5 ns IP50 Read clock low pulse width Trl Tdicdr – Tdicur – 1.5 Tdicdr4 – Tdicur5 Tdicdr – Tdicur + 1.5 ns IP51 Read clock high pulse width Trh Tdicpr – Tdicdr + Tdicur – 1.5 Tdicpr – Tdicdr + Tdicpr – Tdicdr + Tdicur Tdicur + 1.5 ns IP52 Write clock low pulse width Twl Tdicdw – Tdicuw – 1.5 Tdicdw6 – Tdicuw7 ns IP53 Write clock high pulse width Twh Tdicpw – Tdicdw + Tdicuw – 1.5 Tdicpw – Tdicdw Tdicpw – Tdicdw + + Tdicuw Tdicuw + 1.5 ns IP54 Controls setup time for read Tdcsr Tdicur – 1.5 Tdicur ns Tdicdw – Tdicuw + 1.5 — i.MX35 Applications Processors for Automotive Products, Rev. 10 92 Freescale Semiconductor Table 59. Asynchronous Serial Interface Timing Parameters—Access Level (continued) ID Parameter Symbol Typ.1 Min. Max. Units IP55 Controls hold time for read Tdchr Tdicpr – Tdicdr – 1.5 Tdicpr – Tdicdr — ns IP56 Controls setup time for write Tdcsw Tdicuw – 1.5 Tdicuw — ns IP57 Controls hold time for write Tdchw Tdicpw – Tdicdw – 1.5 Tdicpw – Tdicdw — ns IP58 Slave device data delay8 9 10 Tracc 0 — Tdrp – Tlbd – 1.5 IP59 Slave device data hold time8 Troh Tdrp – Tlbd – Tdicdr + 1.5 — Tdicpr – Tdicdr – 1.5 IP60 Write data setup time Tds Tdicdw – 1.5 Tdicdw — ns IP61 Write data hold time Tdh Tdicpw – Tdicdw – 1.5 Tdicpw – Tdicdw — ns Tdicpr – 1.5 Tdicpr Tdicpr + 1.5 ns Tdicpw Tdicpw – 1.5 Tdicpw Tdicpw + 1.5 ns Tdicdr Tdicdr – 1.5 Tdicdr Tdicdr + 1.5 ns Tdicur Tdicur – 1.5 Tdicur Tdicur + 1.5 ns Tdicdw Tdicdw – 1.5 Tdicdw Tdicdw + 1.5 ns Tdicuw Tdicuw – 1.5 Tdicuw Tdicuw + 1.5 ns Tdrp Tdrp + 1.5 ns IP62 Read period2 Tdicpr IP63 Write period3 IP64 Read down time IP65 Read up 4 time5 IP66 Write down time6 IP67 Write up time7 IP68 Read time 1 2 Tdrp – 1.5 ns HSP_CLK DISP#_IF_CLK_PER_RD ⋅ ceil ---------------------------------------------------------------HSP_CLK_PERIOD Display interface clock period value for write: Tdicpw = T 4 Tdrp ns The exact conditions have not been finalized, but will likely match the current customer requirement for their specific display. These conditions may be device specific. Display interface clock period value for read: Tdicpr = T 3 point9 – Tdicur HSP_CLK DISP#_IF_CLK_PER_WR ⋅ ceil -----------------------------------------------------------------HSP_CLK_PERIOD Display interface clock down time for read: 1 2 ⋅ DISP#_IF_CLK_DOWN_RD Tdicdr = --- T HSP_CLK ⋅ ceil ------------------------------------------------------------------------------2 HSP_CLK_PERIOD 5 Display interface clock up time for read: 1 2 ⋅ DISP#_IF_CLK_UP_RD Tdicur = --- T ⋅ ceil -------------------------------------------------------------------2 HSP_CLK HSP_CLK_PERIOD 6 Display interface clock down time for write: 1 2 ⋅ DISP#_IF_CLK_DOWN_WR Tdicdw = --- T HSP_CLK ⋅ ceil --------------------------------------------------------------------------------2 HSP_CLK_PERIOD 7 Display interface clock up time for write: 1 2 ⋅ DISP#_IF_CLK_UP_WR Tdicuw = --- T ⋅ ceil ---------------------------------------------------------------------2 HSP_CLK HSP_CLK_PERIOD 8 This parameter is a requirement to the display connected to the IPU. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 93 9 Data read point: Tdrp = T 10 HSP_CLK DISP#_READ_EN ⋅ ceil -------------------------------------------------HSP_CLK_PERIOD Loopback delay Tlbd is the cumulative propagation delay of read controls and read data. It includes an IPU output delay, a device-level output delay, board delays, a device-level input delay, and an IPU input delay. This value is device specific. The following parameters are programmed via the DI_DISP#_TIME_CONF_1, DI_DISP#_TIME_CONF_2, and DI_HSP_CLK_PER registers: • DISP#_IF_CLK_PER_WR • DISP#_IF_CLK_PER_RD • HSP_CLK_PERIOD • DISP#_IF_CLK_DOWN_WR • DISP#_IF_CLK_UP_WR • DISP#_IF_CLK_DOWN_RD • DISP#_IF_CLK_UP_RD • DISP#_READ_EN 4.9.14 Memory Stick Host Controller (MSHC) Figure 67, Figure 68, and Figure 69 depict the MSHC timings, and Table 60 and Table 61 list the timing parameters. tSCLKc tSCLKwh tSCLKwl MSHC_SCLK tSCLKr tSCLKf Figure 67. MSHC_CLK Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 94 Freescale Semiconductor tSCLKc MSHC_SCLK tBSsu tBSh MSHC_BS tDsu tDh MSHC_DATA (Output) tDd MSHC_DATA (Intput) Figure 68. Transfer Operation Timing Diagram (Serial) i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 95 tSCLKc MSHC_SCLK tBSsu tBSh MSHC_BS tDsu tDh MSHC_DATA (Output) tDd MSHC_DATA (Input) Figure 69. Transfer Operation Timing Diagram (Parallel) NOTE The memory stick host controller is designed to meet the timing requirements per Sony's Memory Stick Pro Format Specifications. Tables in this section detail the specifications’ requirements for parallel and serial modes, and not the i.MX35 timing. Table 60. Serial Interface Timing Parameters1 Standards Signal MSHC_SCLK MSHC_BS Parameter Symbol Unit Min. Max. Cycle tSCLKc 50 — ns H pulse length tSCLKwh 15 — ns L pulse length tSCLKwl 15 — ns Rise time tSCLKr — 10 ns Fall time tSCLKf — 10 ns Setup time tBSsu 5 — ns Hold time tBSh 5 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 96 Freescale Semiconductor Table 60. Serial Interface Timing Parameters1 (continued) Standards Signal Parameter MSHC_DATA 1 Symbol Unit Min. Max. Setup time tDsu 5 — ns Hold time tDh 5 — ns Output delay time tDd — 15 ns Timing is guaranteed for NVCC from 2.7 V through 3.1 V and up to a maximum overdrive NVCC of 3.3 V. See NVCC restrictions described in Table 61. Table 61. Parallel Interface Timing Parameters1 Standards Signal Parameter MSHC_SCLK Unit Min. Max. Cycle tSCLKc 25 — ns H pulse length tSCLKwh 5 — ns L pulse length tSCLKwl 5 — ns Rise time tSCLKr — 10 ns Fall time tSCLKf — 10 ns Setup time tBSsu 8 — ns Hold time tBSh 1 — ns Setup time tDsu 8 — ns Hold time tDh 1 — ns Output delay time tDd — 15 ns MSHC_BS MSHC_DATA 1 Symbol Timing is guaranteed for NVCC from 2.7 V through 3.1 V and up to a maximum overdrive NVCC of 3.3 V. See the NVCC restrictions described in Table 8. 4.9.15 MediaLB Controller Electrical Specifications This section describes the electrical information of the MediaLB Controller module. Table 62. MLB 256/512 Fs Timing Parameters Parameter Symbol Min MLBCLK operating frequency1 fmck 11.264 Typ Max Units Comment MHz Min: 256 × Fs at 44.0 kHz Typ: 256 × Fs at 48.0 kHz Typ: 512 × Fs at 48.0 kHz Max: 512 × Fs at 48.1 kHz Max: 512 × Fs PLL unlocked ns VIL TO VIH 12.288 24.576 24.6272 25.600 MLBCLK rise time tmckr — — 3 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 97 Table 62. MLB 256/512 Fs Timing Parameters (continued) Parameter Symbol Min Typ Max Units Comment MLB fall time tmckf — — 3 ns VIH TO VIL MLBCLK cycle time tmckc — — 81 40 — — ns 256 × Fs 512 × Fs MLBCLK low time tmckl 31.5 30 37 35.5 — — ns 256 × Fs 256 × Fs PLL unlocked 14.5 14 17 16.5 — — ns 512 × Fs 512 × Fs PLL unlocked 31.5 30 38 36.5 — — ns 256 × Fs 256 × Fs PLL unlocked 14.5 14 17 16.5 — — ns 512 × Fs 512 × Fs PLL unlocked MLBCLK high time tmckh MLBCLK pulse width variation tmpwv — — 2 ns pp Note2 MLBSIG/MLBDAT input valid to MLBCLK falling tdsmcf 1 — — ns — MLBSIG/MLBDAT input hold from MLBCLK low tdhmcf 0 — — ns — MLBSIG/MLBDAT output high impedance from MLBCLK low tmcfdz 0 — tmckl ns — Bus Hold Time tmdzh 4 — — ns Note3 1 2 3 The MLB controller can shut off MLBCLK to place MediaLB in a low-power state. Pulse width variation is measured at 1.25 V by triggering on one edge of MLBCLK and measuring the spread on the other edge, measured in ns peak-to-peak (pp) The board must be designed to insure that the high-impedance bus does not leave the logic state of the final driven bit for this time period. Therefore, coupling must be minimized while meeting the maximum capacitive load listed. Ground = 0.0 V; load capacitance = 40 pF; MediaLB speed = 1024 Fs; Fs = 48 kHz; all timing parameters specified from the valid voltage threshold as listed below unless otherwise noted. Table 63. MLB Device 1024Fs Timing Parameters Parameter Symbol Min MLBCLK Operating Frequency1 fmck 45.056 Typ Max Units Comment MHz Min: 1024 × Fs at 44.0 kHz Typ: 1024 × Fs at 48.0 kHz Max: 1024 × Fs at 48.1 kHz Max: 1024 × Fs PLL unlocked 49.152 49.2544 51.200 MLBCLK rise time tmckr — — 1 ns VIL TO VIH MLB fall time tmckf — — 1 ns VIH TO VIL MLBCLK cycle time tmckc — 20.3 — ns — MLBCLK low time tmckl 6.5 6.1 7.7 7.3 — ns PLL unlocked i.MX35 Applications Processors for Automotive Products, Rev. 10 98 Freescale Semiconductor Table 63. MLB Device 1024Fs Timing Parameters (continued) Parameter Symbol Min Typ Max Units Comment MLBCLK high time tmckh 9.7 9.3 10.6 10.2 — — ns PLL unlocked MLBCLK pulse width variation tmpwv — — 0.7 ns pp Note2 MLBSIG/MLBDAT input valid to MLBCLK falling tdsmcf 1 — — ns — MLBSIG/MLBDAT input hold from MLBCLK low tdhmcf 0 — — ns — MLBSIG/MLBDAT output high impedance from MLBCLK low tmcfdz 0 — tmckl ns — Bus Hold Time tmdzh 2 — — ns Note3 1 2 3 The MLB Controller can shut off MLBCLK to place MediaLB in a low-power state. Pulse width variation is measured at 1.25 V by triggering on one edge of MLBCLK and measuring the spread on the other edge, measured in ns peak-to-peak (pp) The board must be designed to insure that the high-impedance bus does not leave the logic state of the final driven bit for this time period. Therefore, coupling must be minimized while meeting the maximum capacitive load listed. 4.9.16 1-Wire Timing Specifications Figure 70 depicts the RPP timing, and Table 64 lists the RPP timing parameters. 1-WIRE Tx “Reset Pulse” DS2502 Tx “Presence Pulse” OW2 1-Wire bus (BATT_LINE) OW3 OW1 OW4 Figure 70. Reset and Presence Pulses (RPP) Timing Diagram Table 64. RPP Sequence Delay Comparisons Timing Parameters ID Parameters Symbol Min. Typ. Max. Units OW1 Reset time low tRSTL 480 511 — µs OW2 Presence detect high tPDH 15 — 60 µs OW3 Presence detect low tPDL 60 — 240 µs OW4 Reset time high tRSTH 480 512 — µs i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 99 Figure 71 depicts write 0 sequence timing, and Table 65 lists the timing parameters. OW6 1-Wire bus (BATT_LINE) OW5 Figure 71. Write 0 Sequence Timing Diagram Table 65. WR0 Sequence Timing Parameters ID Parameter OW5 Write 0 low time OW6 Transmission time slot Symbol Min. Typ. Max. Units tWR0_low 60 100 120 µs tSLOT OW5 117 120 µs Figure 72 shows write 1 sequence timing, and Figure 73 depicts the read sequence timing. Table 66 lists the timing parameters. OW8 1-Wire bus (BATT_LINE) OW7 Figure 72. Write 1 Sequence Timing Diagram OW8 1-Wire bus (BATT_LINE) OW7 OW9 Figure 73. Read Sequence Timing Diagram Table 66. WR1/RD Timing Parameters ID Parameter Symbol Min. Typ. Max. Units OW7 Write 1/read low time tLOW1 1 5 15 µs OW8 Transmission time slot tSLOT 60 117 120 µs OW9 Release time tRELEASE 15 — 45 µs i.MX35 Applications Processors for Automotive Products, Rev. 10 100 Freescale Semiconductor 4.9.17 Parallel ATA Module AC Electrical Specifications The parallel ATA module can work on PIO/multiword DMA/ultra-DMA transfer modes (not available for the MCIMX351). Each transfer mode has a different data transfer rate, Ultra DMA mode 4 data transfer rate is up to 100 MBps. The parallel ATA module interface consists of a total of 29 pins. Some pins have different functions in different transfer modes. There are various requirements for timing relationships among the function pins, in compliance with the ATA/ATAPI-6 specification, and these requirements are configurable by the ATA module registers. 4.9.17.1 General Timing Requirements Table 67 and Figure 74 define the AC characteristics of the interface signals on all data transfer modes. Table 67. AC Characteristics of All Interface Signals ID 1 Parameter Symbol Min. Max. Unit SI1 Rising edge slew rate for any signal on the ATA interface1 Srise1 — 1.25 V/ns SI2 Falling edge slew rate for any signal on the ATA interface1 Sfall1 — 1.25 V/ns SI3 Host interface signal capacitance at the host connector Chost — 20 pF SRISE and SFALL meet this requirement when measured at the sender’s connector from 10–90% of full signal amplitude with all capacitive loads from 15 pF through 40 pF, where all signals have the same capacitive load value. ATA Interface Signals SI2 SI1 Figure 74. ATA Interface Signals Timing Diagram 4.9.17.2 ATA Electrical Specifications (ATA Bus, Bus Buffers) This section discusses ATA parameters. For a detailed description, refer to the ATA-6 specification. Level shifters are required for 3.3-V or 5.0-V compatibility on the ATA interface. The use of bus buffers introduces delays on the bus and introduces skew between signal lines. These factors make it difficult to operate the bus at the highest speed (UDMA-5) when bus buffers are used. Use of bus buffers is not recommended if fast UDMA mode is required. The ATA specification imposes a slew rate limit on the ATA bus. According to this limit, any signal driven on the bus should have a slew rate between 0.4 and 1.2 V/ns with a 40 pF load. Few vendors of bus buffers specify the slew rate of the outgoing signals. When bus buffers are used the ata_data bus buffer is bidirectional, and uses the direction control signal ata_buffer_en. When ata_buffer_en is asserted, the bus should drive from host to device. When i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 101 ata_buffer_en is negated, the bus drives from device to host. Steering of the signal is such that contention on the host and device tri-state buses is always avoided. 4.9.17.3 Timing Parameters Table 68 shows the parameters used in the timing equations. These parameters depend on the implementation of the ATA interface on silicon, the bus buffer used, the cable delay, and the cable skew. Table 68. ATA Timing Parameters Name T ti_ds ti_dh Value/ Contributing Factor1 Description Bus clock period (ipg_clk_ata) Peripheral clock frequency Set-up time ata_data to ata_iordy edge (UDMA-in only) UDMA0 UDMA1 UDMA2, UDMA3 UDMA4 UDMA5 15 ns 10 ns 7 ns 5 ns 4 ns Hold time ata_iordy edge to ata_data (UDMA-in only) UDMA0, UDMA1, UDMA2, UDMA3, UDMA4 UDMA5 5.0 ns 4.6 ns tco Propagation delay bus clock L-to-H to ata_cs0, ata_cs1, ata_da2, ata_da1, ata_da0, ata_dior, ata_diow, ata_dmack, ata_data, ata_buffer_en 12.0 ns tsu Set-up time ata_data to bus clock L-to-H 8.5 ns tsui Set-up time ata_iordy to bus clock H-to-L 8.5 ns thi Hold time ata_iordy to bus clock H to L 2.5 ns tskew1 Maximum difference in propagation delay bus clock L-to-H to any of following signals ata_cs0, ata_cs1, ata_da2, ata_da1, ata_da0, ata_dior, ata_diow, ata_dmack, ata_data (write), ata_buffer_en 7 ns tskew2 Maximum difference in buffer propagation delay for any of following signals ata_cs0, ata_cs1, ata_da2, ata_da1, ata_da0, ata_dior, ata_diow, ata_dmack, ata_data (write), ata_buffer_en Transceiver tskew3 Maximum difference in buffer propagation delay for any of following signals ata_iordy, ata_data (read) Transceiver tbuf Maximum buffer propagation delay Transceiver tcable1 Cable propagation delay for ata_data Cable tcable2 Cable propagation delay for control signals ata_dior, ata_diow, ata_iordy, ata_dmack Cable tskew4 Maximum difference in cable propagation delay between ata_iordy and ata_data (read) Cable tskew5 Maximum difference in cable propagation delay between (ata_dior, ata_diow, ata_dmack) and ata_cs0, ata_cs1, ata_da2, ata_da1, ata_da0, ata_data(write) Cable tskew6 Maximum difference in cable propagation delay without accounting for ground bounce Cable 1 Values provided where applicable. i.MX35 Applications Processors for Automotive Products, Rev. 10 102 Freescale Semiconductor 4.9.17.4 PIO Mode Timing Figure 75 shows timing for PIO read, and Table 69 lists the timing parameters for PIO read. Figure 75. PIO Read Timing Diagram Table 69. PIO Read Timing Parameters ATA Parameter from Parameter Figure 75 Value Controlling Variable t1 t1 t1 (min.) = time_1 × T – (tskew1 + tskew2 + tskew5) time_1 t2 t2r t2 min.) = time_2r × T – (tskew1 + tskew2 + tskew5) time_2r t9 t9 t9 (min.) = time_9 × T – (tskew1 + tskew2 + tskew6) time_3 t5 t5 t5 (min.) = tco + tsu + tbuf + tbuf + tcable1 + tcable2 If not met, increase time_2 t6 t6 0 tA tA tA (min.) = (1.5 + time_ax) × T – (tco + tsui + tcable2 + tcable2 + 2 × tbuf) trd trd1 t0 — trd1 (max.) = (–trd) + (tskew3 + tskew4) trd1 (min.) = (time_pio_rdx – 0.5) × T – (tsu + thi) (time_pio_rdx – 0.5) × T > tsu + thi + tskew3 + tskew4 t0 (min.) = (time_1 + time_2 + time_9) × T — time_ax time_pio_rdx time_1, time_2r, time_9 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 103 Figure 76 shows timing for PIO write, and Table 70 lists the timing parameters for PIO write. Figure 76. PIO Write Timing Diagram Table 70. PIO Write Timing Parameters ATA Parameter Parameter from Figure 76 t1 t1 t2 t2w t9 t9 t9 (min.) = time_9 × T – (tskew1 + tskew2 + tskew6) t3 — t3 (min.) = (time_2w – time_on) × T – (tskew1 + tskew2 +tskew5) t4 t4 t4 (min.) = time_4 × T – tskew1 time_4 tA tA tA = (1.5 + time_ax) × T – (tco + tsui + tcable2 + tcable2 + 2*tbuf) time_ax t0 — t0(min.) = (time_1 + time_2 + time_9) × T — — Avoid bus contention when switching buffer on by making ton long enough. — — — Avoid bus contention when switching buffer off by making toff long enough. — Controlling Variable Value t1 (min.) = time_1 × T – (tskew1 + tskew2 + tskew5) time_1 t2 (min.) = time_2w × T – (tskew1 + tskew2 + tskew5) time_2w time_9 If not met, increase time_2w time_1, time_2r, time_9 i.MX35 Applications Processors for Automotive Products, Rev. 10 104 Freescale Semiconductor Figure 77 shows timing for MDMA read, and Figure 78 shows timing for MDMA write. Table 71 lists the timing parameters for MDMA read and write. Figure 77. MDMA Read Timing Diagram Figure 78. MDMA Write Timing Diagram Table 71. MDMA Read and Write Timing Parameters ATA Parameter Parameter from Figure 77, Figure 78 tm, ti tm tm (min.) = ti (min.) = time_m × T – (tskew1 + tskew2 + tskew5) time_m td td, td1 td1.(min.) = td (min.) = time_d × T – (tskew1 + tskew2 + tskew6) time_d tk tk tk.(min.) = time_k × T – (tskew1 + tskew2 + tskew6) time_k t0 — t0 (min.) = (time_d + time_k) × T tg(read) tgr tgr (min. – read) = tco + tsu + tbuf + tbuf + tcable1 + tcable2 tgr.(min. – drive) = td – te(drive) tf(read) tfr tfr (min. – drive) = 0 tg(write) — tg (min. – write) = time_d × T – (tskew1 + tskew2 + tskew5) time_d tf(write) — tf (min. – write) = time_k × T – (tskew1 + tskew2 + tskew6) time_k tL — tL (max.) = (time_d + time_k–2) × T – (tsu + tco + 2 × tbuf + 2 × tcable2) Value Controlling Variable time_d, time_k time_d — time_d, time_k i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 105 Table 71. MDMA Read and Write Timing Parameters (continued) ATA Parameter Parameter from Figure 77, Figure 78 tn, tj tkjn tn = tj = tkjn = (max.(time_k,. time_jn) × T – (tskew1 + tskew2 + tskew6) — ton toff ton = time_on × T – tskew1 toff = time_off × T – tskew1 4.9.17.5 Controlling Variable Value time_jn — UDMA-In Timing Figure 79 shows timing when the UDMA-in transfer starts, Figure 80 shows timing when the UDMA-in host terminates transfer, Figure 81 shows timing when the UDMA-in device terminates transfer, and Table 72 lists the timing parameters for the UDMA-in burst. Figure 79. UDMA-In Transfer Starts Timing Diagram Figure 80. UDMA-In Host Terminates Transfer Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 106 Freescale Semiconductor Figure 81. UDMA-In Device Terminates Transfer Timing Diagram Table 72. UDMA-In Burst Timing Parameters ATA Parameter Parameters from Figure 79, Figure 80, Figure 81 tack tack tack (min.) = (time_ack × T) – (tskew1 + tskew2) time_ack tenv tenv tenv (min.) = (time_env × T) – (tskew1 + tskew2) tenv (max.) = (time_env × T) + (tskew1 + tskew2) time_env tds tds1 tds – (tskew3) – ti_ds > 0 tdh tdh1 tdh – (tskew3) – ti_dh > 0 tcyc tc1 (tcyc – tskew > T trp trp trp (min.) = time_rp × T – (tskew1 + tskew2 + tskew6) time_rp time_rp Description Controlling Variable tskew3, ti_ds, ti_dh should be low enough T big enough — tx1 (time_rp × T) – (tco + tsu + 3T + 2 × tbuf + 2 × tcable2) > trfs (drive) tmli tmli1 tmli1 (min.) = (time_mlix + 0.4) × T time_mlix tzah tzah tzah (min.) = (time_zah + 0.4) × T time_zah tdzfs tdzfs tdzfs = (time_dzfs × T) – (tskew1 + tskew2) time_dzfs tcvh tcvh tcvh = (time_cvh × T) – (tskew1 + tskew2) time_cvh — ton toff ton = time_on × T – tskew1 toff = time_off × T – tskew1 1 — 1 There is a special timing requirement in the ATA host that requires the internal DIOW to go high three clocks after the last active edge on the DSTROBE signal. The equation given on this line tries to capture this constraint. 2. Make ton and toff large enough to avoid bus contention. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 107 4.9.17.6 UDMA-Out Timing Figure 82 shows timing when the UDMA-out transfer starts, Figure 83 shows timing when the UDMA-out host terminates transfer, Figure 84 shows timing when the UDMA-out device terminates transfer, and Table 73 lists the timing parameters for the UDMA-out burst. Figure 82. UDMA-Out Transfer Starts Timing Diagram Figure 83. UDMA-Out Host Terminates Transfer Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 108 Freescale Semiconductor Figure 84. UDMA-Out Device Terminates Transfer Timing Diagram Table 73. UDMA-Out Burst Timing Parameters ATA Parameter Parameter from Figure 82, Figure 83, Figure 84 tack tack tack (min.) = (time_ack × T) – (tskew1 + tskew2) time_ack tenv tenv tenv (min.) = (time_env × T) – (tskew1 + tskew2) tenv (max.) = (time_env × T) + (tskew1 + tskew2) time_env tdvs tdvs tdvs = (time_dvs ×T) – (tskew1 + tskew2) time_dvs tdvh tdvh tdvs = (time_dvh × T) – (tskew1 + tskew2) time_dvh tcyc tcyc tcyc = time_cyc × T – (tskew1 + tskew2) time_cyc t2cyc — t2cyc = time_cyc × 2 × T time_cyc trfs1 trfs trfs = 1.6 × T + tsui + tco + tbuf + tbuf — tdzfs tss tss tmli tdzfs_mli tli Value tdzfs = time_dzfs × T – (tskew1) tss = time_ss × T – (tskew1 + tskew2) Controlling Variable — time_dzfs time_ss tdzfs_mli = max. (time_dzfs, time_mli) × T – (tskew1 + tskew2) — tli1 tli1 > 0 — tli tli2 tli2 > 0 — tli tli3 tli3 > 0 — tcvh tcvh tcvh = (time_cvh × T) – (tskew1 + tskew2) — ton toff ton = time_on × T – tskew1 toff = time_off × T – tskew1 time_cvh — i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 109 4.9.18 Parallel Interface (ULPI) Timing Electrical and timing specifications of the parallel interface are presented in the subsequent sections. Table 74. Signal Definitions—Parallel Interface Name Direction Signal Description USB_Clk In Interface clock. All interface signals are synchronous to the clock. USB_Data[7:0] I/O Bidirectional data bus, driven low by the link during idle. Bus ownership is determined by Dir. USB_Dir In Direction. Control the direction of the data bus. USB_Stp Out USB_Nxt In Stop. The link asserts this signal for 1 clock cycle to stop the data stream currently on the bus. Next. The PHY asserts this signal to throttle the data. USB_Clk US15 US16 USB_Stp US15 US16 USB_Data US17 US17 USB_Dir/Nxt Figure 85. USB Transmit/Receive Waveform in Parallel Mode Table 75. USB Timing Specification in VP_VM Unidirectional Mode ID Parameter Min. Max. Unit Conditions / Reference Signal US15 USB_TXOE_B — 6.0 ns 10 pF US16 USB_DAT_VP — 0.0 ns 10 pF US17 USB_SE0_VM — 9.0 ns 10 pF 4.9.19 PWM Electrical Specifications This section describes the electrical information of the PWM. The PWM can be programmed to select one of three clock signals as its source frequency. The selected clock signal is passed through a prescaler before being input to the counter. The output is available at the pulse-width modulator output (PWMO) external i.MX35 Applications Processors for Automotive Products, Rev. 10 110 Freescale Semiconductor pin. The modulated signal of the module is observed at this pin. It can be viewed as a clock signal whose period and duty cycle can be varied with different settings of the PWM. The smallest period is two ipg_clk periods with duty cycle of 50 percent. 4.9.20 SJC Electrical Specifications This section details the electrical characteristics for the SJC module. Figure 86 depicts the SJC test clock input timing. Figure 87 depicts the SJC boundary scan timing, Figure 88 depicts the SJC test access port, Figure 89 depicts the SJC TRST timing, and Table 76 lists the SJC timing parameters. SJ1 SJ2 TCK (Input) SJ2 VM VIH VM VIL SJ3 SJ3 Figure 86. Test Clock Input Timing Diagram TCK (Input) VIH VIL SJ4 Data Inputs SJ5 Input Data Valid SJ6 Data Outputs Output Data Valid SJ7 Data Outputs SJ6 Data Outputs Output Data Valid Figure 87. Boundary Scan (JTAG) Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 111 TCK (Input) VIH VIL SJ8 TDI TMS (Input) SJ9 Input Data Valid SJ10 TDO (Output) Output Data Valid SJ11 TDO (Output) SJ10 TDO (Output) Output Data Valid Figure 88. Test Access Port Timing Diagram TCK (Input) SJ13 TRST (Input) SJ12 Figure 89. TRST Timing Diagram Table 76. SJC Timing Parameters All Frequencies ID Parameter Unit Min. Max. 1001 — ns SJ1 TCK cycle time SJ2 TCK clock pulse width measured at VM2 40 — ns SJ3 TCK rise and fall times — 3 ns SJ4 Boundary scan input data set-up time 10 — ns SJ5 Boundary scan input data hold time 50 — ns SJ6 TCK low to output data valid — 50 ns SJ7 TCK low to output high impedance — 50 ns SJ8 TMS, TDI data set-up time 10 — ns SJ9 TMS, TDI data hold time 50 — ns SJ10 TCK low to TDO data valid — 44 ns i.MX35 Applications Processors for Automotive Products, Rev. 10 112 Freescale Semiconductor Table 76. SJC Timing Parameters (continued) All Frequencies ID 1 2 Parameter Unit Min. Max. — 44 ns SJ11 TCK low to TDO high impedance SJ12 TRST assert time 100 — ns SJ13 TRST set-up time to TCK low 40 — ns On cases where SDMA TAP is put in the chain, the max. TCK frequency is limited by max. ratio of 1:8 of SDMA core frequency to TCK limitation. This implies max. frequency of 8.25 MHz (or 121.2 ns) for 66 MHz IPG clock. VM = mid point voltage 4.9.21 SPDIF Timing SPDIF data is sent using bi-phase marking code. When encoding, the SPDIF data signal is modulated by a clock that is twice the bit rate of the data signal. Figure 90 shows SPDIF timing parameters, including the timing of the modulating Rx clock (SRCK) for SPDIF in Rx mode and the timing of the modulating Tx clock (STCLK). for SPDIF in Tx mode. Table 77. SPDIF Timing Parameters Timing Parameter Range Parameters Symbol Units Min. Max. SPDIFIN Skew: asynchronous inputs, no specs apply — — 0.7 ns SPDIFOUT output (Load = 50 pf) • Skew • Transition rising • Transition falling — — — — — — 1.5 24.2 31.3 ns SPDIFOUT1 output (Load = 30 pf) • Skew • Transition rising • Transition falling — — — — — — 1.5 13.6 18.0 ns Modulating Rx clock (SRCK) period srckp 40.0 — ns SRCK high period srckph 16.0 — ns SRCK low period srckpl 16.0 — ns Modulating Tx clock (STCLK) period stclkp 40.0 — ns STCLK high period stclkph 16.0 — ns STCLK low period stclkpl 16.0 — ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 113 srckp srckpl srckph VM SRCK (Output) VM Figure 90. SRCK Timing stclkp stclkpl stclkph VM STCLK (Input) VM Figure 91. STCLK Timing 4.9.22 SSI Electrical Specifications This section describes electrical characteristics of the SSI. • • • • NOTE All of the timing for the SSI is given for a non-inverted serial clock polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync (TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have been inverted, all the timing remains valid by inverting the clock signal STCK/SRCK and/or the frame sync STFS/SRFS shown in the tables and in the figures. All timing is on AUDMUX signals when SSI is being used for data transfer. “Tx” and “Rx” refer to the transmit and receive sections of the SSI, respectively. For internal frame sync operations using the external clock, the FS timing will be the same as that of Tx Data (for example, during AC97 mode of operation). i.MX35 Applications Processors for Automotive Products, Rev. 10 114 Freescale Semiconductor 4.9.22.1 SSI Transmitter Timing with Internal Clock Figure 92 depicts the SSI transmitter timing with internal clock, and Table 78 lists the timing parameters. SS1 SS3 SS5 SS2 SS4 AD1_TXC (Output) SS8 SS6 AD1_TXFS (bl) (Output) SS10 SS12 AD1_TXFS (wl) (Output) SS14 SS15 SS16 SS18 SS17 AD1_TXD (Output) SS43 SS42 SS19 AD1_RXD (Input) Note: SRXD Input in Synchronous mode only SS1 SS3 SS5 SS2 SS4 DAM1_T_CLK (Output) SS6 SS8 DAM1_T_FS (bl) (Output) SS10 DAM1_T_FS (wl) (Output) SS12 SS14 SS16 SS15 SS18 SS17 DAM1_TXD (Output) SS43 SS42 SS19 DAM1_RXD (Input) Note: SRXD Input in Synchronous mode only Figure 92. SSI Transmitter with Internal Clock Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 115 Table 78. SSI Transmitter with Internal Clock Timing Parameters ID Parameter Min. Max. Unit Internal Clock Operation SS1 (Tx/Rx) CK clock period 81.4 — ns SS2 (Tx/Rx) CK clock high period 36.0 — ns SS3 (Tx/Rx) CK clock rise time — 6 ns SS4 (Tx/Rx) CK clock low period 36.0 — ns SS5 (Tx/Rx) CK clock fall time — 6 ns SS6 (Tx) CK high to FS (bl) high — 15.0 ns SS8 (Tx) CK high to FS (bl) low — 15.0 ns SS10 (Tx) CK high to FS (wl) high — 15.0 ns SS12 (Tx) CK high to FS (wl) low — 15.0 ns SS14 (Tx/Rx) Internal FS rise time — 6 ns SS15 (Tx/Rx) Internal FS fall time — 6 ns SS16 (Tx) CK high to STXD valid from high impedance — 15.0 ns SS17 (Tx) CK high to STXD high/low — 15.0 ns SS18 (Tx) CK high to STXD high impedance — 15.0 ns SS19 STXD rise/fall time — 6 ns 10.0 — ns Synchronous Internal Clock Operation SS42 SRXD setup before (Tx) CK falling SS43 SRXD hold after (Tx) CK falling 0 — ns SS52 Loading — 25 pF i.MX35 Applications Processors for Automotive Products, Rev. 10 116 Freescale Semiconductor 4.9.22.2 SSI Receiver Timing with Internal Clock Figure 93 depicts the SSI receiver timing with internal clock. Table 79 lists the timing parameters shown in Figure 93. SS1 SS3 SS5 SS4 SS2 AD1_TXC (Output) SS9 SS7 AD1_TXFS (bl) (Output) SS11 SS13 AD1_TXFS (wl) (Output) SS20 SS21 AD1_RXD (Input) SS51 SS47 SS48 SS49 SS50 AD1_RXC (Output) SS1 SS3 SS5 SS2 SS4 DAM1_T_CLK (Output) SS7 DAM1_T_FS (bl) (Output) SS9 SS11 SS13 DAM1_T_FS (wl) (Output) SS20 SS21 DAM1_RXD (Input) SS47 SS48 SS51 SS50 SS49 DAM1_R_CLK (Output) Figure 93. SSI Receiver with Internal Clock Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 117 Table 79. SSI Receiver with Internal Clock Timing Parameters ID Parameter Min. Max. Unit Internal Clock Operation SS1 (Tx/Rx) CK clock period 81.4 — ns SS2 (Tx/Rx) CK clock high period 36.0 — ns SS3 (Tx/Rx) CK clock rise time — 6 ns SS4 (Tx/Rx) CK clock low period 36.0 — ns SS5 (Tx/Rx) CK clock fall time — 6 ns SS7 (Rx) CK high to FS (bl) high — 15.0 ns SS9 (Rx) CK high to FS (bl) low — 15.0 ns SS11 (Rx) CK high to FS (wl) high — 15.0 ns SS13 (Rx) CK high to FS (wl) low — 15.0 ns SS20 SRXD setup time before (Rx) CK low 10.0 — ns SS21 SRXD hold time after (Rx) CK low 0 — ns 15.04 — ns Oversampling Clock Operation SS47 Oversampling clock period SS48 Oversampling clock high period 6 — ns SS49 Oversampling clock rise time — 3 ns SS50 Oversampling clock low period 6 — ns SS51 Oversampling clock fall time — 3 ns i.MX35 Applications Processors for Automotive Products, Rev. 10 118 Freescale Semiconductor 4.9.22.3 SSI Transmitter Timing with External Clock Figure 94 depicts the SSI transmitter timing with external clock, and Table 80 lists the timing parameters. SS22 SS23 AD1_TXC (Input) SS25 SS26 SS27 SS24 SS29 AD1_TXFS (bl) (Input) SS33 SS31 AD1_TXFS (wl) (Input) SS39 SS37 SS38 AD1_TXD (Output) SS45 SS44 AD1_RXD (Input) SS46 Note: SRXD Input in Synchronous mode only SS22 SS26 SS25 SS23 SS24 DAM1_T_CLK (Input) SS27 SS29 DAM1_T_FS (bl) (Input) SS33 SS31 DAM1_T_FS (wl) (Input) SS39 SS37 SS38 DAM1_TXD (Output) SS44 SS45 DAM1_RXD (Input) Note: SRXD Input in Synchronous mode only SS46 Figure 94. SSI Transmitter with External Clock Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 119 Table 80. SSI Transmitter with External Clock Timing Parameters ID Parameter Min. Max. Unit External Clock Operation SS22 (Tx/Rx) CK clock period 81.4 — ns SS23 (Tx/Rx) CK clock high period 36.0 — ns SS24 (Tx/Rx) CK clock rise time — 6.0 ns SS25 (Tx/Rx) CK clock low period 36.0 — ns SS26 (Tx/Rx) CK clock fall time — 6.0 ns SS27 (Tx) CK high to FS (bl) high –10.0 15.0 ns SS29 (Tx) CK high to FS (bl) low 10.0 — ns SS31 (Tx) CK high to FS (wl) high –10.0 15.0 ns SS33 (Tx) CK high to FS (wl) low 10.0 — ns SS37 (Tx) CK high to STXD valid from high impedance — 15.0 ns SS38 (Tx) CK high to STXD high/low — 15.0 ns SS39 (Tx) CK high to STXD high impedance — 15.0 ns Synchronous External Clock Operation SS44 SRXD setup before (Tx) CK falling 10.0 — ns SS45 SRXD hold after (Tx) CK falling 2.0 — ns SS46 SRXD rise/fall time — 6.0 ns i.MX35 Applications Processors for Automotive Products, Rev. 10 120 Freescale Semiconductor 4.9.22.4 SSI Receiver Timing with External Clock Figure 95 depicts the SSI receiver timing with external clock, and Table 81 lists the timing parameters. SS22 SS26 SS24 SS25 SS23 AD1_TXC (Input) SS30 SS28 AD1_TXFS (bl) (Input) SS32 AD1_TXFS (wl) (Input) SS34 SS35 SS41 SS40 SS36 AD1_RXD (Input) SS22 SS24 SS26 SS23 SS25 DAM1_T_CLK (Input) SS30 SS28 DAM1_T_FS (bl) (Input) DAM1_T_FS (wl) (Input) SS32 SS34 SS35 SS41 SS36 SS40 DAM1_RXD (Input) Figure 95. SSI Receiver with External Clock Timing Diagram Table 81. SSI Receiver with External Clock Timing Parameters ID Parameter Min. Max. Unit External Clock Operation SS22 (Tx/Rx) CK clock period 81.4 — ns SS23 (Tx/Rx) CK clock high period 36.0 — ns SS24 (Tx/Rx) CK clock rise time — 6.0 ns i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 121 Table 81. SSI Receiver with External Clock Timing Parameters (continued) ID Parameter Min. Max. Unit 36.0 — ns — 6.0 ns SS25 (Tx/Rx) CK clock low period SS26 (Tx/Rx) CK clock fall time SS28 (Rx) CK high to FS (bl) high –10.0 15.0 ns SS30 (Rx) CK high to FS (bl) low 10.0 — ns SS32 (Rx) CK high to FS (wl) high –10.0 15.0 ns SS34 (Rx) CK high to FS (wl) low 10.0 — ns SS35 (Tx/Rx) External FS rise time — 6.0 ns SS36 (Tx/Rx) External FS fall time — 6.0 ns SS40 SRXD setup time before (Rx) CK low 10.0 — ns SS41 SRXD hold time after (Rx) CK low 2.0 — ns 4.9.23 UART Electrical This section describes the electrical information of the UART module. 4.9.23.1 UART RS-232 Serial Mode Timing The following subsections give the UART transmit and receive timings in RS-232 serial mode. 4.9.23.1.11 UART Transmitter Figure 96 depicts the transmit timing of UART in RS-232 serial mode, with 8 data bit/1 stop bit format. Table 82 lists the UART RS-232 serial mode transmit timing characteristics. UA1 TXD (output) Start Bit Possible Parity Bit UA1 Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Par Bit STOP BIT UA1 Next Start Bit UA1 Figure 96. UART RS-232 Serial Mode Transmit Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 122 Freescale Semiconductor Table 82. RS-232 Serial Mode Transmit Timing Parameters ID UA1 1 2 Parameter Symbol Min. Max. Units tTbit 1/Fbaud_rate1 – Tref_clk2 1/Fbaud_rate + Tref_clk — Transmit Bit Time Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16. Tref_clk: The period of UART reference clock ref_clk (ipg_perclk after RFDIV divider). 4.9.23.1.12 UART Receiver Figure 97 depicts the RS-232 serial mode receive timing, with 8 data bit/1 stop bit format. Table 83 lists serial mode receive timing characteristics. UA2 RXD (input) Start Bit Possible Parity Bit UA2 Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Par Bit STOP BIT Next Start Bit UA2 UA2 Figure 97. UART RS-232 Serial Mode Receive Timing Diagram Table 83. RS-232 Serial Mode Receive Timing Parameters 1 2 ID Parameter Symbol Min. Max. Units UA2 Receive Bit Time1 tRbit 1/Fbaud_rate2 – 1/(16 × Fbaud_rate) 1/Fbaud_rate + 1/(16 × Fbaud_rate) — The UART receiver can tolerate 1/(16 × Fbaud_rate) tolerance in each bit. But accumulation tolerance in one frame must not exceed 3/(16 × Fbaud_rate). Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency) ÷ 16. 4.9.23.2 UART IrDA Mode Timing The following subsections give the UART transmit and receive timings in IrDA mode. 4.9.23.2.13 UART IrDA Mode Transmitter Figure 98 depicts the UART IrDA mode transmit timing, with 8 data bit/1 stop bit format. Table 84 lists the transmit timing characteristics. UA3 UA4 UA3 UA3 UA3 TXD (output) Start Bit Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Possible Parity Bit STOP BIT Figure 98. UART IrDA Mode Transmit Timing Diagram i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 123 Table 84. IrDA Mode Transmit Timing Parameters 1 2 ID Parameter Symbol Min. Max. Units UA3 Transmit bit time in IrDA mode tTIRbit 1/Fbaud_rate1 – Tref_clk2 1/Fbaud_rate + Tref_clk — UA4 Transmit IR pulse duration tTIRpulse (3/16) × (1/Fbaud_rate) (3/16) × (1/Fbaud_rate) – Tref_clk + Tref_clk — Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16. Tref_clk: The period of UART reference clock ref_clk (ipg_perclk after RFDIV divider). 4.9.23.2.14 UART IrDA Mode Receiver Figure 99 depicts the UART IrDA mode receive timing, with 8 data bit/1 stop bit format. Table 85 lists the receive timing characteristics. UA5 UA6 UA5 UA5 UA5 RXD (input) Start Bit Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Possible Parity Bit STOP BIT Figure 99. UART IrDA Mode Receive Timing Diagram Table 85. IrDA Mode Receive Timing Parameters ID 1 2 Parameter UA5 Receive bit time1 in IrDA mode UA6 Receive IR pulse duration Symbol Min. Max. Units tRIRbit 1/Fbaud_rate2 – 1/(16 × Fbaud_rate) 1/Fbaud_rate + 1/(16 × Fbaud_rate ) — tRIRpulse 1.41 us (5/16) × (1/Fbaud_rate) — The UART receiver can tolerate 1/(16 × Fbaud_rate) tolerance in each bit. But accumulation tolerance in one frame must not exceed 3/(16 × Fbaud_rate). Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency) ÷ 16. 4.9.24 USB Electrical Specifications In order to support four different serial interfaces, the USB serial transceiver can be configured to operate in one of four modes: • DAT_SE0 bidirectional, 3-wire mode • DAT_SE0 unidirectional, 6-wire mode • VP_VM bidirectional, 4-wire mode • VP_VM unidirectional, 6-wire mode i.MX35 Applications Processors for Automotive Products, Rev. 10 124 Freescale Semiconductor 4.9.24.1 DAT_SE0 Bidirectional Mode Table 86 defines the signals for DAT_SE0 bidirectional mode. Figure 100 and Figure 101 show the transmit and receive waveforms respectively. Table 86. Signal Definitions—DAT_SE0 Bidirectional Mode Name Direction Signal Description USB_TXOE_B Out Transmit enable, active low USB_DAT_VP Out In Tx data when USB_TXOE_B is low Differential Rx data when USB_TXOE_B is high USB_SE0_VM Out In SE0 drive when USB_TXOE_B is low SE0 Rx indicator when USB_TXOE_B is high Transmit US3 USB_TXOE_B USB_DAT_VP US1 USB_SE0_VM US2 US4 Figure 100. USB Transmit Waveform in DAT_SE0 Bidirectional Mode Receive USB_TXOE_B USB_DAT_VP US7 US8 USB_SE0_VM Figure 101. USB Receive Waveform in DAT_SE0 Bidirectional Mode i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 125 Table 87 describes the port timing specification in DAT_SE0 bidirectional mode. Table 87. Port Timing Specification in DAT_SE0 Bidirectional Mode No. Parameter Signal Name Direction Min. Max. Unit Conditions/Reference Signal US1 Tx rise/fall time USB_DAT_VP Out — 5.0 ns 50 pF US2 Tx rise/fall time USB_SE0_VM Out — 5.0 ns 50 pF US3 Tx rise/fall time USB_TXOE_B Out — 5.0 ns 50 pF US4 Tx duty cycle USB_DAT_VP Out 49.0 51.0 % — US7 Rx rise/fall time USB_DAT_VP In — 3.0 ns 35 pF US8 Rx rise/fall time USB_SE0_VM In — 3.0 ns 35 pF 4.9.24.2 DAT_SE0 Unidirectional Mode Table 88 defines the signals for DAT_SE0 unidirectional mode. Figure 102 and Figure 103 show the transmit and receive waveforms respectively. Table 88. Signal Definitions—DAT_SE0 Unidirectional Mode Name Direction Signal Description USB_TXOE_B Out Transmit enable, active low USB_DAT_VP Out Tx data when USB_TXOE_B is low USB_SE0_VM Out SE0 drive when USB_TXOE_B is low USB_VP1 In Buffered data on DP when USB_TXOE_B is high USB_VM1 In Buffered data on DM when USB_TXOE_B is high USB_RCV In Differential Rx data when USB_TXOE_B is high Transmit US11 USB_TXOE_B USB_DAT_VP US9 USB_SE0_VM US10 US12 Figure 102. USB Transmit Waveform in DAT_SE0 Unidirectional Mode i.MX35 Applications Processors for Automotive Products, Rev. 10 126 Freescale Semiconductor Receive USB_TXOE_B USB_VP1 USB_RCV US15/US17 US16 USB_VM1 Figure 103. USB Receive Waveform in DAT_SE0 Unidirectional Mode Table 89 describes the port timing specification in DAT_SE0 unidirectional mode. Table 89. USB Port Timing Specification in DAT_SE0 Unidirectional Mode Signal Source Min. Max. Unit Condition/ Reference Signal USB_DAT_VP Out — 5.0 ns 50 pF Tx rise/fall time USB_SE0_VM Out — 5.0 ns 50 pF US11 Tx rise/fall time USB_TXOE_B Out — 5.0 ns 50 pF US12 Tx duty cycle USB_DAT_VP Out 49.0 51.0 % — US15 Rx rise/fall time USB_VP1 In — 3.0 ns 35 pF US16 Rx rise/fall time USB_VM1 In — 3.0 ns 35 pF US17 Rx rise/fall time USB_RCV In — 3.0 ns 35 pF No. Parameter US9 Tx rise/fall time US10 4.9.24.3 Signal Name VP_VM Bidirectional Mode Table 90 defines the signals for VP_VM bidirectional mode. Figure 104 and Figure 105 show the transmit and receive waveforms respectively. Table 90. Signal Definitions—VP_VM Bidirectional Mode Name Direction Signal Description USB_TXOE_B Out USB_DAT_VP Out (Tx) In (Rx) Tx VP data when USB_TXOE_B is low Rx VP data when USB_TXOE_B is high USB_SE0_VM Out (Tx) In (Rx) Tx VM data when USB_TXOE_B low Rx VM data when USB_TXOE_B high USB_RCV In Transmit enable, active low Differential Rx data i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 127 Transmit US20 USB_TXOE_B USB_DAT_VP USB_SE0_VM US18 US21 US19 US22 US22 Figure 104. USB Transmit Waveform in VP_VM Bidirectional Mode Receive US26 USB_DAT_VP USB_SE0_VM US27 US28 USB_RCV US29 Figure 105. USB Receive Waveform in VP_VM Bidirectional Mode Table 91 describes the port timing specification in VP_VM bidirectional mode. Table 91. USB Port Timing Specification in VP_VM Bidirectional Mode No. Parameter Signal Name Direction Min. Max. Unit Condition/ Reference Signal US18 Tx rise/fall time USB_DAT_VP Out — 5.0 ns 50 pF US19 Tx rise/fall time USB_SE0_VM Out — 5.0 ns 50 pF US20 Tx rise/fall time USB_TXOE_B Out — 5.0 ns 50 pF US21 Tx duty cycle USB_DAT_VP Out 49.0 51.0 % — US22 Tx overlap USB_SE0_VM Out –3.0 +3.0 ns USB_DAT_VP US26 Rx rise/fall time USB_DAT_VP In — 3.0 ns 35 pF US27 Rx rise/fall time USB_SE0_VM In — 3.0 ns 35 pF i.MX35 Applications Processors for Automotive Products, Rev. 10 128 Freescale Semiconductor Table 91. USB Port Timing Specification in VP_VM Bidirectional Mode (continued) No. Parameter Signal Name Direction Min. Max. Unit Condition/ Reference Signal US28 Rx skew USB_DAT_VP In –4.0 +4.0 ns USB_SE0_VM US29 Rx skew USB_RCV In –6.0 +2.0 ns USB_DAT_VP 4.9.24.4 VP_VM Unidirectional Mode Table 92 defines the signals for VP_VM unidirectional mode. Figure 106 and Figure 107 show the transmit and receive waveforms respectively. Table 92. Signal Definitions—VP_VM Unidirectional Mode Name Direction Signal Description USB_TXOE_B Out Transmit enable, active low USB_DAT_VP Out Tx VP data when USB_TXOE_B is low USB_SE0_VM Out Tx VM data when USB_TXOE_B is low USB_VP1 In Rx VP data when USB_TXOE_B is high USB_VM1 In Rx VM data when USB_TXOE_B is high USB_RCV In Differential Rx data Transmit US32 USB_TXOE_B USB_DAT_VP USB_SE0_VM US30 US33 US31 US34 US34 Figure 106. USB Transmit Waveform in VP_VM Unidirectional Mode i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 129 Receive USB_TXOE_B USB_VP1 US38 USB_VM1 US40 US39 USB_RCV US41 Figure 107. USB Receive Waveform in VP_VM Unidirectional Mode Table 93 describes the port timing specification in VP_VM unidirectional mode. Table 93. USB Timing Specification in VP_VM Unidirectional Mode No. Parameter Signal Direction Min. Max. Unit Conditions/Reference Signal US30 Tx rise/fall time USB_DAT_VP Out — 5.0 ns 50 pF US31 Tx rise/fall time USB_SE0_VM Out — 5.0 ns 50 pF US32 Tx rise/fall time USB_TXOE_B Out — 5.0 ns 50 pF US33 Tx duty cycle USB_DAT_VP Out 49.0 51.0 % — US34 Tx overlap USB_SE0_VM Out –3.0 +3.0 ns USB_DAT_VP US38 Rx rise/fall time USB_VP1 In — 3.0 ns 35 pF US39 Rx rise/fall time USB_VM1 In — 3.0 ns 35 pF US40 Rx skew USB_VP1 In –4.0 +4.0 ns USB_VM1 US41 Rx skew USB_RCV In –6.0 +2.0 ns USB_VP1 i.MX35 Applications Processors for Automotive Products, Rev. 10 130 Freescale Semiconductor 5 Package Information and Pinout This section includes the following: • Mechanical package drawing • Pin/contact assignment information i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 131 5.1 MAPBGA Production Package 1568-01, 17 × 17 mm, 0.8 Pitch See Figure 108 for the package drawing and dimensions of the production package. Figure 108. Production Package: Mechanical Drawing i.MX35 Applications Processors for Automotive Products, Rev. 10 132 Freescale Semiconductor 5.2 MAPBGA Signal Assignments Table 94 and Table 95 list MAPBGA signals, alphabetized by signal name, for silicon revisions 2.0 and 2.1, respectively. Table 96 and Table 97 show the signal assignment on the i.MX35 ball map for silicon revisions 2.0 and 2.1, respectively. The ball map for silicon revision 2.1 is different than the ballmap for silicon revision 2.0. The layout for each revision is not compatible, so it is important that the correct ballmap be used to implement the layout. Table 94. Silicon Revision 2.0 Signal Ball Map Locations Signal ID A0 A1 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 A2 A20 A21 A22 A23 A24 A25 A3 A4 A5 A6 A7 A8 A9 ATA_BUFF_EN1 ATA_CS01 ATA_CS11 ATA_DA01 ATA_DA11 ATA_DA21 ATA_DATA01 ATA_DATA11 ATA_DATA101 ATA_DATA111 ATA_DATA121 Ball Location A5 D7 F15 D5 F6 B3 D14 D15 D13 D12 E11 D11 E7 D10 E10 D9 E9 D8 E8 C6 D6 B5 C5 A4 B4 A3 T5 V7 T7 R4 V1 R5 Y5 W5 V3 Y2 U3 Signal ID Ball Location 1 ATA_DATA7 ATA_DATA81 ATA_DATA91 ATA_DIOR1 ATA_DIOW1 ATA_DMACK1 ATA_DMARQ1 ATA_INTRQ1 ATA_IORDY1 ATA_RESET_B1 BCLK BOOT_MODE0 BOOT_MODE1 CAPTURE CAS CLK_MODE0 CLK_MODE1 CLKO COMPARE CONTRAST1 CS0 CS1 CS2 CS3 CS4 CS5 CSI_D101 CSI_D111 CSI_D121 CSI_D131 CSI_D141 CSI_D151 CSI_D81 CSI_D91 CSI_HSYNC1 CSI_MCLK1 CSI_PIXCLK1 Y3 U4 W3 Y6 W6 V6 T3 V2 U6 T6 E14 W10 U9 V12 E16 Y10 T10 V10 T12 L16 F17 E19 B20 C19 E18 F19 V16 T15 W16 V15 U14 Y16 U15 W17 V14 W15 Y15 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 133 Table 94. Silicon Revision 2.0 Signal Ball Map Locations (continued) Signal ID ATA_DATA131 ATA_DATA141 ATA_DATA151 ATA_DATA21 ATA_DATA3 ATA_DATA4 ATA_DATA5 ATA_DATA6 CTS2 D0 D1 D10 D11 D12 D13 D14 D15 D2 D3 D3_CLS1 D3_DRDY1 D3_FPSHIFT1 D3_HSYNC1 D3_REV1 D3_SPL1 D3_VSYNC1 D4 D5 D6 D7 D8 D9 DE_B DQM0 DQM1 DQM2 DQM3 EB0 EB1 ECB EXT_ARMCLK EXTAL_AUDIO EXTAL24M FEC_COL FEC_CRS FEC_MDC Ball Location W2 W1 T4 V5 U5 Y4 W4 V4 G5 A2 D4 D2 E6 E3 F5 D1 E2 B2 E5 L17 L20 L15 L18 M17 M18 M19 C3 B1 D3 C2 C1 E4 W19 B19 D17 D16 C18 F18 F16 D19 V8 W20 T20 P3 N5 R1 Signal ID Ball Location 1 CSI_VSYNC CSPI1_MISO CSPI1_MOSI CSPI1_SCLK CSPI1_SPI_RDY CSPI1_SS0 CSPI1_SS1 CTS1 FEC_TDATA0 FEC_TDATA1 FEC_TDATA2 FEC_TDATA3 FEC_TX_CLK FEC_TX_EN FEC_TX_ERR FSR FST FUSE_VDD FUSE_VSS GPIO1_0 GPIO1_1 GPIO2_0 GPIO3_0 HCKR HCKT I2C1_CLK I2C1_DAT I2C2_CLK I2C2_DAT LBA LD01 LD11 LD101 LD111 LD121 LD131 LD141 LD151 LD161 LD171 LD181 LD191 LD21 LD201 LD211 LD221 T14 V9 W9 W8 T8 Y8 U8 R3 P5 M4 M5 L6 P4 T1 N4 K5 J1 P13 M11 T11 Y11 U11 V11 K2 J5 M20 N17 L3 M1 D20 F20 G18 H20 J18 J16 J19 J17 J20 K14 K19 K18 K20 G17 K16 K17 K15 i.MX35 Applications Processors for Automotive Products, Rev. 10 134 Freescale Semiconductor Table 94. Silicon Revision 2.0 Signal Ball Map Locations (continued) Signal ID FEC_MDIO FEC_RDATA0 FEC_RDATA1 FEC_RDATA2 FEC_RDATA3 FEC_RX_CLK FEC_RX_DV FEC_RX_ERR MA10 MGND MLB_CLK MLB_DAT MLB_SIG MVDD NF_CE0 NFALE NFCLE NFRB NFRE_B NFWE_B NFWP_B NGND_ATA NGND_ATA NGND_ATA NGND_CRM NGND_CSI NGND_EMI1 NGND_EMI1 NGND_EMI1 NGND_EMI2 NGND_EMI3 NGND_EMI3 NGND_JTAG NGND_LCDC NGND_LCDC NGND_MISC NGND_MISC NGND_MLB NGND_NFC NGND_SDIO NVCC_ATA NVCC_ATA NVCC_ATA NVCC_ATA NVCC_CRM NVCC_CSI Ball Location Signal ID Ball Location P1 P2 N2 M3 N1 R2 T2 N3 C4 N11 W13 Y13 W12 P11 G3 F2 E1 F3 F1 G2 F4 M9 P9 L10 L11 N10 H8 H10 J10 J11 J12 K12 M13 K11 L12 M7 K8 M10 K9 N12 N6 P6 P7 P8 R9 R11 LD231 L19 G16 G19 H16 H18 G20 H17 H19 G12 F13 F14 G14 P16 H14 J14 L14 M14 K6 K7 L8 R10 G6 H6 H7 P14 E20 V20 U19 T19 T18 M12 M15 N20 N16 P20 R13 P12 W11 Y9 N13 E15 U10 U18 U1 G1 C20 LD31 LD41 LD51 LD61 LD71 LD81 LD91 NVCC_EMI2 NVCC_EMI2 NVCC_EMI2 NVCC_EMI3 NVCC_JTAG NVCC_LCDC NVCC_LCDC NVCC_LCDC NVCC_LCDC NVCC_MISC NVCC_MISC NVCC_MISC NVCC_MLB NVCC_NFC NVCC_NFC NVCC_NFC NVCC_SDIO OE OSC_AUDIO_VDD OSC_AUDIO_VSS OSC24M_VDD OSC24M_VSS PGND PHY1_VDDA PHY1_VDDA PHY1_VSSA PHY1_VSSA PHY2_VDD PHY2_VSS POR_B POWER_FAIL PVDD RAS RESET_IN_B RTCK RTS1 RTS2 RW i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 135 Table 94. Silicon Revision 2.0 Signal Ball Map Locations (continued) Signal ID Ball Location Signal ID Ball Location NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 SD1_CLK SD1_CMD SD1_DATA0 SD1_DATA1 SD1_DATA2 SD1_DATA3 SD10 SD11 SD12 SD13 SD14 SD15 SD16 SD17 SD18 SD19 SD2 SD2_CLK SD2_CMD SD2_DATA0 SD2_DATA1 SD2_DATA2 SD2_DATA3 SD20 SD21 SD22 SD23 SD24 SD25 SD26 SD27 SD28 SD29 SD3 SD30 SD31 SD4 SD5 G7 G8 G9 H9 F10 G10 F11 G11 V18 Y19 R14 U16 W18 V17 A15 B15 C13 B14 A14 B13 C12 C11 A12 B12 B18 W14 U13 V13 T13 Y14 U12 B11 A11 C10 B10 A9 C9 B9 A8 B8 C8 C16 A7 B7 A18 C15 RXD1 RXD2 SCK4 SCK5 SCKR SCKT SD0 SD1 SDCLK SDCLK_B SDQS0 SDQS1 SDQS2 SDQS3 SDWE SJC_MOD SRXD4 SRXD5 STXD4 STXD5 STXFS4 STXFS5 TCK TDI TDO TEST_MODE TMS TRSTB TTM_PIN TX0 TX1 TX2_RX3 TX3_RX2 TX4_RX1 TX5_RX0 TXD1 TXD2 USBOTG_OC USBOTG_PWR USBPHY1_DM USBPHY1_DP USBPHY1_RREF USBPHY1_UID USBPHY1_UPLLGND USBPHY1_UPLLVDD USBPHY1_UPLLVDD U2 H3 L4 L5 K3 J4 C17 A19 E12 E13 B17 A13 A10 C7 G15 U17 L1 K4 M2 K1 L2 J6 R17 P15 R15 Y7 R16 T16 M16 G4 H1 H5 J2 H4 J3 R6 H2 U7 W7 N19 P19 R19 N18 N14 N15 P17 i.MX35 Applications Processors for Automotive Products, Rev. 10 136 Freescale Semiconductor Table 94. Silicon Revision 2.0 Signal Ball Map Locations (continued) 1 Signal ID Ball Location Signal ID Ball Location SD6 SD7 SD8 SD9 SDBA0 SDBA1 SDCKE0 SDCKE1 VDD VDD VDD VDD VDD VDD VDD VDD VDD VDD VDD VSS VSS VSS VSS VSS VSS A17 B16 C14 A16 A6 B6 D18 E17 L7 N7 R7 F8 R8 F9 F12 R12 G13 H15 J15 A1 Y1 J8 M8 N8 J9 USBPHY1_VBUS USBPHY1_VDDA_BIAS USBPHY1_VSSA_BIAS USBPHY2_DM USBPHY2_DP VDD VDD VDD VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSTBY WDOG_RST XTAL_AUDIO XTAL24M P18 R20 R18 Y17 Y18 M6 F7 J7 L9 N9 K10 P10 H11 H12 H13 J13 K13 L13 T17 A20 Y20 T9 Y12 V19 U20 Not available for the MCIMX351. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 137 Table 95. Silicon Revision 2.1 Signal Ball Map Locations Signal ID Ball Location Signal ID Ball Location A0 A1 A10 A11 A12 A13 A14 A15 A16 A18 SDQS1 A19 A2 A21 SDQS2 A22 SDQS3 A24 A25 A3 A4 A5 A6 A7 A8 A9 ATA_BUFF_EN1 ATA_CS0 ATA_CS1 ATA_DA0 ATA_DA1 ATA_DA2 ATA_DATA0 ATA_DATA1 ATA_DATA10 ATA_DATA11 ATA_DATA12 ATA_DATA13 ATA_DATA14 ATA_DATA15 ATA_DATA2 ATA_DATA3 ATA_DATA4 ATA_DATA5 ATA_DATA6 A5 D7 F15 D5 F6 B3 D14 D15 D13 D12 E11 D11 E7 D10 E10 D9 E9 D8 E8 C6 D6 B5 C5 A4 B4 A3 T5 V7 T7 R4 V1 R5 Y5 W5 V3 Y2 U3 W2 W1 T4 V5 U5 Y4 W4 V4 ATA_DATA7 ATA_DATA8 ATA_DATA9 ATA_DIOR ATA_DIOW ATA_DMACK ATA_DMARQ ATA_INTRQ ATA_IORDY ATA_RESET_B SDQS0 BOOT_MODE0 BOOT_MODE1 CAPTURE RAS CLK_MODE0 CLK_MODE1 CLKO COMPARE CONTRAST CS0 CS1 CS2 CS3 CS4 CS5 CSI_D10 CSI_D11 CSI_D12 CSI_D13 CSI_D14 CSI_D15 CSI_D8 CSI_D9 CSI_HSYNC CSI_MCLK CSI_PIXCLK CSI_VSYNC CSPI1_MISO CSPI1_MOSI CSPI1_SCLK CSPI1_SPI_RDY CSPI1_SS0 CSPI1_SS1 CTS1 Y3 U4 W3 Y6 W6 V6 T3 V2 U6 T6 E14 W10 U9 V12 E16 Y10 T10 V10 T12 L16 F17 E19 B20 C19 E18 F19 V16 T15 W16 V15 U14 Y16 U15 W17 V14 W15 Y15 T14 V9 W9 W8 T8 Y8 U8 R3 i.MX35 Applications Processors for Automotive Products, Rev. 10 138 Freescale Semiconductor Table 95. Silicon Revision 2.1 Signal Ball Map Locations (continued) Signal ID Ball Location Signal ID Ball Location CTS2 D0 D1 D10 D11 D12 D13 D14 D15 D2 D3 D3_CLS D3_DRDY D3_FPSHIFT D3_HSYNC D3_REV D3_SPL D3_VSYNC D4 D5 D6 D7 D8 D9 DE_B DQM0 SDCKE1 DQM2 DQM3 EB0 EB1 ECB EXT_ARMCLK EXTAL_AUDIO EXTAL24M FEC_COL FEC_CRS FEC_MDC FEC_MDIO FEC_RDATA0 FEC_RDATA1 FEC_RDATA2 FEC_RDATA3 FEC_RX_CLK FEC_RX_DV FEC_RX_ERR G5 A2 D4 D2 E6 E3 F5 D1 E2 B2 E5 L17 L20 L15 L18 M17 M18 M19 C3 B1 D3 C2 C1 E4 W19 B19 D17 D16 C18 F18 F16 D19 V8 W20 T20 P3 N5 R1 P1 P2 N2 M3 N1 R2 T2 N3 FEC_TDATA0 FEC_TDATA1 FEC_TDATA2 FEC_TDATA3 FEC_TX_CLK FEC_TX_EN FEC_TX_ERR FSR FST FUSE_VDD FUSE_VSS GPIO1_0 GPIO1_1 GPIO2_0 GPIO3_0 HCKR HCKT I2C1_CLK I2C1_DAT I2C2_CLK I2C2_DAT LBA LD0 LD1 LD10 LD11 LD12 LD13 LD14 LD15 LD16 LD17 LD18 LD19 LD2 LD20 LD21 LD22 LD23 LD3 LD4 LD5 LD6 LD7 LD8 LD9 P5 M4 M5 L6 P4 T1 N4 K5 J1 P13 M11 T11 Y11 U11 V11 K2 J5 M20 N17 L3 M1 D20 F20 G18 H20 J18 J16 J19 J17 J20 K14 K19 K18 K20 G17 K16 K17 K15 L19 G16 G19 H16 H18 G20 H17 H19 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 139 Table 95. Silicon Revision 2.1 Signal Ball Map Locations (continued) Signal ID Ball Location Signal ID Ball Location MA10 MGND MLB_CLK MLB_DAT MLB_SIG MVDD NF_CE0 NFALE NFCLE NFRB NFRE_B NFWE_B NFWP_B NGND_ATA NGND_ATA NGND_ATA NGND_CRM NGND_CSI NGND_EMI1 NVCC_EMI1 NGND_EMI1 NGND_EMI2 NGND_EMI3 NGND_EMI3 NGND_JTAG NGND_LCDC NGND_LCDC NGND_MISC NGND_MISC NGND_MLB NGND_NFC NGND_SDIO NVCC_ATA NVCC_ATA NVCC_ATA NVCC_ATA NVCC_CRM NVCC_CSI NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 NGND_EMI1 NVCC_EMI1 NVCC_EMI1 NVCC_EMI1 C4 N11 W13 Y13 W12 P11 G3 F2 E1 F3 F1 G2 F4 M9 P9 L10 L11 N10 H8 H10 J10 J11 J12 K12 M13 K11 L12 M7 K8 M10 K9 N12 N6 P6 P7 P8 R9 R11 G7 G8 G9 H9 F10 G10 F11 G11 NVCC_EMI2 NVCC_EMI2 VSS NVCC_EMI3 NVCC_JTAG NVCC_LCDC NVCC_LCDC NVCC_LCDC NVCC_LCDC NVCC_MISC NVCC_MISC NVCC_MISC NVCC_MLB NVCC_NFC NVCC_NFC NVCC_NFC NVCC_SDIO OE OSC_AUDIO_VDD OSC_AUDIO_VSS OSC24M_VDD OSC24M_VSS PGND PHY1_VDDA PHY1_VDDA PHY1_VSSA PHY1_VSSA PHY2_VDD PHY2_VSS POR_B POWER_FAIL PVDD BCLK RESET_IN_B RTCK RTS1 RTS2 RW RXD1 RXD2 SCK4 SCK5 SCKR SCKT DQM1 SD1 G12 F13 F14 G14 P16 H14 J14 L14 M14 K6 K7 L8 R10 G6 H6 H7 P14 E20 V20 U19 T19 T18 M12 M15 N20 N16 P20 R13 P12 W11 Y9 N13 E15 U10 U18 U1 G1 C20 U2 H3 L4 L5 K3 J4 C17 A19 i.MX35 Applications Processors for Automotive Products, Rev. 10 140 Freescale Semiconductor Table 95. Silicon Revision 2.1 Signal Ball Map Locations (continued) Signal ID Ball Location Signal ID Ball Location SD1_CLK SD1_CMD SD1_DATA0 SD1_DATA1 SD1_DATA2 SD1_DATA3 SD10 SD11 A17 SD13 SD14 SD12 SD16 SD17 SD18 SD19 SD2 SD2_CLK SD2_CMD SD2_DATA0 SD2_DATA1 SD2_DATA2 SD2_DATA3 SD20 SD21 A20 SD22 SD24 SD25 SD26 SD27 SD28 SD29 SD3 SD30 SD31 SD4 SD5 SD6 SD7 SD8 SD9 SDBA0 SDBA1 SDCKE0 CAS V18 Y19 R14 U16 W18 V17 A15 B15 C13 B14 A14 B13 C12 C11 A12 B12 B18 W14 U13 V13 T13 Y14 U12 B11 A11 C10 B10 A9 C9 B9 A8 B8 C8 C16 A7 B7 A18 C15 A17 B16 C14 A16 A6 B6 D18 E17 SDCLK SDCLK_B SD0 SD15 SD23 A23 SDWE SJC_MOD SRXD4 SRXD5 STXD4 STXD5 STXFS4 STXFS5 TCK TDI TDO TEST_MODE TMS TRSTB TTM_PIN TX0 TX1 TX2_RX3 TX3_RX2 TX4_RX1 TX5_RX0 TXD1 TXD2 USBOTG_OC USBOTG_PWR USBPHY1_DM USBPHY1_DP USBPHY1_RREF USBPHY1_UID USBPHY1_UPLLGND USBPHY1_UPLLVDD USBPHY1_UPLLVDD USBPHY1_VBUS USBPHY1_VDDA_BIAS USBPHY1_VSSA_BIAS USBPHY2_DM USBPHY2_DP VDD VDD VDD E12 E13 B17 A13 A10 C7 G15 U17 L1 K4 M2 K1 L2 J6 R17 P15 R15 Y7 R16 T16 M16 G4 H1 H5 J2 H4 J3 R6 H2 U7 W7 N19 P19 R19 N18 N14 N15 P17 P18 R20 R18 Y17 Y18 M6 F7 J7 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 141 Table 95. Silicon Revision 2.1 Signal Ball Map Locations (continued) 1 Signal ID Ball Location Signal ID Ball Location VDD VDD VDD VDD VDD VDD VDD VDD VDD VDD VDD VSS VSS VSS VSS VSS VSS L7 N7 R7 F8 R8 F9 F12 R12 G13 H15 J15 A1 Y1 J8 M8 N8 J9 VSS VSS VSS VSS VSS VSS NVCC_EMI2 VSS VSS VSS VSS VSS VSS VSTBY WDOG_RST XTAL_AUDIO XTAL24M L9 N9 K10 P10 H11 H12 H13 J13 K13 L13 T17 A20 Y20 T9 Y12 V19 U20 Not available for the MCIMX351. i.MX35 Applications Processors for Automotive Products, Rev. 10 142 Freescale Semiconductor Table 96. Silicon Revision 2.0 Ball Map—17 x 17, 0.8 mm Pitch1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 A VSS D0 A9 A7 A0 SDB A0 SD3 0 SD2 7 SD2 4 SDQ S2 SD2 1 SD1 8 SDQ S1 SD1 4 SD1 0 SD9 SD6 SD4 SD1 VSS A B D5 D2 A13 A8 A5 SDB A1 SD3 1 SD2 8 SD2 6 SD2 3 SD2 0 SD1 9 SD1 5 SD1 3 SD1 1 SD7 SDQ S0 SD2 DQM 0 CS2 B C D8 D7 D4 MA1 0 A6 A3 SDQ S3 SD2 9 SD2 5 SD2 2 SD1 7 SD1 6 SD1 2 SD8 SD5 SD3 SD0 DQM 3 CS3 RW C D D14 D10 D6 D1 A11 A4 A1 A24 A22 A20 A19 A17 A16 A14 A15 DQM DQM 2 1 SDC KE0 ECB LBA D E NFC LE D15 D12 D9 D3 D11 A2 A25 A23 A21 A18 SDC LK SDC LK_ B BCL K RAS CAS SDC KE1 CS4 CS1 OE E F NFR E_B NFA LE NFR B NFW P_B D13 A12 VDD VDD VDD NVC C_E MI1 NVC C_E MI1 VDD NVC C_E MI2 NVC C_E MI2 A10 EB1 CS0 EB0 CS5 LD0 F G RTS 2 NFW E_B NF_ CE0 TX0 CTS 2 NVC C_N FC NVC C_E MI1 NVC C_E MI1 NVC C_E MI1 NVC C_E MI1 NVC C_E MI1 NVC C_E MI2 VDD NVC C_E MI3 SDW E LD3 LD2 LD1 LD4 LD7 G H TX1 TXD 2 RXD 2 TX4_ TX2_ RX1 RX3 NVC C_N FC NVC C_N FC NGN D_E MI1 NVC C_E MI1 NGN D_E MI1 VSS VSS VSS NVC C_L CDC VDD LD5 LD8 LD6 LD9 LD10 H J FST TX3_ TX5_ RX2 RX0 SCK T HCK T STX FS5 VDD VSS VSS NGN D_E MI1 NGN D_E MI2 NGN D_E MI3 VSS NVC C_L CDC VDD LD12 LD14 LD11 LD13 LD15 J K STX D5 HCK R SCK R SRX D5 FSR NVC NVC NGN NGN C_MI C_MI D_MI D_N SC SC FC SC VSS NGN D_L CDC NGN D_E MI3 VSS LD16 LD22 LD20 LD21 LD18 LD17 LD19 K L SRX D4 STX FS4 I2C2 _CL K SCK 4 SCK 5 FEC _TD ATA3 VDD NVC C_MI SC VSS NGN D_A TA NGN D_C RM NGN D_L CDC VSS NVC C_L CDC D3_ FPS HIFT CON TRA ST D3_ CLS D3_ HSY NC LD23 D3_ DRD Y L M I2C2 _DAT STX D4 FEC _RD ATA2 FEC _TD ATA1 FEC _TD ATA2 VDD NGN D_MI SC VSS NGN D_A TA NGN D_M LB FUS E_V SS PGN NGN D D_JT AG NVC C_L CDC PHY 1_V DDA TTM _PIN D3_ REV D3_ SPL D3_ VSY NC I2C1 _CL K M N FEC _RD ATA3 FEC _RD ATA1 FEC _RX _ER R FEC _TX_ ERR FEC _CR S NVC C_A TA VDD VSS VSS NGN D_C SI MGN D NGN D_S DIO PVD D USB PHY 1_U PLL GND USB PHY 1_U PLLV DD PHY 1_V SSA I2C1 _DAT USB PHY 1_UI D USB PHY 1_D M PHY 1_V DDA N P FEC FEC _MDI _RD O ATA0 FEC _CO L FEC FEC _TX_ _TD CLK ATA0 NVC C_A TA NVC C_A TA NVC C_A TA NGN D_A TA VSS MVD D PHY 2_V SS FUS E_V DD NVC C_S DIO TDI NVC C_JT AG USB PHY 1_U PLLV DD USB PHY 1_V BUS USB PHY 1_D P PHY 1_V SSA P R FEC _MD C FEC _RX _CL K CTS 1 ATA_ DA0 ATA_ DA2 TXD 1 VDD VDD NVC C_C RM NVC C_M LB NVC C_C SI VDD PHY 2_V DD SD1 _DAT A0 TDO TMS TCK USB PHY 1_V SSA _BIA S USB PHY 1_R REF USB PHY 1_V DDA _BIA S R T FEC _TX_ EN FEC _RX _DV ATA_ ATA_ ATA_ DMA DATA BUF RQ 15 F_E N ATA_ RES ET_ B ATA_ CSPI CS1 1_S PI_R DY VST BY CLK _MO DE1 GPI O1_ 0 COM SD2 CSI_ PAR _DAT VSY E A1 NC CSI_ D11 TRS TB VSS OSC 24M _VS S OSC 24M _VD D EXT AL24 M T U RTS 1 RXD 1 ATA_ ATA_ ATA_ ATA_ DATA DATA DATA IOR 12 8 3 DY USB OTG _OC BOO T_M ODE 1 RES ET_I N_B GPI O2_ 0 SD2 _DAT A3 CSI_ SD1 D8 _DAT A1 SJC _MO D RTC K OSC XTAL _AU 24M DIO_ VSS U CSPI 1_S S1 SD2 _CM D CSI_ D14 i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 143 Table 96. Silicon Revision 2.0 Ball Map—17 x 17, 0.8 mm Pitch1 (continued) 7 8 9 10 11 12 ATA_ ATA_ ATA_ ATA_ ATA_ ATA_ DA1 INTR DATA DATA DATA DMA Q 10 6 2 CK 1 ATA_ CS0 EXT _AR MCL K CSPI 1_MI SO CLK O GPI O3_ 0 CAP TUR E SD2 CSI_ _DAT HSY A0 NC CSI_ D13 CSI_ SD1 D10 _DAT A3 W ATA_ ATA_ ATA_ ATA_ ATA_ ATA_ DATA DATA DATA DATA DATA DIO 14 13 9 5 1 W USB OTG _PW R CSPI CSPI 1_S 1_M CLK OSI BOO T_M ODE 0 POR _B MLB _SIG MLB _CL K CSI_ MCL K CSI_ D12 CSI_ SD1 D9 _DAT A2 DE_ B EXT W AL_ AUDI O Y TES T_M ODE CSPI POW 1_S ER_ S0 FAIL CLK _MO DE0 GPI O1_ 1 WD OG_ RST MLB SD2 CSI_ _DAT _DAT PIXC A2 LK CSI_ D15 USB PHY 2_D M SD1 _CM D VSS V 1 VSS 2 3 4 5 6 ATA_ ATA_ ATA_ ATA_ ATA_ DATA DATA DATA DATA DIO 11 7 4 0 R 13 14 SD2 _CL K 15 16 17 18 SD1 _CL K USB PHY 2_D P 19 20 XTAL OSC _AU _AU DIO DIO_ VDD V Y See Table 95 for pins unavailable in the MCIMX351 SoC. Table 97. Silicon Revision 2.1 Ball Map—17 x 17, 0.8 mm Pitch 1 2 3 4 5 6 7 8 9 16 17 18 19 20 A GND D0 A9 A7 A0 SDB A0 SD30 SD27 SD24 SD23 SD21 SD18 SD15 SD14 SD10 SD9 SD6 SD4 SD1 GND A B D5 D2 A13 A8 A5 SDB A1 SD31 SD28 SD26 SD22 SD20 SD19 SD12 SD13 SD11 SD7 SD0 SD2 DQM 0 CS2 B C D8 D7 D4 MA1 0 A6 A3 A23 D D14 D10 D6 D1 A11 A4 A1 A24 A22 A21 A19 E NFC LE D15 D12 D9 D3 D11 A2 A25 SDQ S3 SDQ S2 F NFR E_B NFAL E NFR B NFW P_B D13 A12 VDD 7 VDD 7 VDD 7 G RTS 2 NFW E_B NF_ CE0 TX0 CTS 2 NVC C_N FC NVC C_E MI1 NVC C_E MI1 H TX1 TXD 2 RXD 2 TX4_ TX2_ RX1 RX3 NVC C_N FC NVC C_N FC J FST TX3_ TX5_ RX2 RX0 SCK T HCK T STX FS5 K STX D5 HCK R SCK R SRX D5 L SRX D4 STX FS4 I2C2 _CLK SCK 4 M I2C2 _DAT N FEC _RD ATA3 A20 11 12 SD17 SD16 13 14 15 A17 SD8 SD5 SD3 DQM 1 DQM 3 CS3 RW C A18 A16 A14 A15 DQM 2 SDC KE1 SDC KE0 ECB LBA D SDQ S1 SDC LK SDC LK_B SDQ S0 BCL K RAS CAS CS4 CS1 OE E GND NVC C_E MI1 VDD 7 NVC C_E MI2 GND A10 EB1 CS0 EB0 CS5 LD0 F NVC C_E MI1 NVC C_E MI1 NVC C_E MI1 NVC C_E MI2 VDD 6 NVC C_E MI3 SDW E LD3 LD2 LD1 LD4 LD7 G GND NVC C_E MI1 NVC C_E MI1 GND GND NVC C_E MI2 NVC C_L CDC VDD 5 LD5 LD8 LD6 LD9 LD10 H VDD 1 GND GND GND GND GND GND NVC C_L CDC VDD 5 LD12 LD14 LD11 LD13 LD15 J FSR NVC NVC C_MI C_MI SC SC GND GND GND GND GND GND LD16 LD22 LD20 LD21 LD18 LD17 LD19 K SCK 5 FEC _TDA TA3 VDD 2 NVC C_MI SC GND GND GND GND GND NVC C_L CDC D3_F PSHI FT CON TRA ST D3_ CLS D3_ HSY NC D3_ DRD Y L STX D4 FEC FEC FEC _RD _TDA _TDA ATA2 TA1 TA2 VDD 2 GND GND GND GND FUS E_V SS PGN D GND NVC C_L CDC PHY TTM 1_VD _PAD DA D3_ REV D3_S D3_V I2C1 PL SYN _CLK C M FEC _RD ATA1 FEC FEC _RX_ _TX_ ERR ERR NVC C_AT A VDD 3 GND GND GND MGN D GND PVD D USB USB PHY I2C1 PHY PHY 1_VS _DAT 1_UP 1_UP SA LLG LLVD ND D USB PHY 1_UI D N FEC _CR S SD29 SD25 10 LD23 USB PHY 1_D M PHY 1_VD DA i.MX35 Applications Processors for Automotive Products, Rev. 10 144 Freescale Semiconductor Table 97. Silicon Revision 2.1 Ball Map—17 x 17, 0.8 mm Pitch (continued) 1 2 3 P FEC _MDI O FEC _RD ATA0 FEC _CO L R FEC _MD C FEC _RX_ CLK T 9 10 11 12 13 14 15 FEC FEC NVC NVC NVC _TX_ _TDA C_AT C_AT C_AT CLK TA0 A A A GND GND MVD D PHY 2_VS S FUS E_V DD NVC C_S DIO TDI NVC USB USB USB PHY C_JT PHY PHY PHY 1_VS AG 1_UP 1_VB 1_DP SA LLVD US D P CTS 1 ATA_ DA0 ATA_ DA2 TXD 1 VDD 3 VDD 3 NVC C_C RM NVC C_M LB NVC C_C SI VDD 4 PHY SD1_ 2_VD DATA D 0 TDO TMS TCK USB PHY 1_VS SA_ BIAS USB PHY 1_VD DA_ BIAS R FEC FEC _TX_ _RX_ EN DV ATA_ DMA RQ ATA_ DATA 15 ATA_ BUF F_E N ATA_ RES ET_B ATA_ CS1 CSPI 1_SP I_RD Y VST BY CLK_ GPIO COM SD2_ MOD 1_0 PAR DATA E1 E 1 CSI_ VSY NC CSI_ D11 TRS TB GND OSC OSC EXTA 24M_ 24M_ L24M VSS VDD T U RTS 1 RXD 1 ATA_ DATA 12 ATA_ ATA_ ATA_ DATA DATA IORD 8 3 Y USB OTG _OC CSPI 1_SS 1 BOO T_M ODE 1 RES ET_I N_B GPIO SD2_ SD2_ 2_0 DATA CMD 3 CSI_ D14 CSI_ D8 SD1_ SJC_ DATA MOD 1 OSC _AU DIO_ VSS XTAL 24M U V ATA_ DA1 ATA_ INTR Q ATA_ DATA 10 ATA_ ATA_ DATA DATA 6 2 ATA_ DMA CK ATA_ CS0 EXT_ CSPI ARM 1_MI CLK SO CLK O GPIO 3_0 CAP TUR E CSI_ HSY NC CSI_ D13 CSI_ D10 SD1_ SD1_ XTAL DATA CLK _AU 3 DIO OSC _AU DIO_ VDD V W ATA_ ATA_ ATA_ DATA DATA DATA 14 13 9 ATA_ ATA_ DATA DATA 5 1 ATA_ DIO W USB OTG _PW R CSPI CSPI 1_SC 1_M LK OSI BOO T_M ODE 0 POR _B MLB MLB SD2_ _SIG _CLK CLK CSI_ MCL K CSI_ D12 CSI_ D9 SD1_ DATA 2 DE_ B EXTA L_AU DIO W Y GND ATA_ ATA_ ATA_ DATA DATA DIOR 4 0 TES T_M ODE CSPI POW CLK_ GPIO WDO MLB SD2_ CSI_ 1_SS ER_ MOD 1_1 G_R _DAT DATA PIXC 0 FAIL E0 ST 2 LK CSI_ D15 USB PHY 2_D M USB SD1_ PHY CMD 2_DP GND Y 16 17 1 6 ATA_ ATA_ DATA DATA 11 7 2 3 4 4 5 5 6 6 7 7 8 8 9 10 11 12 SD2_ DATA 0 13 14 15 16 17 18 RTC K 18 19 USB PHY 1_R REF 19 20 20 Product Documentation All related product documentation for the i.MX35 processor is located at http://www.freescale.com/imx. i.MX35 Applications Processors for Automotive Products, Rev. 10 Freescale Semiconductor 145 7 Revision History Table 98 shows the revision history of this document. Note: There were no revisions of this document between revision 1 and revision 4 or between revision 6 and revision 7. Table 98. i.MX35 Data Sheet Revision History Revision Number Date 10 06/2012 • In Table 2, "Functional Differences in the i.MX35 Parts," on page 4, added two columns for part numbers MCIMX353 and MCIMX357. • Added Table 29, "Clock Input Tolerance," on page 32 in Section 4.9.3, “DPLL Electrical Specifications.” • Updated Table 39, "DDR2 SDRAM Timing Parameter Table," on page 51 for DDR2-400 values. • Updated Table 41, "DDR2 SDRAM Write Cycle Parameters," on page 53 for DDR2-400 values. • Added Table 15, "AC Requirements of I/O Pins," on page 25. • Updated WE4 parameter in Table 33, "WEIM Bus Timing Parameters," on page 38. 9 08/2010 • Updated Table 32, “NFC Timing Parameters.” • Updated Table 33, “WEIM Bus Timing Parameters.” 8 04/2010 • Updated Table 1, “Ordering Information.” • Updated Table 14, “I/O Pin DC Electrical Characteristics.” Substantive Change(s) 6 10/21/2009 • • • • Added information for silicon rev. 2.1 Updated Table 1, “Ordering Information.” Added Table 95, “Silicon Revision 2.1 Signal Ball Map Locations.” Added Table 97, “Silicon Revision 2.1 Ball Map—17 x 17, 0.8 mm Pitch.” 5 08/06/2009 • Filled in TBDs in Table 14. • Revised Figure 15 and Table 33 by removing FCE = 0 and FCE = 1. Added footnote 3 to the table. • Added Table 26, “AC Electrical Characteristics of DDR Type IO Pins in SDRAM Mode Max Drive (1.8 V).” 4 04/30/2009 Note: There were no revisions of this document between revision 1 and revision 4. • In Section 4.3.1, “Powering Up,” reverse positions of steps 5 and 6. • Updated values in Table 10, “i.MX35 Power Modes.” • Added Section 4.4, “Reset Timing.” • In Section 4.8.2, “AC Electrical Characteristics for DDR Pins (DDR2, Mobile DDR, and SDRAM Modes),” removed Slow Slew rate tables, relabeled Table 24, “AC Electrical Characteristics of DDR Type IO Pins in mDDR Mode,” and Table 25, “AC Electrical Characteristics of DDR Type IO Pins in SDRAM Mode,” to exclude mention of slew rate. • In Section 4.9.5.2, “Wireless External Interface Module (WEIM),” modified Figure 16, “Synchronous Memory Timing Diagram for Read Access—WSC = 1,” through Figure 21, “Muxed A/D Mode Timing Diagram for Synchronous Read Access— WSC = 7, LBA = 1, LBN = 1, LAH = 1, OEA = 7.” • In Section 4.9.6, “Enhanced Serial Audio Interface (ESAI) Timing Specifications,” modified Figure 36, “ESAI Transmitter Timing,” and Figure 37, “ESAI Receiver Timing,” to remove extraneous signals. Removed a note from Figure 36, “ESAI Transmitter Timing.” 1 12/2008 • Updated Section 4.3.1, “Powering Up.” • Section 4.7, “Module-Level AC Electrical Specifications”: Updated NFC, SDRAM and mDDR SDRAM timing. Inserted DDR2 SDRAM timing. 0 10/2008 Initial public release i.MX35 Applications Processors for Automotive Products, Rev. 10 146 Freescale Semiconductor How to Reach Us: Home Page: www.freescale.com Web Support: http://www.freescale.com/support USA/Europe or Locations Not Listed: Freescale Semiconductor, Inc. Technical Information Center, EL516 2100 East Elliot Road Tempe, Arizona 85284 1-800-521-6274 or +1-480-768-2130 www.freescale.com/support Europe, Middle East, and Africa: Freescale Halbleiter Deutschland GmbH Technical Information Center Schatzbogen 7 81829 Muenchen, Germany +44 1296 380 456 (English) +46 8 52200080 (English) +49 89 92103 559 (German) +33 1 69 35 48 48 (French) www.freescale.com/support Japan: Freescale Semiconductor Japan Ltd. Headquarters ARCO Tower 15F 1-8-1, Shimo-Meguro, Meguro-ku Tokyo 153-0064 Japan 0120 191014 or +81 3 5437 9125 [email protected] Asia/Pacific: Freescale Semiconductor China Ltd. Exchange Building 23F No. 118 Jianguo Road Chaoyang District Beijing 100022 China +86 10 5879 8000 [email protected] For Literature Requests Only: Freescale Semiconductor Literature Distribution Center P.O. Box 5405 Denver, Colorado 80217 1-800 441-2447 or +1-303-675-2140 Fax: +1-303-675-2150 LDCForFreescaleSemiconductor @hibbertgroup.com Document Number: MCIMX35SR2AEC Rev. 10 06/2012 Information in this document is provided solely to enable system and software implementers to use Freescale Semiconductor products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits or integrated circuits based on the information in this document. Freescale Semiconductor reserves the right to make changes without further notice to any products herein. Freescale Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters that may be provided in Freescale Semiconductor data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”, must be validated for each customer application by customer’s technical experts. Freescale Semiconductor does not convey any license under its patent rights nor the rights of others. Freescale Semiconductor products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Freescale Semiconductor product could create a situation where personal injury or death may occur. Should Buyer purchase or use Freescale Semiconductor products for any such unintended or unauthorized application, Buyer shall indemnify and hold Freescale Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Freescale Semiconductor was negligent regarding the design or manufacture of the part. RoHS-compliant and/or Pb-free versions of Freescale products have the functionality and electrical characteristics as their non-RoHS-compliant and/or non-Pb-free counterparts. For further information, see http://www.freescale.com or contact your Freescale sales representative. For information on Freescale’s Environmental Products program, go to http://www.freescale.com/epp. Freescale and the Freescale logo are trademarks of Freescale Semiconductor, Inc., Reg. U.S. Pat. & Tm. Off. All other product or service names are the property of their respective owners. ARM is the registered trademark of ARM Limited. ARM1136JF-S is the trademark of ARM Limited. © 2012 Freescale Semiconductor, Inc.