MV78230 ARMADA® XP Hardware Specifications MV78230 ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Hardware Specifications Doc. No. MV-S106687-00, Rev. H July 29, 2014, Preliminary Document Classification: Proprietary Information Marvell. Moving Forward Faster MV78230 Hardware Specifications Document Conventions Note: Provides related information or information of special importance. Caution: Indicates potential damage to hardware or software, or loss of data. Warning: Indicates a risk of personal injury. Document Status Doc Status: Preliminary Technical Publication: 0.xx For more information, visit our website at: www.marvell.com Disclaimer No part of this document may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, for any purpose, without the express written permission of Marvell. Marvell retains the right to make changes to this document at any time, without notice. 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H Page 2 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Revision History Revision History Table 1: Revision History R e v i s io n Date C o m m e n ts Rev. H July 29, 2014 Revised Release 1. Added a note in the following locations about contacting a Marvell® FAE if implementing a design integrating the LCD or FPD interfaces. • Preface on page 19 • Section 2.2.5, Flat Panel Display (FPD) Interface, on page 36 • Section 2.2.9, Liquid Crystal Display (LCD) Interface, on page 40 • Section 9.7.2, Flat Panel Display (FPD) Interface AC Timing, on page 112 • Section 9.7.3, Liquid Crystal Display Interface AC Timing, on page 114 2. In section Features on page 7, added the following bullet: - Programmable thermal sensor controller with ±5°C accuracy and overheat detection. 3. In Section 7.1, Power Up/Down Sequence, on page 76, updated Figure 6, Power Up Sequence Example, on page 77 to combine the CPU and Core voltages to a single line on the graph.. 4. In Section 7.2.1, Global System Reset (SYSRSTn), on page 77, updated the first 2 cases in which SYSRST_OUTn is asserted for a duration of 100 ms. 5. Updated Figure 69, 732-Pin FCBGA Package and Dimensions, on page 172 to remove the ball inline pitch dimension and to revise the dimension accuracy. Rev. G August 4, 2013 Revised Release Rev. F December 4, 2012 Revised Release Rev. E May 28, 2012 Revised Release Rev. D October 9, 2011 Revised Release Rev. C August 15, 2011 Revised Release Rev. B December 15, 2010 Revised Release Rev. A August 24, 2010 Initial Release Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 3 MV78230 Hardware Specifications THIS PAGE IS INTENTIONALLY LEFT BLANK Doc. No. MV-S106687-00 Rev. H Page 4 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary MV78230 ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors PRODUCT OVERVIEW ARMADA ® XP Family MV78230 Device The MV78230 is a complete system-on-chip (SoC) solution based on the Marvell® Core Processor embedded CPU technology. By leveraging the successful Marvell system controllers and extensive expertise in ARM instruction-set-compliant CPUs, the ARMADA XP Family of SoCs present a new level of performance, integration, and efficiency to raise the performance/power and performance/cost bar. The Marvell ARMADA XP device presents a new level of performance, integration and efficiency to make the system design simple and cost efficient. The ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors include the following devices: MV78230 MV78232 MV78260 MV78460 With full pin and software compatibility between the different devices, the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors enables full performance scalability to best fit the requirements of any specific application. This specification refers to the MV78230 only. For more information about other members of the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors, refer to the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Functional Specifications. The MV78230 integrates Dual Superscalar CPUs with: ARMv7-compliant CPU cores with the latest Marvell micro-architecture enhancements, with a double precision IEEE-compliant Floating Point Unit (FPU) per core Shared Level 2 (L2) 1MB cache Low-latency, high-bandwidth, tightly coupled DDR3/DDR3L memory controller The advanced I/O peripherals include PCI Express (PCIe) Gen1.1/2, USB2.0 with integrated PHYs, SATA ports, Ethernet, LCD, and TDM interfaces. To allow enhanced handshake and data flow, a full hardware I/O cache coherency scheme is implemented between the I/Os and the CPU. Optimized for low-power operation and providing advanced power management capabilities, the 40 nm process based MV78230 is ideally suited for a wide range of applications that require both high-performance and minimal power consumption. The rich and diversified interface mix of the MV78230 allows it to be the perfect solution for different types of applications and systems in various fields such as: Wireless infrastructure: Cellular, WiMax and WiFi Low-Mid range integrated routers Enterprise Network Storage (NAS, RAID, iSCSI) products Mid-High end consumer and Enterprise appliances (such as laser printers) Networking and Telecom Line cards Unified Threat Management boxes VoIP media gateways Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 5 MV78230 Hardware Specifications The on-chip Mbus architecture, a Marvell® proprietary crossbar interconnect for non-blocking any-to-any connectivity, enables concurrent transactions among multiple units. This design results in high system throughput, allowing system designers to create high-performance products. The innovative Coherency Fabric architecture provides a coherent interconnect between the CPUs themselves and between the CPUs and the I/O masters. This enables the system to operate either in Symmetrical Multi Processing (SMP) mode or Asymmetric Multi Processing (AMP) mode, with I/O cache coherency. In addition, the efficiency of the bus enables a high-frequency, high-bandwidth, and low-latency access time throughout the CPU memory subsystem. The pin and software compatibility with the other ARMADA XP devices, offers full performance scalability to best fit the requirements of any specific applications. MV78230 Block Diagram Shared L2 / SRAM 1 MB Networking Accelerator Buffer Management Flexible Parser and Classifier TCAM based 1K entries Deposit Dual ARM v6/v7 Dual ARM CPUv7 CPUs 1.6per GHz, with at FPU core withatFPU per core 2 GHz Secured Boot Advanced Power Management Discovery Coherency Fabric DDR3 32-bits Controller + ECC Device Bus, NAND Flash, SPI, UARTs, I2C, SDIO 3 x GbE / QSGMII 4 x IDMA 4 x XOR LCD Controller Mbus Crossbar Switch 2x Security Engines 2 x SATA II PCIe 2.0 x 1 PCIe2.0 x 4 / Quad x 1 7 SERDES Lanes Doc. No. MV-S106687-00 Rev. H Page 6 TDM Interface with 32 VoIP Channels 3 x USB2.0 Host / Device USB PHY x 3 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Features MV78230 Device FEATURES • • • • • • • • Symmetrical Multi Processing (SMP) and The MV78230 Includes: • Two high-performance, dual-issue CPU with Floating Point Unit • SMP/AMP operation modes • Supports I/O cache coherency • 1 MB L2 cache • Three 10/100/1000 Ethernet MAC controllers • High-bandwidth DDR3-1600 memory interface (32-bit SDRAM with ECC option) • Seven SERDES lanes with versatile muxing options for SGMII, QSGMII, PCIe, ETM, and SATA ports • PCI Express 2.0 x4 port; can also function as four x1 ports • Additional x1 PCI Express 2.0 port • Three USB Host/Device ports with integrated PHYs • Two integrated security cryptographic engines • Four IDMA engines • Integrated Storage Accelerator engine (four XOR DMA or iSCSI CRC engines) • TDM interface supporting up to 32 VoIP channels • 16-bit Device Bus with up to five chip selects, including NAND Flash support • Two SPI interfaces • SD/SDIO/MMC Host interface • LCD controller with both parallel and LVDS transmitter interfaces • Four 16750 compatible UART ports Asymmetric Multi Processing (AMP) modes • Compliant with ARMv7 architecture, published in • • • • • • • • • • • • • • • Two I2C interfaces Programmable Timers and Watchdogs Real Time Clock (RTC) Adaptive Voltage Scaling (AVS) Interrupt controller with priority scheme Secured boot Advanced power management • • • Internal Architecture • High-bandwidth, low-latency Coherency Fabric interconnect between the Marvell® Core Processor CPU and CPU memory subsystem • Advanced Mbus (crossbar extension) architecture with any-to-any concurrent I/O connectivity • Full I/O cache coherency Two Dual-Issue ARMv7-Compliant CPU • Up to 1.6 GHz • Superscalar RISC CPU with Harvard architecture issues two instructions per cycle • Single/double precision Floating Point Unit (VFP3-16) IEEE 754 compliant per core • the ARM Architecture Reference Manual, Second Edition Supports 32-bit instruction set for performance and flexibility Large Physical Address Expansion support—up to 40-bit address space Thumb-2 and Thumb-EE instruction set for code density Supports DSP instructions to boost performance for signal processing applications MMU-ARMv7 compliant VMSA MMU Management unit 4-KB L0 Instruction and data cache, direct mapping 32-KB L1 Instruction cache four-way, set-associative, physically indexed physically tagged, parity protected 32-KB L1 Data cache, eight-way, set-associative, physically indexed, physically tagged, parity protected MESI cache coherency scheme Hit-under-miss and multiple outstanding requests Advanced write coalescing support Variable stages pipeline—six to ten stages Out-of-order execution for increased performance In-order retire via a Reordering Buffer (ROB) Advanced branch prediction—32 Branch Target Buffer (BTB) and 1K entries Branch Prediction Unit (BPU) with GShare algorithm Branch Return Stack Point for subroutine call 64-bit internal data bus with 64-bit load/store instructions Endianness options—Little, Big, and Mixed Endianness JTAG/ARM-compatible ICE, and Embedded Trace Module (ETM) for enhanced real time debug capabilities 1-MB Unified L2/SRAM • Eight-way, write-back and write-through cache • Physically addressed • Non-blocking pipeline supports multiple outstanding requests and Hit Under Miss (HUM) operation • Per-way configured byte addressable SRAM or L2 cache Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 7 MV78230 Hardware Specifications • I/O direct access to/from L2 cache/SRAM for all High-Speed Integrated SERDES Lanes • Integrated seven low-power, high-speed SERDES PHYs, based on proven Marvell SERDES technology • Diverse muxing options of PCIe, SATA, SGMII, QSGMII, and ETM interfaces PCI Express Interfaces (x4, quad x1) • PCI Express Gen 1.1 at 2.5 Gbps / Gen 2.0 at 5 Gbps signaling • May be configured as either Root Complex or Endpoint • x1/x4 link width • Lane polarity reversal support • Maximum payload size of 128 bytes • Single Virtual Channel (VC-0) • Replay buffer support • Extended PCI Express configuration space • Power management: L0s and L1 ASPM active power state support; software L1 and L2 support • MSI/MSI-x support • Error message support Configured PCI Express x4 or Quad x1 Port • The PCI Express x4 port can be configured to function as four independent x1 ports, useful for interfacing multiple off-the-shelf PCI Express devices • Each of the quad x1 ports is PCI Express Base 2.0 compliant, has its own register file, and supports the same full feature set as the x4 port Additional identical PCI-Express Gen2.0 interface (x1) PCI Express Master Specific Features • Host to PCI Express bridge—translates CPU cycles to PCI Express memory or configuration cycles • Supports DMA bursts between memory and PCI Express • Supports up to four outstanding read transactions • Maximum read request of up to 128 bytes • Maximum write request of up to 128 bytes Mbus masters, allowing data storing directly into the L2/SRAM • ECC protected • Multi Gigabit Ethernet packet pre-loading, via a single CPU activation write transaction Three Gigabit Ethernet MACs • Supports 10/100/1000/2500 Mbps • Full wire speed receive and transmit of short packets • Layer 2/3/4 flexible packet modification and hardware forwarding engine • RGMII / MII / GMII / SGMII/ DRSGMII / QSGMII • Priority queueing on receive based on DA, VLAN-Tag, IP-TOS • Per queue egress rate shaping • Supports queuing based on Marvell® DSA Tag • Layer2/3/4 frame encapsulation detection • Supports long frames (up to 10K) on both receive and transmit • TCP/IP acceleration • IEEE 1588v2 support • EEE (Energy Efficient Ethernet) support • Hardware buffer management for off loading the software-intensive tasks of buffer memory allocation and release DDR3 SDRAM Controller • 32-bit interface with an ECC option • DDR3 up to 800 MHz (DDR3-1600) • Clock ratio of 1:N and 2:N between the DDR SDRAM and the CPU core, respectively • SSTL 1.8/1.5V/1.35 I/Os • Auto calibration of I/Os output impedance • Supports four SDRAM ranks • Supports all DDR devices densities up to 4 Gb • Supports all DIMM configurations (registered and unbuffered, x8, or x16 SDRAM devices) • DDR3 write and read leveling DIMM support • DDR3 address mirroring support • Supports DDR3 BL8 • Supports 2T and 3T modes to enable high-frequency operation even under heavy load configuration • Supports SDRAM bank interleaving • Supports up to 32 open pages • Supports up to 128-byte burst per single memory access PCI Express Target Specific Features • Supports reception of up to four read requests • Maximum read request of up to 4 KB • Maximum write request of up to 128 bytes • Supports PCI Express access to all of the device’s internal registers Three USB Ports • USB 2.0 compliant with integrated PHY • Each port can act as a USB Host or Device (peripheral) • Enhanced Host Controller Interface (EHCI) compatible as a host Doc. No. MV-S106687-00 Rev. H Page 8 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Features MV78230 Device • As a host, supports direct connection to all peripheral types (LS, FS, HS) • As a peripheral, connects to all host types (HS, FS) and hubs • Up to six independent endpoints, supporting control, interrupt, bulk, and isochronous data transfers • Dedicated DMA for data movement between memory and port Two Marvell® 3 Gbps (Gen2i) SATA Interfaces • Compliant with SATA II Phase 1 specifications - Supports SATA II Native Command Queuing (NCQ), up to 128 outstanding commands - First party DMA (FPDMA) full support - Backwards compatible with SATA I devices • Supports SATA II Phase 2 advanced features - 3 Gbps (Gen2i) SATA II speed - Port Multiplier (PM)—Performs FIS-based switching as defined in SATA working group port multiplier definition - Port Selector (PS)—Issues the protocol-based Out-Of-Band (OOB) sequence to select the active host port • Supports external SATA (eSATA) • Supports device 48-bit addressing • Supports ATA Tag Command Queuing • Enhanced-DMA (EDMA) for the SATA port - Automatic command execution without host intervention - Command queuing support, for up to 128 outstanding commands - Separate SATA request/response queues - 64-bit addressing support for descriptors and data buffers in system memory • Read ahead • Advanced interrupt coalescing • Advanced drive diagnostics via the ATA SMART command Two Cryptographic Engines • Hardware implementation on encryption and authentication engines to boost packet processing speed • Dedicated DMA to feed the hardware engines with data from the internal SRAM memory or from the DDR memory • Implements AES, DES, and 3DES encryption algorithms • Implements SHA2, SHA1 and MD5 authentication algorithms Four-Channel Independent DMA Controller • Chaining via linked-lists of descriptors • Moves data from any interface to any interface • Supports increment or hold on both the source and destination address Four XOR DMA Channels • Useful for RAID application • Supports XOR operation on up to eight source blocks • Supports iSCSI CRC-32 calculation • Supports normal DMA transfer as well TDM Interface • Supports up to 32 independent VoIP channels • Generic interface to standard SLIC/SLAC/DAA/codec devices • Compatible with standard PCM highway formats • Dedicated DMA engine per each RX and TX channel with flexible buffer allocation and size per channel • Fully flexible and configurable slot allocation up to 128 full duplex slots • Each TDM channel can be used either in High-Level Data Link Control (HDLC) Bit Oriented protocol mode or in Transparent Protocol mode Device Bus Controller • 16-bit multiplexed address/data bus • Supports different types of standard memory devices such as flash and ROM • Supports NAND Flash • Five chip selects with programmable timing • Optional external wait-state support • 8/16-bit width device support • Up to 128B burst per a single device bus access Two SPI Ports • General purpose SPI interface • Up to 8 chip selects • Supports boot from SPI Flash SD/SDIO/MMC Host Interface • 1-bit/4-bit SDmem, SDIO, and MMC cards • Up to 50 MHz • Hardware generate/check CRC on all command and data transaction on the card bus Four UART Interfaces • 16750 UART compatible • Each port has two pins for transmit and receive operations, and two pins for modem control functions • One channel also supports an integrated DMA, capable of up to 64-KB transfer Integrated programmable 32-bit timers/counters and watchdog timers Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 9 MV78230 Hardware Specifications Interrupt Controller • Advanced interrupt controller with interrupt prioritization mechanism Two I2C Interfaces • General purpose I2C master/slave • EEPROM Serial initialization support LCD Controller • Either parallel or serialized LVDS interface for connecting with remote panels • Up to 24 bits per pixel (bpp) RGB • Three overlay layers (video, graphics, and cursor) • YCbCr to RGB conversion • YCbCr 4:4:4, 4:2:2 or 4:2:0 input support • Color management (brightness, contrast, and hue) • Up-scaling and down-scaling support • Linear horizontal and vertical up-scaling • Color platter: Three 256 entries (2/4/8 bpp) for video and graphic overlay channels • Alpha blending support for color panels • Dedicated DMA for data movements between memory and port • Pulse Width Modulation control • Dedicated display PLL for maximum precision in interface clock ratio Real Time Clock Integrated BootROM with secured boot flow option Multi-purpose Pins dedicated for peripheral functions and General Purpose I/O • Each pin can be configured independently • GPIO inputs can be used to register interrupts from external devices, and generate maskable interrupts Clock Generation Support • Internal generation of CPU core clock, SDRAM clock, Core clock, PCIe clock, GbE clock, USB clock, and SATA clock from a single 25-MHz reference clock • Supports internal generation of spread spectrum clocking on the CPU and SDRAM clocks Advanced Power Saving Modes • Dynamic CPU frequency scaling for each of the cores • CPU wait for interrupt mode • Dynamic power down options • Selectable clock gating of different interfaces • SDRAM Self Refresh and Power Down modes • PCI Express, SGMII, USB, and SATA SERDES shutdown • Programmable thermal sensor controller with ±5°C accuracy and overheat detection. • Various wake up options FCBGA 23 x 23 mm package, pin compatible with the MV78460 and MV78260 devices Doc. No. MV-S106687-00 Rev. H Page 10 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Table of Contents Table of Contents Revision History ....................................................................................................................................... 3 Product Overview ....................................................................................................................................... 5 Features....................................................................................................................................................... 7 Preface ..................................................................................................................................................... 19 About this Document ..................................................................................................................................... 19 Related Documentation ................................................................................................................................. 19 Document Conventions ................................................................................................................................. 20 1 Typical Applications and System Configurations .................................................................. 21 1.1 NVR/DVR/Hybrid Video Surveillance Application ......................................................................................... 21 1.2 Enterprise Laser Printer Application .............................................................................................................. 22 1.3 Enterprise Wireless Access Point ................................................................................................................. 23 2 Pin Information .......................................................................................................................... 25 2.1 Pin Logic ....................................................................................................................................................... 25 2.2 Pin Descriptions ............................................................................................................................................ 27 2.3 Internal Pull-up and Pull-down Pins .............................................................................................................. 59 3 Unused Interface Strapping ...................................................................................................... 61 4 MV78230 Pin Map, Pin List, and Package Trace Lengths ..................................................... 63 5 Clocking ..................................................................................................................................... 64 5.1 Clock Domain ................................................................................................................................................ 64 5.2 Clock Frequency Configuration Options ........................................................................................................ 65 5.3 Spread Spectrum Clock Generator (SSCG) .................................................................................................. 66 6 Pin Multiplexing ......................................................................................................................... 67 6.1 Multi Purpose Pins Functional Summary ...................................................................................................... 67 6.2 Multi Purpose Pins Power Segments ............................................................................................................ 68 6.3 Multi Purpose Pins Functional Considerations .............................................................................................. 68 6.4 Gigabit Ethernet Pins Multiplexing on the MPP ............................................................................................. 69 6.5 LCD Pin Multiplexing on the MPP ................................................................................................................. 70 6.6 Serialized LVDS Transmitter ......................................................................................................................... 72 6.7 High-Speed SERDES Multiplexing ................................................................................................................ 74 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 11 MV78230 Hardware Specifications 7 Reset and Initialization .............................................................................................................. 76 7.1 Power Up/Down Sequence ........................................................................................................................... 76 7.2 Hardware Reset ............................................................................................................................................ 77 7.3 PCI Express Reset ........................................................................................................................................ 79 7.4 Power On Reset (POR) ................................................................................................................................. 80 7.5 Reset Configuration ...................................................................................................................................... 80 7.6 Serial ROM Initialization ................................................................................................................................ 85 7.7 Boot Sequence .............................................................................................................................................. 87 8 JTAG Interface ........................................................................................................................... 88 8.1 Instruction Register ....................................................................................................................................... 88 8.2 Bypass Register ............................................................................................................................................ 89 8.3 JTAG Scan Chain ......................................................................................................................................... 89 8.4 ID Register .................................................................................................................................................... 89 9 Electrical Specifications ........................................................................................................... 90 9.1 Absolute Maximum Ratings .......................................................................................................................... 90 9.2 Recommended Operating Conditions ........................................................................................................... 92 9.3 Thermal Power Dissipation ........................................................................................................................... 94 9.4 SoC Power Dissipation for Power Management Unit Low Power Modes ..................................................... 96 9.5 Current Consumption .................................................................................................................................... 98 9.6 DC Electrical Specifications ........................................................................................................................ 100 9.7 AC Electrical Specifications ........................................................................................................................ 108 9.8 Differential Interface Electrical Characteristics ............................................................................................ 145 10 Thermal Data ............................................................................................................................ 171 11 Package Mechanical Dimensions .......................................................................................... 172 12 Part Order Numbering/Package Marking .............................................................................. 173 12.1 Part Order Numbering ................................................................................................................................. 173 12.2 Package Marking ........................................................................................................................................ 174 Doc. No. MV-S106687-00 Rev. H Page 12 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary List of Tables List of Tables Revision History ....................................................................................................................................... 3 Table 1: Revision History ............................................................................................................................... 3 Product Overview ....................................................................................................................................... 5 Features....................................................................................................................................................... 7 Preface ..................................................................................................................................................... 19 1 Typical Applications and System Configurations ....................................................................... 21 2 Pin Information ............................................................................................................................... 25 3 Table 2: Pin Functions and Assignments Table Key .................................................................................... 27 Table 3: Interface Pin Prefixes ...................................................................................................................... 27 Table 4: Gigabit Ethernet Port Interface Pin Assignments ........................................................................... 29 Table 5: Serial Management Interface (SMI) Pin Description ....................................................................... 32 Table 6: Device Bus/NAND Flash Interface Pin Assignments ...................................................................... 33 Table 7: Multi Purpose Pin Assignments ...................................................................................................... 35 Table 8: Flat Panel Display (FPD) Interface Pin Description ........................................................................ 36 Table 9: Genera Purpose Pins (GPP) Pin Description ................................................................................. 37 Table 10: Inter-Integrated Circuit Interface (I2C) Pin Description ................................................................... 38 Table 11: JTAG Interface Pin Description ...................................................................................................... 39 Table 12: Liquid Crystal Display (LCD) Interface Pin Description ................................................................... 40 Table 13: Miscellaneous Signals Pin Description ........................................................................................... 41 Table 14: PCI Express (PCIe) Clocks/Reset Pin Description ......................................................................... 43 Table 15: Precise Timing Protocol (PTP) Interface Pin Description ............................................................... 44 Table 16: Real Time Clock (RTC) Interface Pin Description ........................................................................... 45 Table 17: Serial-ATA (SATA) Interface Pin Description .................................................................................. 46 Table 18: Secure Digital Input/Output (SDIO) Interface Pin Description ........................................................ 47 Table 19: SDRAM DDR3 Interface Pin Description ........................................................................................ 48 Table 20: Serial Peripheral Interface 0 (SPI0) Pin Description ....................................................................... 51 Table 21: Serial Peripheral Interface 1 (SPI1) Pin Description ....................................................................... 51 Table 22: Time Division Multiplexing (TDM) Interface Pin Description ........................................................... 52 Table 23: Universal Asynchronous Receiver Transmitter (UART) Interface Pin Description ......................... 53 Table 24: USB 2.0 Interface Pin Description .................................................................................................. 54 Table 25: SERDES Port Interface Pin Description ......................................................................................... 55 Table 26: Power Supply Pins .......................................................................................................................... 57 Table 27: Internal Pull-up Pins ........................................................................................................................ 59 Table 28: Internal Pull-down Pins ................................................................................................................... 60 Unused Interface Strapping ........................................................................................................... 61 Table 29: Unused Interface Strapping ............................................................................................................ 61 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 13 MV78230 Hardware Specifications 4 MV78230 Pin Map, Pin List, and Package Trace Lengths .......................................................... 63 5 Clocking ........................................................................................................................................... 64 Table 30: 6 Pin Multiplexing .............................................................................................................................. 67 Table 31: 7 8 9 Clock Frequency Options ............................................................................................................... 65 Gigabit Ethernet Pins Multiplexing .................................................................................................. 69 Table 32: LCD Interface Modes ...................................................................................................................... 70 Table 33: LCD Connectivity to LVDS .............................................................................................................. 73 Table 34: MV78230 SERDES Lanes Multiplex Options ................................................................................. 75 Reset and Initialization ................................................................................................................... 76 Table 35: Non-Core and Core Voltages ......................................................................................................... 76 Table 36: Reset Configuration Pins ................................................................................................................ 81 JTAG Interface ................................................................................................................................ 88 Table 37: Supported JTAG Instructions .......................................................................................................... 89 Table 38: IDCODE Register Map ................................................................................................................... 89 Electrical Specifications ................................................................................................................ 90 Table 39: Absolute Maximum Ratings ............................................................................................................ 90 Table 40: Recommended Operating Conditions ............................................................................................. 92 Table 41: Core and CPU Thermal Power Dissipation ..................................................................................... 94 Table 42: I/O Interface Thermal Power Dissipation ....................................................................................... 95 Table 43: SoC Power Dissipation ................................................................................................................... 96 Table 44: Current Consumption ...................................................................................................................... 98 Table 45: General 3.3V Interface (CMOS) DC Electrical Specifications ....................................................... 100 Table 46: General 2.5V Interface (CMOS) DC Electrical Specifications ....................................................... 101 Table 47: General 1.8V Interface (CMOS) DC Electrical Specifications ....................................................... 101 Table 48: Flat Panel Display Interface (LVDS) DC Electrical Specifications ................................................ 102 Table 49: SDRAM DDR3 (1.5V) Interface DC Electrical Specifications ....................................................... 103 Table 50: SDRAM DDR3L (1.35V) Interface DC Electrical Specifications ................................................... 104 Table 51: I2C Interface 3.3V DC Electrical Specifications ............................................................................ 105 Table 52: SPI Interface 3.3V DC Electrical Specifications ............................................................................ 105 Table 53: TDM Interface 3.3V DC Electrical Specifications .......................................................................... 106 Table 54: NAND Flash 3.3V DC Electrical Specification .............................................................................. 106 Table 55: NAND Flash 1.8V DC Electrical Specification .............................................................................. 107 Table 56: Reference Clock and Reset AC Timing Specifications ................................................................. 108 Table 57: FPD AC Timing Table ................................................................................................................... 112 Table 58: LCD AC Timing Table ................................................................................................................... 114 Table 59: RGMII AC Timing Table ................................................................................................................ 116 Table 60: GMII AC Timing Table .................................................................................................................. 118 Table 61: MII/MMII MAC Mode AC Timing Table ......................................................................................... 120 Table 62: SMI Master Mode AC Timing Table .............................................................................................. 122 Table 63: SDRAM DDR3 (667 MHz) Interface AC Timing Table ................................................................. 124 Table 64: SDRAM DDR3 (800 MHz) Interface AC Timing Table ................................................................ 125 Doc. No. MV-S106687-00 Rev. H Page 14 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary List of Tables Table 65: 10 MMC Host AC Timing Table ......................................................................................................... 130 Table 67: Device Bus Interface AC Timing Table ......................................................................................... 132 Table 68: SPI (Master Mode) AC Timing Table ............................................................................................ 134 Table 69: TDM Interface AC Timing Table ................................................................................................... 136 Table 70: HDLC Interface AC Timing Table ................................................................................................. 137 Table 71: I2C Master AC Timing Table ........................................................................................................ 139 Table 72: I2C Slave AC Timing Table .......................................................................................................... 139 Table 73: JTAG Interface AC Timing Table .................................................................................................. 141 Table 74: NAND Flash AC Timing Table ...................................................................................................... 143 Table 75: PCI Express Interface Differential Reference Clock Characteristics ............................................ 146 Table 76: PCI Express Interface Spread Spectrum Requirements ............................................................... 146 Table 77: PCI Express 1.1 Interface Driver and Receiver Characteristics ................................................... 147 Table 78: PCI Express 2 Interface Driver and Receiver Characteristics ...................................................... 148 Table 79: SATA I Interface Gen1i Mode Driver and Receiver Characteristics ............................................. 151 Table 80: SATA II Interface Gen2i Mode Driver and Receiver Characteristics ............................................ 153 Table 81: SATA II Interface Gen2m Mode Driver and Receiver Characteristics .......................................... 154 Table 82: USB Low Speed Driver and Receiver Characteristics .................................................................. 155 Table 83: USB Full Speed Driver and Receiver Characteristics ................................................................... 156 Table 84: USB High Speed Driver and Receiver Characteristics ................................................................. 157 Table 85: SGMII Interface Driver and Receiver Characteristics (1000BASE-X) ........................................... 159 Table 86: DR-SGMII Short Reach (SR) Driver and Receiver Characteristics .............................................. 161 Table 87: QSGMII Driver and Receiver Characteristics ............................................................................... 165 Table 88: sETM Interface Driver and Receiver Characteristics .................................................................... 169 Thermal Data ................................................................................................................................. 171 Table 89: 11 12 SDIO Host in High-Speed Mode AC Timing Table ....................................................................... 128 Table 66: Thermal Data for the MV78230 in FCBGA Package .................................................................... 171 Package Mechanical Dimensions ............................................................................................... 172 Part Order Numbering/Package Marking .................................................................................... 173 Table 90: MV78230 Part Order Options ....................................................................................................... 173 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 15 MV78230 Hardware Specifications List of Figures Revision History ....................................................................................................................................... 3 Product Overview ....................................................................................................................................... 9 Features..................................................................................................................................................... 11 Revision History ....................................................................................................................................... 3 Product Overview ..................................................................................................................................... 5 MV78230 Block Diagram .................................................................................................................. 6 Features ..................................................................................................................................................... 7 Preface ..................................................................................................................................................... 19 1 2 Typical Applications and System Configurations ....................................................................... 21 Figure 1: MV78230 in a Hybrid Surveillance Box Application ........................................................................ 22 Figure 2: MV78230 in an Enterprise Laser Printer Application ...................................................................... 23 Figure 3: MV78230 Enterprise Wireless Access Point .................................................................................. 24 Pin Information ............................................................................................................................... 25 Figure 4: MV78230 Pin Logic Diagram .......................................................................................................... 26 3 Unused Interface Strapping ........................................................................................................... 61 4 MV78230 Pin Map, Pin List, and Package Trace Lengths .......................................................... 63 5 Clocking ........................................................................................................................................... 64 6 Pin Multiplexing .............................................................................................................................. 67 Figure 5: 7 8 Pin Multiplexing and Connectivity Diagram .................................................................................... 72 Reset and Initialization ................................................................................................................... 76 Figure 6: Power Up Sequence Example ........................................................................................................ 77 Figure 7: Serial ROM Data Structure ............................................................................................................. 86 Figure 8: Serial ROM Read Example ............................................................................................................. 87 JTAG Interface ................................................................................................................................ 88 Figure 9: ETM-JTAG-AP-Parallel Mode ....................................................................................................... 88 Doc. No. MV-S106687-00 Rev. H Page 16 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary List of Figures 9 Electrical Specifications ................................................................................................................ 90 Figure 10: DEV_CLK_OUT and REFCLK_OUT Reference Clock Test Circuit ............................................. 110 Figure 11: DEV_CLK_OUT and REFCLK_OUT AC Timing Diagram ............................................................ 111 Figure 12: FPD AC Timing Diagram .............................................................................................................. 113 Figure 13: LCD Test Circuit ........................................................................................................................... 114 Figure 14: LCD Transmit AC Timing Diagram ............................................................................................... 115 Figure 15: RGMII Test Circuit ........................................................................................................................ 116 Figure 16: RGMII AC Timing Diagram ........................................................................................................... 117 Figure 17: GMII Test Circuit ........................................................................................................................... 118 Figure 18: GMII Output AC Timing Diagram .................................................................................................. 119 Figure 19: GMII Input AC Timing Diagram ..................................................................................................... 119 Figure 20: MII/MMII MAC Mode Test Circuit .................................................................................................. 120 Figure 21: MII/MMII MAC Mode Output Delay AC Timing Diagram ............................................................... 120 Figure 22: MII/MMII MAC Mode Input AC Timing Diagram ............................................................................ 121 Figure 23: MDIO Master Mode Test Circuit ................................................................................................... 122 Figure 24: MDC Master Mode Test Circuit .................................................................................................... 123 Figure 25: SMI Master Mode Output AC Timing Diagram ............................................................................. 123 Figure 26: SMI Master Mode Input AC Timing Diagram ................................................................................ 123 Figure 27: SDRAM DDR3 Interface Test Circuit ............................................................................................ 125 Figure 28: SDRAM DDR3 Interface Write AC Timing Diagram ..................................................................... 126 Figure 29: SDRAM DDR3 Interface Address and Control AC Timing Diagram ............................................. 126 Figure 30: SDRAM DDR3 Interface Read AC Timing Diagram ..................................................................... 127 Figure 31: Secure Digital Input/Output (SDIO) Test Circuit ........................................................................... 128 Figure 32: SDIO Host in High Speed Mode Output AC Timing Diagram ....................................................... 129 Figure 33: SDIO Host in High Speed Mode Input AC Timing Diagram .......................................................... 129 Figure 34: MMC Test Circuit .......................................................................................................................... 130 Figure 35: MMC High-Speed Host Output AC Timing Diagram ..................................................................... 131 Figure 36: MMC High-Speed Host Input AC Timing Diagram ........................................................................ 131 Figure 37: Device Bus Interface Test Circuit ................................................................................................. 132 Figure 38: Device Bus Interface Output Delay AC Timing Diagram .............................................................. 133 Figure 39: Device Bus Interface Input AC Timing Diagram ........................................................................... 133 Figure 40: SPI (Master Mode) Test Circuit .................................................................................................... 134 Figure 41: SPI (Master Mode) AC Timing Diagram ....................................................................................... 135 Figure 42: TDM Interface Test Circuit ............................................................................................................ 137 Figure 43: TDM Interface Output Delay AC Timing Diagram ......................................................................... 138 Figure 44: TDM Interface Input Delay AC Timing Diagram ............................................................................ 138 Figure 45: I2C Test Circuit ............................................................................................................................. 140 Figure 46: I2C Output Delay AC Timing Diagram .......................................................................................... 140 Figure 47: I2C Input AC Timing Diagram ....................................................................................................... 140 Figure 48: JTAG Interface Test Circuit .......................................................................................................... 141 Figure 49: JTAG Interface Output Delay AC Timing Diagram ....................................................................... 142 Figure 50: JTAG Interface Input AC Timing Diagram .................................................................................... 142 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 17 MV78230 Hardware Specifications 10 11 Figure 51: NAND Flash Test Circuit ............................................................................................................... 143 Figure 52: NAND Flash Input AC Timing Diagram ......................................................................................... 144 Figure 53: NAND Flash Output AC Timing Diagram ...................................................................................... 144 Figure 54: PCI Express Interface 1.1 Test Circuit .......................................................................................... 149 Figure 55: PCI Express Interface 2.0 Test Circuit .......................................................................................... 150 Figure 56: Low/Full Speed Data Signal Rise and Fall Time .......................................................................... 157 Figure 57: High Speed TX Eye Diagram Pattern Template ........................................................................... 158 Figure 58: High Speed RX Eye Diagram Pattern Template ........................................................................... 158 Figure 59: Tri-Speed Interface Driver Output Voltage Limits And Definitions ................................................ 160 Figure 60: Driver Output Differential Amplitude and Eye Opening ................................................................ 160 Figure 61: DR-SGMII Driver Output Voltage Limits and Definitions ............................................................... 162 Figure 62: DR-SGMII Driver Output Differential Voltage under Pre-emphasis .............................................. 163 Figure 63: DR-SGMII Driver Output Differential Amplitude and Eye Opening ............................................... 164 Figure 64: QSGMII Driver Output Voltage Limits and Definitions .................................................................. 167 Figure 65: Interconnect Insertion Loss ........................................................................................................... 167 Figure 66: Driver Output Differential Amplitude and Eye Opening ................................................................ 168 Figure 67: Driver Output Voltage Limits and Definitions ................................................................................ 170 Figure 68: Driver Output Differential Amplitude and Eye Opening ................................................................ 170 Thermal Data ................................................................................................................................. 171 Package Mechanical Dimensions ............................................................................................... 172 Figure 69: 12 732-Pin FCBGA Package and Dimensions .................................................................................. 172 Part Order Numbering/Package Marking .................................................................................... 173 Figure 70: Sample Part Number .................................................................................................................... 173 Figure 71: Package Marking and Pin 1 Location (Top View) ......................................................................... 174 Doc. No. MV-S106687-00 Rev. H Page 18 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Preface About this Document Preface About this Document This document provides the hardware specifications for the Marvell® MV78230 device. The hardware specifications include detailed pin information, configuration settings, electrical characteristics and physical specifications. This document is intended to be the basic source of information for designers of new systems. In this document, the MV78230 is often referred to as the “device”. Note Before designing a system implementing the Liquid Crystal Display (LCD) interface or the Flat Panel Display (FPD) interface, contact a Marvell® Field Applications Engineer (FAE). Related Documentation The following documents contain additional information related to the MV78230. For the latest revision, contact a Marvell representative. Titl e D oc u m e n t N um b e r ARMADA® XP Family of Highly Integrated Multi-Core ARMv7 Based SoC Processors Functional Specifications MV-S107021-00 MV78230/78x60 Design Guide MV-S301878-00 ARMADA® XP MP Core Highly Integrated Marvell ARMv7 SoC Processors Datasheet MV-S108492-00 MV78230/78x60 ARMADA® XP Family of Highly Integrated Multi-Core ARMv7 Based SoC Processors Functional Errata MV-S501280-00 MV78230/78x60 ARMADA® XP Family of Highly Integrated Multi-Core ARMv7 Based SoC Processors CPU Core Errata MV-S501281-00 See the Marvell Extranet website for the latest product documentation. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 19 MV78230 Hardware Specifications Document Conventions The following conventions are used in this document: Signal Range A signal name followed by a range enclosed in brackets represents a range of logically related signals. The first number in the range indicates the most significant bit (MSb) and the last number indicates the least significant bit (LSb). Example: DB_Addr[12:0] Active Low Signals # An n letter at the end of a signal name indicates that the signal’s active state occurs when voltage is low. Example: INTn State Names State names are indicated in italic font. Example: linkfail Register Naming Conventions Register field names are indicated by angle brackets. Example: <RegInit> Register field bits are enclosed in brackets. Example: Field [1:0] Register addresses are represented in hexadecimal format. Example: 0x0 Reserved: The contents of the register are reserved for internal use only or for future use. A lowercase <n> in angle brackets in a register indicates that there are multiple registers with this name. Example: Multicast Configuration Register<n> Reset Values Reset values have the following meanings: 0 = Bit clear 1 = Bit set Abbreviations Kb: kilobit KB: kilobyte Mb: megabit MB: megabyte Gb: gigabit GB: gigabyte Numbering Conventions Unless otherwise indicated, all numbers in this document are decimal (base 10). An 0x prefix indicates a hexadecimal number. An 0b prefix indicates a binary number. Doc. No. MV-S106687-00 Rev. H Page 20 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Typical Applications and System Configurations NVR/DVR/Hybrid Video Surveillance Application 1 Typical Applications and System Configurations The MV78230 can be used in a variety of applications. Examples of these applications are provided in the following sections. 1.1 NVR/DVR/Hybrid Video Surveillance Application Video surveillance applications, Network Video Recorders (NVR), and Digital Video Recorders (DVR) can also take advantage of the MV78230 SoC. The high-integration of the MV78230 that resides within the NVR box, with the high-performance core processor CPU, drives H.264 or MPEG-2 data streams from multiple camera banks that are connected over the GbE ports to various I/Os. These I/Os include storage (disks over PCIe or SATA interfaces) or remote host monitoring (over Ethernet interface). The TCP acceleration features offered by the device, and the ability to balance the work load on the CPUs handling the incoming TCP streams, enables the platform to support dozens of the high definition IP cameras. High-performance writes and reads to mass storage are an essential centerpiece for these applications, and the device offers outstanding performance in this arena. There are several storage expansion options with the two PCIe ports, offering five to eight high-speed, 5 Gbps PCIe lanes, and enabling connectivity to mass storage or DSP banks to interface analog cameras. The fluent PCIe-to-Memory and Memory-to-PCIe operations of the MV78230, the effective disk access, and the core processor CPU capability to successfully handle the high frame rate and resolution from a large number of sources, enables the device to support the application’s target number of analog cameras. The three USB ports with integrated PHYs, the SATA ports that can be used for eSATA extensions or a DVD write backup interface, with the LCD interface that can be used for a local view via VGA, and the integrated clock generation and security engine offer a complete SoC integrated solution at low power to make this SoC the ideal choice for such applications. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 21 MV78230 Hardware Specifications Figure 1 shows an example of MV78230 in a hybrid surveillance box application. Figure 1: MV78230 in a Hybrid Surveillance Box Application VGA LCD Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz 1 MB L2 Cache Device Bus Local Display Ethernet PHY Gigabit Ethernet NOR / NAND / SPI Flash USB Port MV78230 USB Port Gigabit Ethernet . . USB Port Gigabit Ethernet Switch Advanced Power Management PCIe Gen2.0 x1 DSP …. …. …. PCIe Gen2.0 x1 I2C , UART, GPIOs PCIe Gen2.0 x1 External Hard Drive Serial Ports, Alarms In/Out SATA SATA eSATA / DVD Writer DSP PCIe to SATA Analog Cameras 1.2 DDR3 Memory Coherency Fabric Network IP Cameras 32-bit DRAM + ECC Option Hard Drives Enterprise Laser Printer Application The MV78230 I/O integration, low power, strong core processor CPUs, and an on-chip Floating Point Unit (FPU) makes the device an ideal solution for high-performance enterprise printer applications. The device integrates several I/O peripherals that result in a smaller, simpler board design with lower manufacturing cost. The device’s advanced power save modes enable a power-saving, environmentally friendly, green printer design that meets the restrictive power consumption requirements of worldwide energy regulations, such as Energy Star, EuP, and Top Runners. In addition to system level power save modes such as DRAM power save modes, Energy Efficient Ethernet, PCIe, and USB power save modes, the MV78230 offers chip level power save options that include power down modes, standby modes, clock throttling modes. To complete this device’s efficient operation, it offers diverse waking options from power save modes, such as: Diversified Wake On LAN (WOL) options Wake On USB Wake On GPIO Doc. No. MV-S106687-00 Rev. H Page 22 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Typical Applications and System Configurations Enterprise Wireless Access Point It also guarantees zero packet loss during the wake-up period until the CPU is powered up and ready to process the incoming packets. The multiple PCIe lanes allow printer designers to connect imaging ASICs to the x4 PCIe interfaces, and use the x1 configurations for other PCIe peripherals. The three on-chip USB ports can connect to PCs, scanners, fax machines, USB flash drives, or wireless connectivity devices. The integrated SATA interface eliminates the need for an external SATA controller for the printer’s spooling hard drive. The integrated LCD controller is capable of supporting up to 24 bpp, with high resolution. It can be used to interface with the printer’s LCD panel. The integrated SPI controller provides the option to interface with an LCD screen, if it is used as a touch screen. As in most printers, the LCD panel is located relatively far from the CPU, the device provides LVDS transmitters for the clock and data to connect between the device’s LCD logic and the remote LCD panel. Figure 2 shows a MV78230 SoC in an enterprise laser printer application. Figure 2: MV78230 in an Enterprise Laser Printer Application Gigabit Ethernet Network USB Port USB Flash Drive Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz USB Port Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz 1 MB L2 Cache 32-bit DRAM DDR3 Memory Device Bus NOR/NAND/ SPI Flash Coherency Fabric PC LCD LVDS Transmitter MV78230 USB Port SPI External Hard Drive Advanced Power Management Security Acceleration PCIe Gen2.0 x4 Image ASIC 1.3 PCIe Gen2.0 x1 I2C, UART, GPIOs LCD Panel with Touch Screen Serial Ports SATA Customer ASIC Hard Drive Enterprise Wireless Access Point The MV78230 is a perfect fit for Enterprise class wireless access point. The two CPUs may be used either in AMP mode, where one core is handling the traffic and the other core handles the application layer, or in SMP mode where both cores are running symmetrically as a single ultra-powerful CPU core that can handle both tasks. The high-bandwidth PCIe ports (Gen2.0, 5 Gbps) provide the needed connectivity to the WiFi modules, while the internal proprietary MBus interconnect accelerates the data flow to and from the memory. The integrated security accelerator can be used for secured traffic exchange with the LAN, while the USB/SDIO ports can be used for software upgrade access. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 23 MV78230 Hardware Specifications The low power consumption of the device enables the access point solution to be powered by Ethernet (POE) ready. Figure 3 shows the MV78230 in a typical wireless access point application. Figure 3: MV78230 Enterprise Wireless Access Point Ethernet PHY LAN Ethernet PHY Gigabit Ethernet Gigabit Ethernet LAN Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz Marvell® Core Processor CPU ARMv7 32K-I, 32K-D Up to 1.6 GHz 1 MB L2 Cache 32- bit DRAM Device Bus DDR3 Memory NOR/NAND/ SPI Flash Coherency Fabric WiFi USB Port PCIe x 1 MV 78230 802.11 N 2.4G WiFi PCIe x1 802.11 N 5G POE Ready Doc. No. MV-S106687-00 Rev. H Page 24 I2C, UART Serial Ports Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Logic 2 Pin Information This section provides the pin logic diagram for each device and a detailed description of the pin assignments and their functionality. 2.1 Pin Logic This section provides the pin logic diagram for the MV78230. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 25 MV78230 Hardware Specifications Figure 4: MV78230 Pin Logic Diagram DEV_A [2:0] Flat Panel Display DEV_A D[15:0] LVLCD_CLKOUT/LVLCD_CLKOUTn LVLCD[3:0]/LVLCDn[3:0] DEV_A LE[1:0] DEV_B OOTCSn DEV_B URSTn LCD_CLK Device Bus DEV_CSn[3:0] DEV_OEn LCD_D[23:0] LCD Parallel Interface LCD_DE LCD_HSYNC DEV_REA DYn LCD_P WM DEV_WEn[1:0] LCD_VSYNC DEV_CLK_OUT LCD_EXT_REF_CLK JT_RSTn GE0_COL JT_CLK JT_TDI GE0_CRS JTAG Interface GE0_RXCLK JT_TDO GE0_RXD[7:0] GMII/MII Interface JT_TM S_CORE JT_TM S_CP U GE0_RXDV GE0_RXERR GE0_TXCLK REF_CLK_XIN GE0_TXD[7:0] XOUT GE0_TXEN REFCLK_OUT GE0_TXCLKOUT M Rn CDRn SYSRST_OUTn GE<n>_RXD[3:0] Miscellaneous SYSRSTn GE<n>_RXCTL RGMII Interface CORE_A VS_FB CP U_A VS_FB GE<n>_RXCLK GE<n>_TXD[3:0] GE<n>_TXCTL GE<n>_TXCLKOUT P EX0_CLK_P /N P EX1_CLK_P /N n = 0 thru 1 PCIe Clocks/Reset P CIe_CLKREQ[1:0] SMI Interface P CIe_RSTOUTn RTC_XIN RTC_XOUT GE_M DIO P TP _CLK RTC Interface PTP Interface RTC_A LA RM n P TP _EVENT_REQ P TP _TRIG_GEN SD0_CLK SD0_CM D GE_M DC TDM _INT[7:0]n SDIO/MMC Interface SD0_D[3:0] TDM _RSTn TDM Interface TDM _DRX TDM _DTX M _A [15:0] TDM _FSYNC M _B A [2:0] TDM _P CLK M _CA Sn SATA Interface M _CB [7:0] M _CKE[3:0] SA TA <n>_P RESENT_A CTIVEn n = 0 thru 1 M _CLKOUT/M _CLKOUTn[3:0] M _CSn[3:0] SERDES Interface M _DM [4:0] M _DQ[31:0] M _DQS/M _DQSn[4:0] SDRAM DDR3 Interface SRD<n>_RX_P /N SRD<n>_TX_P /N n = 0 thru 6 M _ODT[3:0] SP I<n>_CSn[7:0] M _RA Sn SPI Interface M _RESETn M _WEn SP I<n>_M ISO SP I<n>_M OSI SP I<n>_SCK M _B B n = 0 thru 1 M _VTT_CTRL M _DECC_ERR USB <n>_DP USB <n>_DM I2C Interface UA <n>_RXD UART Interface NF_RB n NF_IO[15:0] TWSI<n>_SDA n = 0 thru 1 USB Interface n = 0 thru 2 NF_CLE/NF_A LE TWSI<n>_SCK NAND Flash Interface UA <n>_TXD UA <n>_CTS UA <n>_RTS n = 0 thru 3 NF_REn/NF_WEn Doc. No. MV-S106687-00 Rev. H Page 26 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2 Pin Descriptions This section details all the pins for the different interfaces providing a functional description of each pin and pin attributes. Table 2 defines the abbreviations and acronyms used in the pin description tables. Table 2: Pin Functions and Assignments Table Key Te r m D e fi n it io n <n> Represents port number when there are more than one ports Analog Analog Driver/Receiver or Power Supply Calib Calibration pad type CML Current Mode Logic CMOS Complementary Metal-Oxide-Semiconductor DDR Double Data Rate GND Ground Supply HCSL High-speed Current Steering Logic I Input I/O Input/Output LVDS Low-Voltage Differential Signaling O Output OD Open Drain pin Power Power Supply SDR Single Data Rate SSTL Stub Series Terminated Logic t/s Tri-State pin TS Tri-State Value XXXn n - Suffix represents an Active Low Signal Table 3: Interface Pin Prefixes In t e r f a c e Prefix Gigabit Ethernet GE_ JTAG JT_ Liquid Crystal Display LCD_ LCD Flat Panel Display (LVDS) LVLCD_ SDRAM M_ Misc N/A Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 27 MV78230 Hardware Specifications Table 3: Interface Pin Prefixes (Continued) In t e r f a c e Prefix MPP N/A NAND Flash NF_ PCI Express PEX_ PCIe_ Precise Time Protocol PTP_ Real Time Clock RTC_ Secure Digital Input/Output SDIO_ SERDES SRD_ SPI SPI_ TDM TDM_ I2C TWSI_ UART UA_ USB USB_ Doc. No. MV-S106687-00 Rev. H Page 28 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.1 Gigabit Ethernet Port Interface Pin Assignments Note Table 4: The GE0/GE1 signals are implemented on the Multi Purpose Pin Interface. See Section 6, Pin Multiplexing, on page 67. Gigabit Ethernet Port Interface Pin Assignments Pin Name I/O P in Ty pe Power R a il Description O CMOS VDDO_A RGMII Transmit Clock Provides 125 MHz for 1000 Mbps, 25 MHz for 100 Mbps, and 2.5 MHz for 10 Mbps. All RGMII output pins are referenced to GE0_TXCLKOUT GbE Port0 GE0_ TXCLKOUT GMII Transmit Clock All GMII output pins are referenced to GE0_TXCLKOUT. GE0_TXCLK I CMOS VDDO_B MII Transmit Reference Clock This clock is provided by an external PHY device connected to the MAC. All MII output pins are referenced to GE0_TXCLK. GE0_TXD[3:0] O CMOS DDR VDDO_A RGMII Transmit Data Contains the transmit data nibble outputs that run at double data rate. Bits [3:0] are presented on the rising edge of GE0_TXCLKOUT. CMOS SDR MII Transmit Data This bus is referenced to GE0_TXCLK. GMII Transmit Data This bus is referenced to GE0_TXCLKOUT GE0_TXD[7:4] O CMOS SDR VDDO_A GMII Transmit Data This bus is referenced to GE0_TXCLKOUT. GE0_TXCTL/ GE0_TXEN O CMOS DDR VDDO_A RGMII Transmit Control A logical derivative of transmit data enable (TXEN) on GE0_TXCLKOUT rising edge, and data error (TXERR) on GE0_TXCLKOUT falling edge. CMOS SDR MII Transmit Enable Indicates that the packet is being transmitted on the data lines. This pin is referenced to GE0_TXCLK. GMII Transmit Enable Indicates that the packet is being transmitted on the data lines. This pin is referenced to GE0_TXCLKOUT. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 29 MV78230 Hardware Specifications Table 4: Gigabit Ethernet Port Interface Pin Assignments (Continued) Pin Name I/O P in Ty pe Power R a il Description GE0_CRS I CMOS VDDO_B MII Carrier Sense Indication This signal is relevant for half-duplex mode only. This signal is asynchronous. GMII Carrier Sense Indication This signal is relevant for half-duplex mode only. This signal is asynchronous. GE0_RXD[3:0] I CMOS DDR VDDO_A CMOS SDR RGMII Receive Data Contains the receive data nibble inputs that run at double data rate. Bits [3:0] are presented on the rising edge of GE0_RXCLK. MII Receive Data This bus is referenced to GE0_RXCLK. GMII Receive Data This bus is referenced to GE0_RXCLK. GE0_RXD[7:4] I CMOS SDR VDDO_A GMII Receive Data This bus is referenced to GE0_RXCLK. GE0_RXERR I CMOS SDR VDDO_B MII Receive Error This pin is referenced to GE0_RXCLK. GMII Receive Error This pin is referenced to GE0_RXCLK. GE0_RXCTL/ GE0_RXDV I CMOS DDR VDDO_A CMOS SDR RGMII Receive Control A logical derivative of receive data valid (RXDV) on GE0_RXCLK rising edge, and data error (RXERR) on GE0_RXCLK falling edge. MII Receive Data Valid This pin is referenced to GE0_RXCLK. GMII Receive Data Valid This pin is referenced to GE0_RXCLK. GE0_RXCLK I CMOS VDDO_A RGMII Receive Clock Receives 125 MHz for 1000 Mbps, 25 MHz for 100 Mbps, and 2.5 MHz for 10 Mbps. All RGMII input pins are referenced to GE0_RXCLK. MII Receive Clock RXD, RXDV, and RXERR pins are referenced to GE0_RXCLK. GMII Receive Clock RXD, RXDV, and RXERR pins are referenced to GE0_RXCLK. GE0_COL I CMOS VDDO_B MII Collision Indication This signal is relevant for half-duplex mode only. This signal is asynchronous. Doc. No. MV-S106687-00 Rev. H Page 30 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions Table 4: Gigabit Ethernet Port Interface Pin Assignments (Continued) Pin Name I/O P in Ty pe Power R a il Description GE1_ TXCLKOUT O CMOS VDDO_B RGMII Transmit Clock Provides 125 MHz for 1000 Mbps, 25 MHz for 100 Mbps, and 2.5 MHz for 10 Mbps. All RGMII output pins are referenced to GE1_TXCLKOUT. GE1_TXD[3:0] O CMOS DDR VDDO_B RGMII Transmit Data Contains the transmit data nibble outputs that run at double data rate. Bits [3:0] are presented on the rising edge of GE1_TXCLKOUT. GE1_TXCTL O CMOS DDR VDDO_B RGMII Transmit Control A logical derivative of transmit data enable (TXEN) on GE1_TXCLKOUT rising edge, and data error (TXERR) on GE1_TXCLKOUT falling edge. GE1_RXD[3:0] I CMOS DDR VDDO_B RGMII Receive Data Contains the receive data nibble inputs that run at double data rate. Bits [3:0] are presented on the rising edge of GE1_RXCLK. GE1_RXCTL I CMOS DDR VDDO_B RGMII Receive Control A logical derivative of receive data valid (RXDV) on GE1_RXCLK rising edge, and data error (RXERR) on GE1_RXCLK falling edge. GE1_RXCLK I CMOS VDDO_B RGMII Receive Clock Receives 125 MHz for 1000 Mbps, 25 MHz for 100 Mbps, and 2.5 MHz for 10 Mbps. All RGMII input pins are referenced to GE1_RXCLK. GbE Port1 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 31 MV78230 Hardware Specifications 2.2.2 Table 5: Serial Management Interface (SMI) Serial Management Interface (SMI) Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n GE_MDC O CMOS VDDO_A Serial Management Interface Data Clock Provides the timing reference for the transfer of the GE_MDIO signal. NOTE: When not used, can be left NC. This pin has an integrated pull-down resistor. GE_MDIO I/O CMOS SDR VDDO_A Serial Management Interface Data Input/Output Must be pulled up to VDDO_A using a 2.0 kilohm resistor. NOTE: When not used, must be pulled up to VDDO_A. Doc. No. MV-S106687-00 Rev. H Page 32 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.3 Table 6: Device Bus/NAND Flash Interface Pin Assignments Device Bus/NAND Flash Interface Pin Assignments Pin Name I/ O P in Ty p e P ow e r Rail Description DEV_CSn[3:0] O CMOS SDR VDDO_ DEV For a Device bus, used as the device bus chip select that corresponds to ranks [3:0]. NOTE: These pins have integrated pull-up resistors. For a NAND Flash interface, used as a chip enable signal. NOTE: DEV_CSn[0] is the boot chip select for the NAND Flash Controller 2.0, only. DEV_BOOTCSn O CMOS SDR VDDO_ DEV Device Bus Boot Chip Select NOTE: This pin has an integrated pull-up resistor. When the boot device is a NAND Flash interface, use DEV_CSn[0] as the boot chip select for the NAND Flash Controller 2.0. DEV_OEn/ DEV_A[15] O CMOS SDR VDDO_ DEV For a Device bus, used as device bus output enable. Used as DEV_A[15] (device address bus) during first ALE cycle (DEV_ALE[1]). NOTE: This pin has an integrated pull-up resistor. For a NAND Flash interface, used as NF_REn. DEV_WEn[1:0]/ DEV_A[16] O CMOS SDR VDDO_ DEV For a Device bus, used as a device bus byte write enable (bit per byte). DEV_WEn[0] is used as DEV_A[16] (device address bus) during first ALE cycle (DEV_ALE[1]). NOTE: DEV_WEn[0] has an integrated pull-up resistor. DEV_WEn[1] has an integrated pull-down resistor. For the NAND Flash interface, see the functional specification for further information on their usage. For a NAND Flash interface, DEV_WEn[0] is used as NF_WEn. DEV_ALE[1:0] O CMOS SDR VDDO_ DEV Device Bus Address Latch Enable NOTE: These pins have integrated pull-down resistors. DEV_AD[7:0]/ DEV_A[13:6]/ DEV_A[26:19] t/s I/O CMOS SDR VDDO_ DEV For a Device bus, used as DEV_AD[7:0] (device data bus) during the data phase. Driven by MV78230 on write access, and by the device on read access. Used as DEV_A[13:6] (device address bus) during first ALE cycle (DEV_ALE[1]). Used as DEV_A[26:19] (device address bus) during second ALE cycle (DEV_ALE[0]). NOTE: These pins have integrated pull-up/down resistors. For a NAND Flash interface, used as NF_IO[7:0]. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 33 MV78230 Hardware Specifications Table 6: Device Bus/NAND Flash Interface Pin Assignments (Continued) Pin Name I/ O P in Ty p e P ow e r Rail Description DEV_AD[15:8]/ DEV_A[14]/ DEV_A[15] t/s I/O CMOS SDR VDDO_ DEV For a Device bus, used as DEV_AD[15:8] (device data bus) during the data phase. Driven by MV78230 on write access, and by the device on read access. DEV_AD[8] is used as DEV_A[14] (device address bus) during first ALE cycle (DEV_ALE[1]). DEV_AD[8] is used as DEV_A[15] (device address bus) during second ALE cycle (DEV_ALE[0]). NOTE: These pins have integrated pull-up/down resistors. For a NAND Flash interface, used as NF_IO[15:8]. DEV_A[2:0]/ DEV_A[5:3]/ DEV_A[18:16] t/s I/O CMOS SDR VDDO_ DEV For a Device bus, used as the device bus address. DEV_A[2:0] is used during the data phase. DEV_A[2:0] is not latched, but connected directly to the device. It is an incrementing address in case of burst access. Used as DEV_A[5:3] during the first ALE cycle (DEV_ALE[1]). Used as DEV_A[18:16] during the second ALE cycle (DEV_ALE[0]). NOTE: These pins have integrated pull-up/down resistors. For a NAND Flash interface: • DEV_A[0] is NF_CLE (Command Latch Enable) • DEV_A[1] is NF_ALE (Address Latch Enable) DEV_READYn I CMOS SDR VDDO_ DEV For a Device bus, used as the Device READY signal. Used as cycle extender when interfacing a slow device. When inactive during a device access, the access is extended until DEV_READYn assertion. NOTE: This pin has an integrated pull-down resistor. DEV_BURSTn/ DEV_LASTn O CMOS SDR VDDO_ DEV Device Burst/Device Last NOTE: This signal is multiplexed on MPP, see Section 6.1, Multi Purpose Pins Functional Summary, on page 67. DEV_CLK_OUT O CMOS SDR VDDO_ DEV Device Clock Output Clock reference when in synchronous device bus mode. The pin can be configured to drive a clock running at 1:N of TCLK rate. NOTE: This signal is multiplexed on MPP, see Section 6.1, Multi Purpose Pins Functional Summary, on page 67. NF_RBn I CMOS SDR VDDO_D EV NAND Flash READY/BUSY signal to indicate the target status. When the signal is low, it indicates that one or more operations are in progress. NOTE: This signal is multiplexed on MPP, see Section 6.1, Multi Purpose Pins Functional Summary, on page 67. Doc. No. MV-S106687-00 Rev. H Page 34 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.4 Multi Purpose Pin Assignment Note Table 7: See Section 6, Pin Multiplexing, on page 67 for additional information about the MPP pins. Multi Purpose Pin Assignments Pin Name I/O P in Ty p e Power R a il s D e sc r ip ti on MPP[11:0] t/s I/O CMOS VDDO_A Multi Purpose Pins Various functionalities NOTE: These pins have internal pull-up/down resistors. MPP[23:12] t/s I/O CMOS VDDO_B Multi Purpose Pins Various functionalities NOTE: These pins have internal pull-up/down resistors. MPP[35:24] t/s I/O CMOS VDDO_C Multi Purpose Pins Various functionalities NOTE: These pins have internal pull-up/down resistors. MPP[47:36] t/s I/O CMOS VDDO_D Multi Purpose Pins Various functionalities NOTE: These pins have internal pull-up/down resistors. MPP[48] t/s I/O CMOS VDDO_ DEV Multi Purpose Pin Various functionalities NOTE: These pins have internal pull-up/down resistors. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 35 MV78230 Hardware Specifications 2.2.5 Flat Panel Display (FPD) Interface Note Table 8: Before designing a system implementing the Flat Panel Display (FPD) interface, contact a Marvell® Field Applications Engineer (FAE). When unused, can be left unconnected. Flat Panel Display (FPD) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n LVLCD_CLKOUTn LVLCD_CLKOUT O LVDS VDDO_FPD Differential LVDS pixel clock output. LVLCDn[3:0] LVLCD[3:0] O LVDS VDDO_FPD Differential LVDS data output. Doc. No. MV-S106687-00 Rev. H Page 36 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.6 General Purpose Pins (GPP) Each individual pin can be defined as an input, output, or edge-sensitive interrupt input. These pins can be used for indications retrieving or for peripherals control. Table 9: Genera Purpose Pins (GPP) Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n GPIO[11:0] I/O CMOS VDDO_A General Purpose Pin(s) GPIO[23:12] I/O CMOS VDDO_B General Purpose Pin(s) GPIO[35:24] I/O CMOS VDDO_C General Purpose Pin(s) GPIO[47:36] I/O CMOS VDDO_D General Purpose Pin(s) GPIO[48] I/O CMOS VDDO_ DEV General Purpose Pin(s) Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 37 MV78230 Hardware Specifications 2.2.7 Inter-Integrated Circuit Interface (I2C) I2C and TWSI both refer to the same interface. Either name can be used in this document. Table 10: Inter-Integrated Circuit Interface (I2C) Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n Where <n> represents numbers 0 thru 1 TWSI<n>_SCK I/O OD CMOS VDDO_MISC TWSI (I2C) Serial Clock Serves as output when acting as a TWSI (I2C) master. Serves as input when acting as a TWSI (I2C) slave. NOTE: Requires a 4.7 kohm pull-up resistor to VDDO_MISC. TWSI<n>_SDA I/O OD CMOS SDR VDDO_MISC TWSI (I2C) Serial Data/Address Address or write data driven by the TWSI (I2C) master or read response data driven by the TWSI (I2C) slave. NOTE: Requires a 4.7 kohm pull-up resistor to VDDO_MISC. Doc. No. MV-S106687-00 Rev. H Page 38 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.8 JTAG Interface The device supports a JTAG interface and is compliant with the IEEE 1149.1 standard. It supports mandatory and optional boundary scan instructions. Table 11: JTAG Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n JT_CLK I CMOS VDDO_MISC JTAG Test Clock JT_TDI, JT_TDO, JT_TMS_CORE and JT_TMS_CPU are referenced to this clock. NOTE: This pin has an integrated pull-down resistor. JT_TDI I CMOS SDR VDDO_MISC JTAG Test Data Input Sampled on JT_CLK rising edge. NOTE: This pin has an integrated pull-up resistor. JT_TDO O CMOS SDR VDDO_MISC JTAG Test Data Output Driven on JT_CLK falling edge. JT_TMS_CORE I CMOS SDR VDDO_MISC JTAG Test Mode Select Sampled on JT_CLK rising edge. TMS signal for boundary scan mode (see the JTAG Interface section). NOTE: When unused, must be pulled up to VDDO_MISC. JT_TMS_CPU I CMOS SDR VDDO_MISC JTAG Test Mode Select Sampled on JT_CLK rising edge. TMS signal for CPU debugger and trace mode (see the JTAG Interface section). CPU for debugger connectivity NOTE: This pin has an integrated pull-up resistor. JT_RSTn I CMOS VDDO_MISC JTAG Test Asynchronous Reset NOTE: This pin has an integrated pull-down resistor. If this pull-down conflicts with other devices, the JTAG tool must not use this signal. This signal is not mandatory for the JTAG interface, since the TAP (Test Access Port) can be reset by driving the JT_TMS signal HIGH for 5 JT_CLK cycles. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 39 MV78230 Hardware Specifications 2.2.9 Liquid Crystal Display (LCD) Interface The device supports the following resolutions: One layer: Up to 1024x768 Two layers: Up to 1024x600 For the targeted resolution, select the 25 MHz or 27 MHz reference clock. Note Before designing a system implementing the Liquid Crystal Display (LCD) interface, contact a Marvell® Field Applications Engineer (FAE). This interface is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Table 12: Liquid Crystal Display (LCD) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n LCD_CLK O CMOS VDDO_C LCD Pixel Clock LCD_E, LCD_D[23:0], LCD_HSYNC, and LCD_VSYNC are referenced to this clock. LCD_D[11:0] O CMOS SDR VDDO_A LCD Data Bus This signal is referenced to LCD_CLK. NOTE: The power rail is determined by which MPP pin is configured to support these signals. For more information, see Section 6, Pin Multiplexing. LCD_D[23:12] VDDO_B LCD_E O CMOS SDR VDDO_C LCD Data Enable (pixel valid indication) This signal is referenced to LCD_CLK. LCD_PWM O CMOS VDDO_C LCD Pulse Width Modulation Control LCD_EXT_REF_CLK I CMOS VDDO_C LCD Reference clock for generating LCD pixel clock when internal clock is unused. LCD_HSYNC O CMOS SDR VDDO_C LCD Horizontal Synchronization This signal is referenced to LCD_CLK. If an external VGA DAC is used, this signal can control the signals delay to compensate for the external DAC pipeline delay. LCD_VSYNC O CMOS SDR VDDO_C LCD Vertical Synchronization This signal is referenced to LCD_CLK. If an external VGA DAC is used, this signal can control the signals delay to compensate for the external DAC pipeline delay. Doc. No. MV-S106687-00 Rev. H Page 40 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.10 Miscellaneous Signals The Miscellaneous signals list contains clocks, reset, and PLL related signals. Table 13: Miscellaneous Signals Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n CDRn I CMOS VDDO_MISC Active low, CPU Debugger Reset input. May be used by the debugger logic to reset the device. NOTE: This pin is internally pulled up. MRn I CMOS VDDO_MISC Active-Low, Manual Reset Input MRn is the connected within the SoC to the interval Power on Reset (POR) logic, therefore triggering the assertion of the SYSRST_OUTn pin. The POR maintains the assertion of the SYSRST_OUTn pin as long as the MRn is asserted low, and for an additional 100 ms after MRn de-assertion. NOTE: MRn doesn’t reset the device, it only triggers the SYSRST_OUTn pin. This pin is internally pulled up. REF_CLK_XIN I CMOS XTAL_AVDD Reference clock input from the external oscillator or input from the external crystal. Used as input to core and CPU PLLs, LCD PLL, USB PLL, and Serdes PLL. XOUT O Analog XTAL_AVDD Feedback signal to the external crystal. REFCLK_OUT O CMOS VDDO_D 25 MHz output clock NOTE: This signal is multiplexed. For more information, see Section 6.1, Multi Purpose Pins Functional Summary. SYSRST_OUTn O OD CMOS VDDO_MISC Reset request from the device to the board reset logic. NOTE: Requires a pull-up resistor to VDDO_MISC. SYSRSTn I CMOS VDDO_MISC System Reset Main reset signal of the device. Used to reset all units to their initial state. NOTE: For reset timing, see in the device Design Guide. M_NCAL Calib VDDO_M Memory SDRAM Interface Calibration. Calibrates output NMOS driver and ODT. Connect to VDDO_M through a 931 ohm +/- 1% resistor. M_PCAL Calib VDDO_M Memory SDRAM Interface Calibration. Calibrates output PMOS driver and ODT. Connect to VSS through a 931 ohm +/- 1% resistor. Analog AVS_SSCG_ AVDD Feedback voltage to the VDD regulator. NOTE: This pin can be required for some specific frequency configurations that are listed in Table 30, Clock Frequency Options, on page 65. If this pin’s usage is not required, leave this pin unconnected. CORE_AVS_FB O Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 41 MV78230 Hardware Specifications Table 13: Miscellaneous Signals Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n CPU_AVS_FB O Analog AVS_SSCG_ AVDD Feedback voltage to the VDD_CPU regulator. NOTE: This pin is required for some specific frequency configurations that are listed in Table 30, Clock Frequency Options, on page 65. If this pin’s usage is not required, leave this pin unconnected. SRD_ISET Calib Analog reference current for the SERDES and USB interfaces. This pin must be tied to a 6.04 kilohm ±1% pull-down resistor. Doc. No. MV-S106687-00 Rev. H Page 42 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.11 PCI Express (PCIe) Clocks/Reset Table 14: PCI Express (PCIe) Clocks/Reset Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n PEX0_CLK_P/N I/O HCSL XTAL_AVDD PCI Express Reference Clock 100 MHz Differential pair. As an output, each pin must be pulled down through a 49.9 ohm ±1% resistor. NOTE: When unused, these signals can be left unconnected. PEX1_CLK_P/N O HCSL XTAL_AVDD PCI Express Reference Clock 100 MHz Differential pair. Each pin must be pulled down through a 49.9 ohm ±1% resistor. NOTE: When unused, these signals can be left unconnected. PCIe_RSTOUTn O CMOS VDDO_D Endpoint external triggered reset. For further details, refer to the RESET section. NOTE: This signal is multiplexed. For more information, see Section 6.1, Multi Purpose Pins Functional Summary. Where <n> represents the numbers of 0 thru 1 PCIe_CLKREQ<n> I CMOS VDDO_D Endpoint request to enable/disable the reference clock. NOTE: These signals are multiplexed. For more information, see Section 6.1, Multi Purpose Pins Functional Summary. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 43 MV78230 Hardware Specifications 2.2.12 Precise Timing Protocol (PTP) Interface Note This interface is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. The power rail is determined by the MPP selection. Table 15: Precise Timing Protocol (PTP) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n PTP_CLK I CMOS VDDO_B or VDDO_C PTP reference clock for time stamping. PTP_EVENT_REQ I CMOS VDDO_B or VDDO_C PTP capturing event time. PTP_TRIG_GEN O CMOS VDDO_B or VDDO_C PTP pulse signal. Doc. No. MV-S106687-00 Rev. H Page 44 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.13 Real Time Clock (RTC) Interface Table 16: Real Time Clock (RTC) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n RTC_ALARMn O OD CMOS RTC_AVDD Active low, open drain, real time clock alarm output. Indicates when the Real Time Clock (RTC) reaches the alarm date/time. NOTE: This pin requires an external 100 Kohm pull-up resistor to RTC_AVDD. RTC_XIN I Analog RTC_AVDD Crystal Clock Input. RTC_XOUT O Analog RTC_AVDD Crystal Clock Output (feedback). Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 45 MV78230 Hardware Specifications 2.2.14 Serial-ATA (SATA) Interface Table 17: Serial-ATA (SATA) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n Where <n> represents numbers 0 thru 1 SATA<n>_PRESENT _ACTIVEn O CMOS VDDO_B, VDDO_C, or VDDO_D Disk Present Indication. NOTE: These signals are multiplexed. For more information, see Section 6.1, Multi Purpose Pins Functional Summary. The power rail is determined by the MPP selection. SATA<n>_RX_P SATA<n>_RX_N I CML SRD_AVDD Receive Lane Differential pair of SATA. NOTE: These pins are muxed on the SERDES interface. For more information, see Section 6.5 High Speed SERDES Multiplexing. SATA<n>_TX_P SATA<n>_TX_N O CML SRD_AVDD Transmit Lane Differential pair of SATA. NOTE: These pins are muxed on the SERDES interface. For more information, see Section 6.5 High Speed SERDES Multiplexing. Doc. No. MV-S106687-00 Rev. H Page 46 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.15 Secure Digital Input/Output (SDIO) Interface Note This interface is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Table 18: Secure Digital Input/Output (SDIO) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n SD0_CLK O CMOS VDDO_C SDIO Clock Output SD0_CMD and SD0_D[3:0] signals are referenced to this clock. SD0_CMD I/O CMOS SDR VDDO_C SDIO Command/Response This signal is referenced to SD0_CLK. NOTE: This pin must be pulled up to VDDO_C through a 10 kilohm resistor. SD0_D[3:0] I/O CMOS SDR VDDO_C SDIO Data Bus This bus is referenced to SD0_CLK. NOTE: This bus must be pulled up to VDDO_C through a 10 kilohm resistor. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 47 MV78230 Hardware Specifications 2.2.16 SDRAM DDR3 Interface Table 19: SDRAM DDR3 Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n M_A[15:0] O SSTL SDR VDDO_M DRAM Address Outputs Provides the row address for ACTIVE commands (RASn), the column address, Auto Precharge bit (A[10]) and Burst Chop (A[12]) information for READ/WRITE commands (CASn), to determine, with the bank address bits (BA), the DRAM address. These signals are referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0] NOTE: When unused, can be left unconnected. M_BA[2:0] O SSTL SDR VDDO_M DRAM Bank Address Outputs Selects one of the eight virtual banks during an ACTIVE (M_RASn), READ/WRITE (M_CASn), or PRECHARGE command. These signals are referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0]. NOTE: When unused, can be left unconnected. M_BB I CMOS VDDO_B, VDDO_C, or VDDO_D DRAM Battery Backup Trigger Once asserted high, the device will immediately put the DRAM in self refresh mode. NOTE: This pin is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. The power rail is determined by the MPP selection. M_CASn O SSTL SDR VDDO_M DRAM Column Address Strobe Asserted to indicate an active column address driven on the address lines. This signal is referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0]. M_CB[7:0] I/O SSTL DDR VDDO_M DRAM ECC Check Bits Driven during writes to the DRAM. Driven by the DRAM during reads. These signals are referenced to M_DQS[4] and M_DQSn[4]. NOTE: When unused, can be left unconnected. Doc. No. MV-S106687-00 Rev. H Page 48 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions Table 19: SDRAM DDR3 Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n M_CLKOUT[3:0] M_CLKOUTn[3:0] O SSTL VDDO_M DRAM Differential Clock Output All address and control output signals are clocked on the crossing of the positive edge of M_CLKOUT[3:0] and negative edge of M_CLKOUTn[3:0]. The M_DQS[4:0]/M_DQSn[4:0] output (during the WRITE data phase) is referenced to the crossings of M_CLKOUT[3:0] and M_CLKOUTn[3:0] (both directions of crossing). NOTE: When unused, can be left unconnected. For additional details, see also Unused Interface Strapping chapter. M_CLKOUT[0] and M_CLKOUTn[0] cannot be disabled and is always driven. M_CKE[3:0] O SSTL SDR VDDO_M DRAM Clock Enable Control Driven high to enable DRAM clock. Driven low when setting the DRAM in self Refresh Mode or Power Down mode. All M_CKE[3:0] pins are driven together (no separate self refresh or power down mode per each DRAM rank). This signal is referenced to M_CLKOUT[3:0] M_CLKOUTn[3:0] and CKn. NOTE: When unused, can be left unconnected. M_CSn[3:0] O SSTL SDR VDDO_M DRAM Chip Select Control Asserted to select a specific DRAM physical rank. This signal is referenced to M_CLKOUT[3:0] M_CLKOUTn[3:0] and CKn. NOTE: When unused, can be left unconnected. M_DM[4:0] O SSTL DDR VDDO_M DRAM Data Mask Driven during writes to the DRAM to mask the corresponding group of M_DQ[31:0] and M_DQS[4:0]/ M_DQSn[4:0] pins. This signal is referenced to M_DQS[4:0] and M_DQSn[4:0]. NOTE: When unused, can be left unconnected. M_DQ[31:0] I/O SSTL DDR VDDO_M DRAM Data Bus Driven during writes to the DRAM. Driven by the DRAM during reads. These signals are referenced to M_DQS[4:0] and M_DQSn[4:0]. NOTE: For additional details with unused pins, see the section “Unused Interface Strapping”. M_DQS[4:0] M_DQSn[4:0] I/O SSTL DDR VDDO_M DRAM Data Strobe Data strobe for input and output data. Driven during writes to the DRAM. Driven by the DRAM during reads. NOTE: For additional details with unused pins, see the section “Unused Interface Strapping”. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 49 MV78230 Hardware Specifications Table 19: SDRAM DDR3 Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n M_ODT[3:0] O SSTL SDR VDDO_M DRAM On Die Termination Control Driven to the DRAM to turn on/off DRAM on die termination resistor. This signal is referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0]. NOTE: When unused, can be left unconnected. M_RASn O SSTL SDR VDDO_M DRAM Row Address Strobe Asserted to indicate an active row address driven on the address lines. This signal is referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0]. M_RESETn O CMOS VDDO_M DRAM active low asynchronous reset. NOTE: When unused, can be left unconnected. M_WEn O SSTL SDR VDDO_M DRAM Write Enable Command Active low. Asserted to indicate a WRITE command to the DRAM. This signal is referenced to M_CLKOUT[3:0] and M_CLKOUTn[3:0]. M_VTT_CTRL O CMOS VDDO_C or VDDO_D Memory VTT Power Control Controls the EN pin of a VTT power regulator that is used for switching on/off the board’s termination voltage for the address/control lines. NOTE: This signal is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. The power rail is determined by the MPP selection. M_DECC_ERR O CMOS VDDO_C Memory Double ECC Error Asserted upon a double ECC error detected during read data phase from DRAM. Remains active as long as the <DBit> field in the in the DDR Controller Interrupt Cause register is asserted. For further information about the DDR Controller Interrupt Cause register, refer to the device’s functional specifications. NOTE: This signal is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. The power rail is determined by the MPP option. Doc. No. MV-S106687-00 Rev. H Page 50 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.17 Serial Peripheral Interface (SPI) Note This interface is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Table 20: Serial Peripheral Interface 0 (SPI0) Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n SPI0_CSn[7:0] O CMOS SDR VDDO_D SPI Chip-Select This signal is referenced to SPI0_SCK. NOTE: This pin must be pulled up to VDDO_D. SPI0_MISO I CMOS SDR VDDO_D SPI Data In (Master In / Slave Out) This signal is referenced to SPI0_SCK. SPI0_MOSI O CMOS SDR VDDO_D SPI Data Out (Master Out / Slave In) This signal is referenced to SPI0_SCK. SPI0_SCK O CMOS VDDO_D SPI Clock Output All SPI0 signals are referenced to this clock. Table 21: Serial Peripheral Interface 1 (SPI1) Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n SPI1_CSn[7:0] O CMOS SDR VDDO_B, VDDO_D SPI Chip-Select This signal is referenced to SPI1_SCK. NOTE: This pin must be pulled up to the relevant power rail. SPI1_MISO I CMOS SDR VDDO_B, VDDO_D SPI Data In (Master In / Slave Out) This signal is referenced to SPI1_SCK. SPI1_MOSI O CMOS SDR VDDO_B, VDDO_D SPI Data Out (Master Out / Slave In) This signal is referenced to SPI1_SCK. SPI1_SCK O CMOS VDDO_B, VDDO_D SPI Clock Output All SPI1 signals are referenced to this clock. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 51 MV78230 Hardware Specifications 2.2.18 Time Division Multiplexing (TDM) Interface Note This interface is implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Table 22: Time Division Multiplexing (TDM) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n TDM_DRX I CMOS SDR VDDO_C Pulse Code Modulation (PCM) Input Data This signal is referenced to TDM_PCLK. TDM_DTX O CMOS SDR VDDO_C Pulse Code Modulation (PCM) Output Data This signal is referenced to TDM_TX_PCLK. TDM_INTn[6:0] I CMOS VDDO_C Interrupt input from the SLIC device. TDM_INTn[7] VDDO_D TDM_RSTn O CMOS VDDO_C SLIC asynchronous reset signal. TDM_FSYNC I/O CMOS SDR VDDO_C Frame Synchronous Signal Driven by the device if configured as Frame master. Input to the device (driven by an external component) if configured as Frame slave. This signal is referenced to TDM_PCLK. TDM_PCLK I/O CMOS VDDO_C Pulse Code Modulation (PCM) Bit Clock Driven by the device if configured as PCLK master. Input to the device (driven by an external component) if configured as PCLK slave. TDM_FSYNC and TDM_DRX are referenced to this clock. Doc. No. MV-S106687-00 Rev. H Page 52 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.19 Universal Asynchronous Receiver Transmitter (UART) Interface Note The following are dedicated pins: UA0_RXD, UA1_RXD, UA0_TXD, and UA1_TXD. The remaining signals are implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Table 23: Universal Asynchronous Receiver Transmitter (UART) Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n UA0_CTS UA1_CTS I CMOS VDDO_D UART Clear To Send NOTE: UART<n>_CTS pins are implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. UA2_CTS UA3_CTS UA0_RTS UA1_RTS VDDO_D O CMOS UA2_RTS UA3_RTS UA0_RXD UA1_RXD VDDO_D I CMOS UA2_RXD UA3_RXD UA0_TXD UA1_TXD UA2_TXD UA3_TXD VDDO_D VDDO_MISC VDDO_D O CMOS VDDO_MISC VDDO_D UART Request To Send NOTE: UART<n>_RTS pins are implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. UART Receive Data NOTE: UART 2/3 RXD pins are implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. UART Transmit Data NOTE: UA0_TXD/UA1_TXD have an integrated pull-down resistor. UA2_TXD/UA3_TXD pins are implemented on the Multi Purpose Pin interface. For more information, see Section 6, Pin Multiplexing. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 53 MV78230 Hardware Specifications 2.2.20 USB 2.0 Interface When unused, can be left unconnected. Note Table 24: USB 2.0 Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n USB_AVDD and USB_AVDDL USB 2.0 Data Differential Pair. NOTE: USB1_DP/DM pins are actually a CMOS pin type when configured to the Low Speed mode. Where <n> represents numbers 0 thru 2 USB<n>_DP USB<n>_DM I/O CML Doc. No. MV-S106687-00 Rev. H Page 54 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.21 SERDES Port Interface Note The SERDES interface supports the following modes: PCI Express, SATA, USB, SGMII, DR-SGMII, QSGMII, and sETM. Table 25: SERDES Port Interface Pin Description Pin Name I/ O Pin Ty pe Power Rail D e s c r i p t io n Where <n> represents numbers 0 thru 6 SRD<n>_RX_N I CML SRD_AVDD Receive data: Differential analog input of SERDES Port <n>. SRD<n>_RX_P I CML SRD_AVDD Receive data: Differential analog input of SERDES Port <n>. SRD<n>_TX_N O CML SRD_AVDD Transmit data: Differential analog output of SERDES Port <n>. SRD<n>_TX_P O CML SRD_AVDD Transmit data: Differential analog output of SERDES Port <n>. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 55 MV78230 Hardware Specifications 2.2.22 Reserved/Not Connected Pins Pin Name D e s c r i p t io n RSVD_VSS Reserved Must be connected to VSS ground. RSVD_VDD_CPU Reserved. Must be connected to VDD_CPU power. RSVD_VDD Reserved. Must be connected to VDD power. RSVD_NC Reserved Must be not connected. NC Not connected. Doc. No. MV-S106687-00 Rev. H Page 56 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Pin Descriptions 2.2.23 Power Supply Pins Table 26 provides the voltage levels for the various interface pins. These also include the analog power supplies for the PLLs or PHYS. Table 26: Power Supply Pins Pin Name Pi n Ty p e D es c r ip t i o n VDD Power 0.9V core voltage VDD_CPU Power 1.05/1.1V CPU core and CPU subsystem voltage VDDO_MISC Power 3.3V I/O supply voltage for the TWSI0/1, UART0/1, and JTAG interfaces, and the following signals: • SYSRSTn • SYSRST_OUTn • MRn • CDRn VDDO_M Power 1.35/1.5/1.8V I/O supply voltage for the SDRAM interface VDDO_A Power 1.8/2.5/3.3V I/O supply voltage for the SMI interface and MPP[11:0] VDDO_B Power 1.8/2.5/3.3V I/O supply voltage for the MPP[23:12] VDDO_C Power 1.8V or 3.3V I/O supply voltage for the MPP[35:24] VDDO_D Power 3.3V I/O supply voltage for the SPI interface and MPP[47:36] VDDO_DEV Power 1.8V or 3.3V I/O supply voltage for the Device Bus interface and MPP[48] VDDO_FPD Power 1.8V I/O supply voltage for Flat Panel Display interface VHV Power 1.8V I/O supply voltage for eFuse Connect the power supply to the VHV ball only when burning the eFuse. When reading the eFuse and in all other times, disconnect the power supply from the VHV ball. The VHV is left floating. CORE_TDM_PLL_ AVDD Analog Power 1.8V Core PLL and TDM PLL quiet power supply NOTE: Implement the PLL filter as described in the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide. CPU_PLL_AVDD Analog Power 1.8V CPU PLL quiet power supply NOTE: Implement the PLL filter as described in the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide. USB_AVDD Analog Power 3.3V USB 2.0 PHY quiet power supply NOTE: See the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide for power supply filtering recommendations. USB_AVDDL Analog Power 1.8V USB 2.0 PHY quiet power supply NOTE: See the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide for power supply filtering recommendations. SRD_AVDD Analog Power 1.8V SERDES quiet power supply NOTE: See the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide for power supply filtering recommendations. RTC_AVDD Analog Power 3.0V (via the battery) or 3.3V (via the board) RTC interface voltage Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 57 MV78230 Hardware Specifications Table 26: Power Supply Pins (Continued) Pin Name Pi n Ty p e D es c r ip t i o n XTAL_AVDD Analog Power 1.8V XTAL and PCI Express clock outputs quiet power supply NOTE: See the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Design Guide for power supply filtering recommendations. AVS_SSCG_AVDD Analog Power 1.8V CORE_AVS, CPU_AVS, and the Spread Spectrum Clock Generator (SSCG) quiet power supply VSS Ground Ground XTAL_AVSS Analog Ground XTAL quiet ground CPU_PLL_AVSS Analog Ground CPU PLL quiet ground CORE_TDM_PLL_ AVSS Analog Ground TDM PLL quiet ground AVS_SSCG_AVSS Analog Ground CORE_AVS, CPU_AVS, and SSCG quiet ground Doc. No. MV-S106687-00 Rev. H Page 58 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Information Internal Pull-up and Pull-down Pins 2.3 Internal Pull-up and Pull-down Pins Table 27 and Table 28 lists the pins of the device package that are connected to internal pull-up and pull-down resistors. When these pins are Not Connected (NC) on the system board, these resistors set the default value for input and sample at reset configuration pins. The internal pull-up and pull-down resistor value is 50 k. An external resistor with a lower value can override this internal resistor. For the pin location, see the attached Excel file in Section 4, MV78230 Pin Map, Pin List, and Package Trace Lengths, on page 63. Table 27: Internal Pull-up Pins P in N a m e Pin Name Pin Name Pin Name Pi n N am e CDRn JT_TDI MPP[14] MPP[29] MPP[42] DEV_AD[3] JT_TMS_CORE MPP[15] MPP[30] MPP[43] DEV_AD[5] JT_TMS_CPU MPP[16] MPP[31] MPP[44] DEV_AD[7] GE_MDIO MPP[18] MPP[32] MPP[45] DEV_AD[8] MPP[0] MPP[19] MPP[33] MPP[46] DEV_AD[9] MPP[3] MPP[20] MPP[34] MPP[47] DEV_BOOTCSn MPP[6] MPP[21] MPP[35] MRn DEV_CSn[0] MPP[7] MPP[22] MPP[36] TWSI0_SCK DEV_CSn[1] MPP[8] MPP[23] MPP[37] TWSI0_SDA DEV_CSn[2] MPP[9] MPP[25] MPP[38] TWSI1_SCK DEV_CSn[3] MPP[10] MPP[26] MPP[39] TWSI1_SDA DEV_OEn MPP[11] MPP[27] MPP[40] DEV_Wen[0] MPP[13] MPP[28] MPP[41] Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 59 MV78230 Hardware Specifications Table 28: Internal Pull-down Pins P in N a m e Pin Name DEV_A[0] DEV_ALE[1] DEV_A[1] DEV_READYn DEV_A[2] DEV_WEn[1] DEV_AD[0] GE_MDC DEV_AD[1] JT_CLK DEV_AD[2] JT_RSTn DEV_AD[4] MPP[1] DEV_AD[6] MPP[2] DEV_AD[10] MPP[4] DEV_AD[11] MPP[5] DEV_AD[12] MPP[12] DEV_AD[13] MPP[17] DEV_AD[14] MPP[24] DEV_AD[15] UA0_TXD DEV_ALE[0] UA1_TXD Doc. No. MV-S106687-00 Rev. H Page 60 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Unused Interface Strapping 3 Unused Interface Strapping Table 29 lists the signal strapping for systems in which some of the MV78230 interfaces are unused. Table 29: Unused Interface Strapping Unused Interface Str a p p in g Device Connect VDDO_DEV to 1.8V or 3.3V. The Device bus signals can be left unconnected. SDRAM If there are unused clock pairs: • Leave the unused pair unconnected. • In the DDR Controller Control (Low) register (Offset: 0x1404), set <Clk1Drv> (bit[12]),<Clk2Drv> (bit[13]), or <Clk3Drv> (bit[15]) to 0 (high-Z). NOTE: M_CLKOUT[0] and M_CLKOUTn[0] cannot be disabled and are always driven. The following SDRAM signals can be left unconnected when unused: • M_A • M_BA • M_CB • M_DM • M_DQ • M_DQS/DQSn • M_CSn • M_ODT • M_CKE Ethernet SMI GE_MDIO must be pulled up with a 1–4.7 kilohm resistor to VDDO_A. I2C Unused TWSI<n>_SDA and TWSI<n>_SCK signals must be pulled up with a 1–4.7 kilohm resistor to VDDO_MISC. JTAG If the JT_TMS_CORE is: • Not connected: There is no need for an external pull-up. • Connected: JT_TMS_CORE must kept high if unused (i.e. pulled up). UART Unused UA<n>_RXD signals must be pulled up with a 1–4.7 kilohm resistor to VDDO_MISC. Unused UA<n>_TXD signals can be left unconnected. MPP Configure unused signals as GPIO outputs. No external pullups are required. Leave the power rail driving the unused MPPs connected as follows: • Leave VDDO_A connected to 1.8V or 2.5V or 3.3V. • Leave VDDO_B connected to 1.8V or 2.5V or 3.3V. • Leave VDDO_C connected to 1.8V or 3.3V. • Leave VDDO_D connected to 3.3V. • Leave VDDO_DEV connected to 1.8V or 3.3V. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 61 MV78230 Hardware Specifications Table 29: Unused Interface Strapping Unused Interface Str a p p in g USB Unused USB<n>_DP and USB<n>_DM signals can be left unconnected. Power down any unused USB ports via the register configuration. If all the USB ports are unused: • Discard the power filter. • Connect USB_AVDD to VSS. • Connect USB_AVDDL to VSS. SERDES Unused SRD<n>_TX_P/N and SRD<n>_RX_P/N signals can be left unconnected. Power down any unused SERDES port via register configuration. If all the SERDES ports are unused: • Discard the power filter. • Connect SRD_AVDD to VSS. PCI Express Clocks Unused signals can be left unconnected. To power down the PECL receiver, write 0 to the Ana Grp Config register (offset: 0x0001847C) <PU_CLK> bit[10]. If the PCIe_CLKREQ pins are not required, the relevant MPP pins must be configured to a different mode. For further information, see Section 6.1, Multi Purpose Pins Functional Summary, on page 67. Flat Panel Display Unused signals can be left unconnected If all signals in this interface are unused, VDDO_FPD can also be left unconnected. RTC RTC_AVDD, RTC_XIN, and RTC_XOUT can be left unconnected. RTC Alarm RTC_ALARMn can be left unconnected. If unused, the external pull-up can be removed. Configure the alarm register to 32’b0 and then the clear control register field to 1. Adaptive Voltage Scaling (AVS) CPU_AVS_FB and CORE_AVS_FB can be left unconnected. AVS_SSCG_AVDD and AVS_SSCG_AVSS must be left connected. Discard the power filter only if all of the following pins are not in use: • CPU AVS • CORE AVS • SSCG Doc. No. MV-S106687-00 Rev. H Page 62 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary MV78230 Pin Map, Pin List, and Package Trace Lengths 4 MV78230 Pin Map, Pin List, and Package Trace Lengths The MV78230 pin lists and package trace lengths are provided as Excel file attachments. To open the attached Excel pin list file, double-click the pin icon below: MV78230 Pin Map and Pin List File attachments are only supported by Adobe Reader 6.0 and above. Note To download the latest version of free Adobe Reader go to http://www.adobe.com. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 63 MV78230 Hardware Specifications 5 Clocking 5.1 Clock Domain The MV78230 has multiple clock domains: PCLK0, PCLK1: Marvell® Core Processor ARM CPU clocks—up to 1.6 GHz1 NBCLK: The Coherent Fabric clock. Also used as the L2 cache clock—up to 800 MHz1 HCLK: The SDRAM controller internal clock—up to 400 MHz1 DRAMCLK: The SDRAM interface clock—up to 800 MHz1 TCLK: The device’s core clock—250 MHz. DEV_CLK_OUT: Up to TCLK/4 PCI Express clock: • Runs at 250 MHz when configured to Gen1.1 • Runs at 500 MHz when configured to Gen2.0 GbE ports clock: • 125 MHz for 1000 Mbps • 25 MHz for 100 Mbps • 2.5 MHz for 10 Mbps 5.1.1 SMI clock: Up to TCLK/8 SATA clock: Runs at 150 MHz USB clock: Runs up to 480 MHz (at High Speed mode) UART clock: Up to TCLK frequency divided by 16 SPI clock: Up to 50 MHz I2C clock: Up to 100 kHz LCD clock: Up to 65 MHz for both parallel and LVDS interfaces SDIO clock: Up to 50 MHz TDM clock: Up to 8.192 MHz Clock Ratios The supported PCLK0-to-NBCLK clock ratios are 1:1, 1:2, 1:3 and 2:3. The supported NBCLK-to-HCLK clock ratios are 1:N and 2:N. The supported HCLK-to-DRAMCLK clock ratios are 1:1 and 1:2. According to this defined ratio, SW needs to configure the DRAM controller’s working mode to be 1:1 or 1:2. The supported PCLK0-to-PCLK<n> clock ratios are 1:1, 1:2 and 1:3. 1. Controlled by the Spread Spectrum Clock Generator (SSCG). For details, see Section 5.3, Spread Spectrum Clock Generator (SSCG), on page 66. Doc. No. MV-S106687-00 Rev. H Page 64 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Clocking Clock Frequency Configuration Options The PCLK0-to-NBCLK ratios, NBCLK-to-HCLK ratios, and HCLK-to-DRAMCLK ratios are determined via reset strapping. Table 30 summarizes the possible frequencies of the various domains as a function of the selected CPU speed. Note 5.2 To set up target clock frequencies, first select the target CPU speed via CPU0 Clock Frequency Select in Table 36, Reset Configuration Pins, on page 81 reset straps, and then configure the Fabric Frequency Options reset straps to the specified index according to Table 30. The PCLK0 frequency specifies the target frequency of CPU0. The other CPU core default clock frequency is set to the selected NBCLK frequency. As part of the CPU0 boot flow, and in case a different speed target is required for the other core, the software needs to reconfigure the target frequencies for the other core through the software. PCLK0 frequency must always be greater or equal to PCLK<n>. Clock Frequency Configuration Options Table 30 lists the various frequency options and the supported CPU0 speeds that may be configured via the <CPU0 Clock Frequency Select> field in Non-Core and Core Voltages (Table 35 p. 84) reset straps. Table 30: Clock Frequency Options NOTE: The Fabric Frequency Configuration Index column applies to the reset strap vector represented by the <Fabric Frequency Options> field in Non-Core and Core Voltages (Table 35 p. 84). CPU0 Clock Frequency (PCLK) [MHz] N B C LK [ M H z ] HC LK [ M Hz] D R A M C L K [M H z ] Fabric F r e qu e n c y C o nf ig u r a ti on I n de x 800 400 200 400 5 1066 533 267 533 5 1200 600 300 600 5 1200 600 200 400 9 1333 667 333 667 5 15001 750 375 750 5 15002 750 250 500 9 16002 800 266 533 9 16002 800 320 640 10 16002 800 400 800 5 1. The CPU_AVS_FB pin must be used with this clock frequency. For further information on AVS usage, see the MV78230/78x60 Design Guide (MV-S301878-00). 2. The CORE_AVS_FB and CPU_AVS_FB pins must be used with this clock frequency. For further information on AVS usage, see the MV78230/78x60 Design Guide. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 65 MV78230 Hardware Specifications 5.3 Spread Spectrum Clock Generator (SSCG) The Spread Spectrum Clock Generator (SSCG) may be used to generate the spread spectrum clock for the PLL input. See <SSCG Disable> in Table 36, Reset Configuration Pins, on page 81, for SSCG enable/disable configuration settings. The SSCG block can be configured to perform up spread, down spread and center spread. The modulation frequency is configurable. The typical frequency is 30 kHz. The spread percentage can also be configured up to 1%. For additional details, see the SSCG Configuration Register description in the device’s Functional Specifications. Doc. No. MV-S106687-00 Rev. H Page 66 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Multiplexing Multi Purpose Pins Functional Summary 6 Pin Multiplexing 6.1 Multi Purpose Pins Functional Summary The device contains 49 Multi Purpose Pins (MPP). Each pin can be assigned a different functionality through the configuration of the MPP Control register. These configuration options include: GPIO: General Purpose In/Out Port, each of the 49 MPP pins may be configured as a GPIO signals—see the General Purpose I/O Port section in the device’s Functional Specifications. DEV_BURSTn/DEV_LASTn: Device Bus interface signals—see the Device Bus section in the device’s Functional Specifications. NF_RBn: Ready/Busy indication for the NAND Flash interface—See Table 6, Device Bus/NAND Flash Interface Pin Assignments, on page 33 DEV_CLK_OUT: Outputs a divided core clock (TCLK)—see the Device Bus section in the device’s Functional Specifications. TDM_INTn[7:0], TDM_RSTn, TDM_PCLK, TDM_FSYNC, TDM_DRX, TDM_DTX: TDM (Voice) interface signals—see the TDM section in the device’s Functional Specifications. SPI<n>_CS[7:0]n, SPI<n>_SCK, SPI<n>_MISO, SPI<n>_MOSI (n= 0 thru 1): SPI (Serial Peripheral Interface) signals—see the SPI section in the device’s Functional Specifications. UA0_CTSn, UA0_RTSn, UA1_CTSn, UA1_RTSn, UA2_RXD, UA2_TXD, UA2_CTSn, UA2_RTSn, UA3_RXD, UA3_TXD, UA3_CTSn, UA3_RTSn: UART pins—see the UART section in the device’s Functional Specifications. I2C signals: TWSI0/1_SDA, TWSI0/1_SCK SD0_CLK, SD0_CMD, SD0_D[3:0]: SDIO interface—see the SDIO section in the device’s Functional Specifications. PTP_EVENT_REQ, PTP_TRIG_GEN, PTP_CLK: Precise Timing Protocol signals—see the Gigabit Ethernet Controller section in the device’s Functional Specifications. GE<n>_TXCLKOUT, GE<n>_TXD[3:0], GE<n>_TXCTL, GE<n>_RXD[3:0], GE<n>_RXCTL, GE<n>_RXCLK (n= 0 thru 1): Ethernet RGMII signals for ports 0 and 1 —see the Gigabit Ethernet Controller section in the device’s Functional Specifications. GE0_TXD[7:4], GE0_TXCLK, GE0_COL, GE0_RXERR, GE0_CRS, GE0_RXD[7:4]: GbE port0 signals when configured to GMII/MII interface—see the Gigabit Ethernet Controller section in the device’s Functional Specifications. Also, see Table 31, Gigabit Ethernet Pins Multiplexing for port mode selections. SATA<n>_PRESENT_ACTIVEn (n= 0 thru 1): Combined SATA active and SATA present indications—see the Serial-ATA section in the device’s Functional Specifications. M_BB: SDRAM battery backup trigger—see the SDRAM Self Refresh section in the device’s Functional Specifications. M_VTT_CTRL, M_DECC_ERR: VTT power regulator control and asserted signal upon double ECC error detection during the read data phase from DRAM. See the SDRAM section the device’s Functional Specifications. LCD_D[23:0], LCD_HSYNC, LCD_VSYNC, LCD_PWM, LCD_CLK, LCD_E, LCD_VGA_HSYNC, LCD_VGA_VSYNC: LCD interface signals—see Table 32, LCD Interface Modes, on page 70 for pin allocation and the LCD section in the device’s Functional Specifications. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 67 MV78230 Hardware Specifications LCD_EXT_REF_CLK: Optional reference clock for the LCD interface. See the LCD section in the device’s Functional Specifications. REFCLK_OUT: Stable 25 MHz output clock from the device. Can be used as reference input clock for other components on the board. PCIe_CLKREQ0, PCIe_CLKREQ1: When the port is configured as RC, endpoints may drive the clock request to high. This causes the PCI clock request to be gated. During normal operations, the clock request should be driven low, which means the PCI clock is not held. For further information, see the PCI Express section in the device’s Functional Specifications. PCIe_RSTOUTn: PCIe reset out indication. See the PCI Express section in the device’s Functional Specifications. The attached Excel file lists each MPP pins’ functionality as determined by the MPP Multiplex registers. For more information, refer to the Pins Multiplexing Interface Registers section in the device’s Functional Specifications. To open the attached Excel MPP map file, double-click the pin icon below: MV78230 MPP Map File attachments are only supported by Adobe Reader 6.0 and above. Note 6.2 To download the latest version of free Adobe Reader go to http://www.adobe.com. Multi Purpose Pins Power Segments The different power segments for each of the MPP pins is listed in the Power Pins Description table in Table 26, Power Supply Pins, on page 57. The voltage level of VDDO_C and VDDO_DEV is determined by a reset strap. The voltage level of VDDO_A and VDDO_B is 3.3V by default, with a register configurable option to 1.8/2.5V or 2.5V. Refer to the System Considerations section in the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Functional Specifications for more information about voltage setting. 6.3 Multi Purpose Pins Functional Considerations When configuring MPP pins note the following issues, also refer to the attached Multi Purpose Pin Functional Summary Table: For MPPs assigned as NOR or SPI flash, the wake-up mode after reset depends on the Boot mode (see the Boot Device Type Selection field in Table 36, Reset Configuration Pins, on page 81). There are a few options for the boot device as listed in Table 36. The value set in field Boot Device Type Selection determines the type of the boot select during reset. The values set in Table 36 effect the default value of <MPPSel> fields in the MPP Control registers. • If Boot Device Type Selection is set to 0x3, MPP[39:36] pins wake up as SPI flash signals. UART0, UART1, UART2, and UART3 signals are duplicated on some MPP pins. The UART0, UART1, UART2, or UART3 signals must not be configured to more than one MPP option. Doc. No. MV-S106687-00 Rev. H Page 68 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Multiplexing Gigabit Ethernet Pins Multiplexing on the MPP 6.4 All other MPP interface pins wake up after reset in 0x0 mode (GPIO). By default, these pins are set to Data Output disabled (Tri-State). Therefore, these MPPs are in fact inputs. Some of the MPP pins are sampled during SYSRSTn de-assertion to set the device configuration. These pins must be driven to the correct value during reset (see Table 36, Reset Configuration Pins, on page 81). Pins that are left as GPIO and are not connected must be configured as outputs via the GPIO registers after SYSRSTn de-assertion (see General Purpose I/O section in the ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors Functional Specifications). Gigabit Ethernet Pins Multiplexing on the MPP There are two Gigabit Ethernet ports that are multiplexed on the MPP pins. Each of these Gigabit Ethernet ports can operate in RGMII mode. Port 0 also supports GMII/MII signaling. The device also contains a SERDES interface that can be used as SGMII interfaces for port 0, 1, 2. Once a port is configured as an SGMII port, it cannot be selected as an RGMII/GMII/MII port on the MPP pins. The SGMII interface may be selected on various SERDES options (see Section 6.7, High-Speed SERDES Multiplexing, on page 74. Do not select more than one SERDES option for the same GbE port. Table 31 lists the Gigabit Ethernet multiplexing pin configuration options for Port0 and Port1, when the port is not used as SGMII. Table 31: Gigabit Ethernet Pins Multiplexing MPP # GE0 GMII, GE1 is S G M I I or N/A G E0 M I I, G E1 i s S G M II o r N /A G E 0 R G M II , G E 1 ei t h e r S G M I I o r N /A GE1 RGMII, GE0 either SG M II o r N / A Both GE0 and GE1 are RGMII MPP[0] GE0_TXCLKOUT (out) N/A GE0_TXCLKOUT (out) N/A GE0_TXCLKOUT (out) MPP[1] GE0_TXD[0] (out) GE0_TXD[0] (out) GE0_TXD[0] (out) N/A GE0_TXD[0] (out) MPP[2] GE0_TXD[1] (out) GE0_TXD[1] (out) GE0_TXD[1] (out) N/A GE0_TXD[1] (out) MPP[3] GE0_TXD[2] (out) GE0_TXD[2] (out) GE0_TXD[2] (out) N/A GE0_TXD[2] (out) MPP[4] GE0_TXD[3] (out) GE0_TXD[3] (out) GE0_TXD[3] (out) N/A GE0_TXD[3] (out) MPP[5] GE0_TXEN (out) GE0_TXEN (out) GE0_TXCTL (out) N/A GE0_TXCTL (out) MPP[6] GE0_RXD[0] (in) GE0_RXD[0] (in) GE0_RXD[0] (in) N/A GE0_RXD[0] (in) MPP[7] GE0_RXD[1] (in) GE0_RXD[1] (in) GE0_RXD[1] (in) N/A GE0_RXD[1] (in) MPP[8] GE0_RXD[2] (in) GE0_RXD[2] (in) GE0_RXD[2] (in) N/A GE0_RXD[2] (in) MPP[9] GE0_RXD[3] (in) GE0_RXD[3] (in) GE0_RXD[3] (in) N/A GE0_RXD[3] (in) MPP[10] GE0_RXDV (in) GE0_RXDV (in) GE0_RXCTL (in) N/A GE0_RXCTL (in) MPP[11] GE0_RXCLK (in) GE0_RXCLK (in) GE0_RXCLK (in) N/A GE0_RXCLK (in) MPP[12] GE0_TXD[4] (out) N/A N/A GE1_TXCLKOUT (out) GE1_TXCLKOUT (out) Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 69 MV78230 Hardware Specifications Table 31: Gigabit Ethernet Pins Multiplexing (Continued) MPP # GE0 GMII, GE1 is S G M I I or N/A G E0 M I I, G E1 i s S G M II o r N /A G E 0 R G M II , G E 1 ei t h e r S G M I I o r N /A GE1 RGMII, GE0 either SG M II o r N / A Both GE0 and GE1 are RGMII MPP[13] GE0_TXD[5] (out) N/A N/A GE1_TXD[0] (out) GE1_TXD[0] (out) MPP[14] GE0_TXD[6] (out) N/A N/A GE1_TXD[1] (out) GE1_TXD[1] (out) MPP[15] GE0_TXD[7] (out) N/A N/A GE1_TXD[2] (out) GE1_TXD[2] (out) MPP[16] N/A GE0_TXCLK (in) N/A GE1_TXD[3] (out) GE1_TXD[3] (out) MPP[17] GE0_COL (in) GE0_COL (in) N/A GE1_TXCTL (out) GE1_TXCTL (out) MPP[18] GE0_RXERR (in) GE0_RXERR (in) N/A GE1_RXD[0] (in) GE1_RXD[0] (in) MPP[19] GE0_CRS (in) GE0_CRS (in) N/A GE1_RXD[1] (in) GE1_RXD[1] (in) MPP[20] GE0_RXD[4] (in) N/A N/A GE1_RXD[2] (in) GE1_RXD[2] (in) MPP[21] GE0_RXD[5] (in) N/A N/A GE1_RXD[3] (in) GE1_RXD[3] (in) MPP[22] GE0_RXD[6] (in) N/A N/A GE1_RXCTL (in) GE1_RXCTL (in) MPP[23] GE0_RXD[7] (in) N/A N/A GE1_RXCLK (in) GE1_RXCLK (in) Note 6.5 When using GbE signals on MPPs, all relevant GbE signals (except those marked as N/A) must be implemented. For example, if using MII, and the chosen PHY does not have an MII_RXERR out signal, the GE0_RXERR on the MPP pin must still be configured accordingly and must have a pull-down resistor. LCD Pin Multiplexing on the MPP The LCD interface is multiplexed on MPP[28:0] (see Table 32). Not all LCD panels require the full 29 pins. Any pins that are not used as LCD pins, may be used for different pin assignment according to the options shown in the attached Excel file (see Section 6.1, Multi Purpose Pins Functional Summary, on page 67). The supported LCD interface modes are listed in Table 32. Table 32: LCD Interface Modes MPP Pin L C D Pi n Mode 0 Mode 1 Mode 2 M od e 3 Dumb Panel 2 4 - b it C o lo r 8:8:8 D um b P a ne l 1 8 - b it C o lo r 6:6:6 D u m b P an e l 1 6- b it C o l o r 5:6:5 Dumb Panel 12-bit Color 4:4:4 MPP[0] LCD_D[0] Red[0] Red[2] Red[3] Red[4] MPP[1] LCD_D[1] Red[1] Red[3] Red[4] Red[5] MPP[2] LCD_D[2] Red[2] Red[4] Red[5] Red[6] MPP[3] LCD_D[3] Red[3] Red[5] Red[6] Red[7] Doc. No. MV-S106687-00 Rev. H Page 70 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Multiplexing LCD Pin Multiplexing on the MPP Table 32: LCD Interface Modes (Continued) MPP Pin L C D Pi n Mode 0 Mode 1 Mode 2 M od e 3 Dumb Panel 2 4 - b it C o lo r 8:8:8 D um b P a ne l 1 8 - b it C o lo r 6:6:6 D u m b P an e l 1 6- b it C o l o r 5:6:5 Dumb Panel 12-bit Color 4:4:4 MPP[4] LCD_D[4] Red[4] Red[6] Red[7] Green[4] MPP[5] LCD_D[5] Red[5] Red[7] Green[2] Green[5] MPP[6] LCD_D[6] Red[6] Green[2] Green[3] Green[6] MPP[7] LCD_D[7] Red[7] Green[3] Green[4] Green[7] MPP[8] LCD_D[8] Green[0] Green[4] Green[5] Blue[4] MPP[9] LCD_D[9] Green[1] Green[5] Green[6] Blue[5] MPP[10] LCD_D[10] Green[2] Green[6] Green[7] Blue[6] MPP[11] LCD_D[11] Green[3] Green[7] Blue[3] Blue[7] MPP[12] LCD_D[12] Green[4] Blue[2] Blue[4] N/A MPP[13] LCD_D[13] Green[5] Blue[3] Blue[5] N/A MPP[14] LCD_D[14] Green[6] Blue[4] Blue[6] N/A MPP[15] LCD_D[15] Green[7] Blue[5] Blue[7] N/A MPP[16] LCD_D[16] Blue[0] Blue[6] N/A N/A MPP[17] LCD_D[17] Blue[1] Blue[7] N/A N/A MPP[18] LCD_D[18] Blue[2] N/A N/A N/A MPP[19] LCD_D[19] Blue[3] N/A N/A N/A MPP[20] LCD_D[20] Blue[4] N/A N/A N/A MPP[21] LCD_D[21] Blue[5] N/A N/A N/A MPP[22] LCD_D[22] Blue[6] N/A N/A N/A MPP[23] LCD_D[23] Blue[7] BIAS_OUT (32 kHz) BIAS_OUT (32 kHz) BIAS_OUT (32 kHz) MPP[24] LCD_HSY NC H_Sync H_Sync H_Sync H_Sync MPP[25] LCD_VSY NC V_Sync V_Sync V_Sync V_Sync MPP[26] LCD_CLK Pixel_Clock Pixel_Clock Pixel_Clock Pixel_Clock MPP[27] LCD_E Data Enable Data Enable Data Enable Data Enable MPP[28] LCD_PWM BIAS_OUT (32 kHz) N/A N/A N/A Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 71 MV78230 Hardware Specifications Note 6.6 When a touch panel SPI interface is required, use one of the available SPI interface configuration options on the MPP pins. The SPI interface may be configured through MPP[47:36]. Serialized LVDS Transmitter The integrated serialized LVDS transmitter supports the following features at up to 65 MSPS: 18-bit or 24-bit per pixel (three or four transmit differential data/control lanes) Transmit differential clock lane (driven by the LCD_CLK output) Two data serialization options in 24-bit per pixel mode Option to disable serialization and force constant zero output in data/control lanes Configurable tick delay on data/control lanes relative to clock lane Option to disable the fast reference clock when LVDS is not in use Option to power down LVDS pads when not in use The LVDS and parallel RGB interface are usually not used together. When LVDS is not used, Marvell recommends powering down the pads and disabling serialization for power saving. Figure 5 displays the connectivity between the LCD unit and the LVDS. Figure 5: Pin Multiplexing and Connectivity Diagram PWM 7 D0,D1,D2,D3,D4,D6,D7 Parallel- Load7- bit Shift Register >A,B,…..G > 7 x CLK > Load LVDS LVLCD0 LVLCD0n LVDS 7 LCD Unit Parallel Interface D8,D9,D12,D13,D14,D15,D18 Parallel- Load7- bit Shift Register >A,B,…..G > 7 x CLK > Load LVLCD1 LVLCD1n LVDS 7 D19,D20,D21,D22,D24,D25,D26 7 D27,D5,D10,D11,D16,D17,D23 Parallel- Load7- bit Shift Register >A,B,…..G > 7 x CLK > Load Parallel- Load7- bit Shift Register >A,B,…..G > 7 x CLK > Load LVLCD2 LVLCD2n LVDS LVLCD3 LVLCD3n LVLCD_ CLKOUT Clock Dividers Pixel clock LVLCD_ CLKOUTn REF_CLK_XIN mux PLL LCD_EXT_REF_CLK Table 33 lists the connectivity between the LCD and the LVDS options. Doc. No. MV-S106687-00 Rev. H Page 72 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Multiplexing Serialized LVDS Transmitter Table 33: LCD Connectivity to LVDS Pi n 24 BPP Controller and Panel 18 BPP Controller and Panel Mode0 Dumb Panel 2 4 - b it C o l o r 8 : 8 : 8 LVD S O p ti o n1 LVD S O p ti o n2 M od e 1 D u m b P an e l 1 8 - b i t C o lo r 6 : 6 : 6 LV D S O p ti on 1 0 Red[0] (LSB) D0 D27 Red[2] (LSB) D0 1 Red[1] D1 D5 Red[3] D1 2 Red[2] D2 D0 Red[4] D2 3 Red[3] D3 D1 Red[5] D3 4 Red[4] D4 D2 Red[6] D4 5 Red[5] D6 D3 Red[7] (MSB) D6 6 Red[6] D27 D4 Green[2] (LSB) D7 7 Red[7] (MSB) D5 D6 Green[3] D8 8 Green[0] (LSB) D7 D10 Green[4] D9 9 Green[1] D8 D11 Green[5] D12 10 Green[2] D9 D7 Green[6] D13 11 Green[3] D12 D8 Green[7] (MSB) D14 12 Green[4] D13 D9 Blue[2] (LSB) D15 13 Green[5] D14 D12 Blue[3] D18 14 Green[6] D10 D13 Blue[4] D19 15 Green[7] (MSB) D11 D14 Blue[5] D20 16 Blue[0] (LSB) D15 D16 Blue[6] D21 17 Blue[1] D18 D17 Blue[7] (MSB) D22 18 Blue[2] D19 D15 NA GND 19 Blue[3] D20 D18 NA GND 20 Blue[4] D21 D19 NA GND 21 Blue[5] D22 D20 NA GND 22 Blue[6] D16 D21 NA GND 23 Blue[7] (MSB) D17 D22 BIAS_OUT (32 kHz) GND 24 H_sync D24 D24 H_sync D24 25 V_sync D25 D25 V_sync D25 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 73 MV78230 Hardware Specifications Table 33: LCD Connectivity to LVDS (Continued) Pi n 24 BPP Controller and Panel 18 BPP Controller and Panel Mode0 Dumb Panel 2 4 - b it C o l o r 8 : 8 : 8 LVD S O p ti o n1 LVD S O p ti o n2 M od e 1 D u m b P an e l 1 8 - b i t C o lo r 6 : 6 : 6 LV D S O p ti on 1 26 Pixel clk CLK* CLK* Pixel clk CLK* 27 DENA D26 D26 DENA D26 28 BIAS_OUT (32 kHz) D23=RSRVD D23=RSRVD NA D23=RSRVD 6.7 High-Speed SERDES Multiplexing The MV78230 integrates seven high-speed SERDES lanes. The SERDES lanes provide a physical SERDES link to the following interfaces: The following PCI Express operational modes: • Gen2.0 up to 5 Gbps • Gen1.1 up to 2.5 Gbps PCIe unit 0 may be configured to x4 or quad x1 lanes. PCIe unit 1 is always x1. SGMII interface: • SGMII0 and SGMII2 can operate at 1.25 Gbps or 3.125 Gbps. • SGMII1 operate at 1.25 Gbps. QSGMII (up to 5 Gbps) SATA Gen1 (1.5 Gbps) and SATA Gen2 (3 Gbps) Embedded Trace Module (ETM) Table 34, MV78230 SERDES Lanes Multiplex Options presents the different modes available for each SERDES lane. Each lane can be configured independently for the required link type, according to the specified application. If a lane is unused, it can be turned off. Note For SERDES configuration information, see the Shared SERDES Selectors registers (offsets: 0x00018270 and 0x00018274) in the device’s Functional Specifications. Doc. No. MV-S106687-00 Rev. H Page 74 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Pin Multiplexing High-Speed SERDES Multiplexing Table 34: MV78230 SERDES Lanes Multiplex Options L an e s 0 1 2 3 4 5 6 PCIe0.0 PCIe0.1 PCIe0.2 PCIe0.3 PCIe1.0 SATA 0 SGMII0 SATA 1 SGMII 1 SGMII 2 SGMII1 SATA0 SGMII 2 SGMII0 ETM0 ETM1 ETM0 QSGMII QSGMII Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 75 MV78230 Hardware Specifications 7 Reset and Initialization This section details the device’s reset sequence and initialization procedure. 7.1 Power Up/Down Sequence 7.1.1 Power-Up Sequence These requirements must be applied to meet the device power-up sequence (see Figure 6): The Non-Core voltages (I/O and Analog), as listed in Table 35, must reach 70% of their voltage level before the Core voltages. The order of the power up sequence between the Non-Core voltages is unimportant. The order of the power up sequence between the Core voltages is unimportant either. The reset signal(s) must be asserted before the Core voltages reach 70% of their voltage level. Each reference clock input must toggle with its respective voltage level before the first Core voltage reaches 70% of their voltage level. If a crystal oscillator is used, the system can rely on the oscillator wake-up mechanism. Table 35: Non-Core and Core Voltages N on -C o r e Vol ta g e s I/ O Vo lta ge s A n a l og Po w e r S up p li e s VDDO_A VDDO_B VDDO_C VDDO_D VDDO_DEV VDDO_M VDDO_MISC VDDO_FPD VHV RTC_AVDD SRD_AVDD CORE_TDM_AVDD CPU_PLL_AVDD XTAL_AVDD USB_AVDD USB_AVDDL Doc. No. MV-S106687-00 Rev. H Page 76 C o r e Vo lta g e s VDD VDD_CPU Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization Hardware Reset Figure 6: Power Up Sequence Example Voltage Non-Core Voltage 70% of Non-Core Voltages Core Voltage 70% of Core Voltages Reset(s) Clock(s) Note 7.1.2 It is the designer's responsibility to verify that the power sequencing requirements of other components are also met. Although the Non-Core voltages can be powered up any time before the Core voltages, allow a reasonable time limit (for example 100 ms) between the first Non-Core voltage power-up and the last Core voltage power-up. Power-Down Sequence Allow a reasonable time limit (for example 100 ms) between the first and last voltage power-down. 7.2 Hardware Reset The device has three reset inputs pin: SYSRSTn, CDRn, MRn. The following sections describe the functionality of these signals. 7.2.1 Global System Reset (SYSRSTn) When asserted, the entire chip is placed in its initial state. Most outputs are placed in high-Z. The following output pins are still active during SYSRSTn assertion: M_CLKOUT[3:0], M_CLKOUTn[3:0] M_CKE[3:0] M_ODT[3:0] M_RESET SRD<n>_TX_P SRD<n>_TX_N USB<n>_DM USB<n>_DP Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 77 MV78230 Hardware Specifications PEX<n>_CLK_N PEX<n>_CLK_P The device has an optional SYSRST_OUTn open drain output signal, that is used as a reset request from the device to the board reset logic. This signal is set when one of the following maskable events occurs. In each of these cases, SYSRST_OUTn is asserted for a duration of 100 ms: Received a hot reset indication from the PCI Express port 0 link when used as a PCI Express endpoint, and bit <PCIe0RstOutMaskSysRstOut> is cleared to 0, and <GlobalSoftRstOutEn> is set to 1 in the RSTOUTn Mask Register (offset 0x00018260) (see the System Registers appendix of the device’s Functional Specifications). PCI Express port 0 link failure, when used as a PCI Express endpoint, and bit <PCIe0RstOutMaskSysRstOut> is cleared to 0, and <GlobalSoftRstOutEn> is set to 1 in the RSTOUTn Mask Register (see the System Registers appendix of the device’s Functional Specifications). One of the Watchdog timers expires and bit <WDRstOutEn> of the relevant watchdog counter is set to 1 in the RSTOUTn Mask Register (see the System Registers appendix of the device’s Functional Specifications). Bit <SystemSoftRst> is set to 1 in System Soft Reset Register (offset 0x00018264) and bit <SoftRstOutEn> is set to 1 in RSTOUTn Mask Register (offset 0x00018260) (see the System Registers appendix of the device’s Functional Specifications). An assertion of the internal power-on-reset (POR) circuit (see Section 7.4, Power On Reset (POR), on page 80 for further details). This assertion is not maskable. The duration of this assertion is for at least 100ms. SYSRST_OUTn is asserted as long as the MRn input signal is asserted low, and for an additional at least 100 ms after MRn de-assertion (This is useful for implementations that include a manual reset button). Note 7.2.1.1 SYSRSTn must be active for a minimum length of 20 ms. Core power, I/O power, and analog power must be stable (VDD +/- 5%) during that time and onward. SYSRSTn Duration Counter When SYSRSTn is asserted low, a SYSRSTn duration counter starts counting. It continues to count as long as the SYSRSTn signal remains asserted. The counter clock is the 25 MHz reference clock. It is a 29-bit counter, yielding a maximum counting duration of 2^29/25 MHz (21.4 seconds). The host software can read the counter value and reset the counter. When the counter reaches its maximum value, it remains at this value until the counter reset is triggered by software. See the device’s Functional Specifications for details on how to configure the SYSRSTn duration counter. Note The SYSRSTn duration counter is useful for implementing manufacturer/factory reset. Upon a long reset assertion, greater than a pre-configured threshold, the host software may reset all settings to the factory default values. Doc. No. MV-S106687-00 Rev. H Page 78 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization PCI Express Reset 7.2.2 Manual Reset (MRn) The Manual Reset pin (MRn) provide the user the ability to reset the device without powering down the device. This is useful for implementations that include a reset button. Once MRn pin is asserted low, the device’s reset logic, that includes a bouncer circuit to avoid false reset spikes, will propagate a reset indication to the SYSRST_OUTn pin. The SYSRST_OUTn will be asserted as long as the MRn pin is kept asserted and for additional 100ms. The external (on board) logic may drive this indication back to the SYSRSTn pin to reset the device, and in addition use the SYSRST_OUTn pin to reset the entire board. 7.2.3 Marvell® Core Processor CPU Debugger Reset Connect the CPU debugger reset to the CDRn pin. When the CPU Debugger reset is asserted, the device returns to its default value. The device mechanisms related to the debugger are excluded from the reset event. This includes the PLLs, the SSCG, the XTAL, and the registers controlling those mechanisms. In general, the CDRn is de-asserted after all processes on the TAP controller are completed (refer to the specific Debugger specifications). CPU debugger reset should be fed into two separate circuits: The device’s CDRn pin (the reset pin for the debugger). The board reset for all other devices (not including the device’s SYSRSTn pin), since SYSRST_OUTn will not be forced by the CDR pin. 7.3 PCI Express Reset As a Root Complex, the device can generate a Hot Reset to the PCI Express port. Upon CPU setting of the PCI Express Control register’s <ConMstrHot Reset> bit, the PCI Express unit sends a Hot Reset indication to the Endpoint (see the PCI Express Interface section in the device’s Functional Specifications). When the device works as an Endpoint, and a Hot Reset packet is received: A maskable interrupt is asserted. If the PCI Express Debug Control register’s <DisHotResetRegRst> is cleared, the device also resets the PCI Express register file to its default values. The device triggers an internal reset, if not masked by PCI Express Debug Control register’s <ConfMskHotReset> bit. Link failure is detected if the PCI Express link was up (LTTSSM L0 state) and dropped back to an inactive state (LTSSM Detect state). When Link failure is detected: A maskable interrupt is asserted If the PCI Express Debug Control register’s <DisLinkFailRegRst> is cleared, the device also resets the PCI Express register file to its default values. The device triggers an internal reset, if not masked by PCI Express Debug Control register’s <ConfMskLinkFail> bit. Whether initiated by a hot reset or link failure, this internal reset indication can be routed to the PCIe_RSTOUTn signal (multiplexed on MPP[43]) to reset components on the board without resetting the entire device (e.g reset only the endpoint card). Note Only the PCIe0 port (or PCIe0.0 port in Quad x1 configuration) can act as a PCI Express endpoint, and only this port can generate the PCI Express internal reset indication. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 79 MV78230 Hardware Specifications 7.4 Power On Reset (POR) The device integrates a Power On Reset (POR) circuit. The circuit is triggered when the VDD (digital core voltage) and VDD_CPU (CPU core Voltage) power up levels reach a VDD threshold (with a threshold maximum value of 0.8V). Hysteresis: Another trigger will only occur after any of the power first drops to 50 mV, and then a power up occurs. Once the POR logic was triggered the SYSRST_OUTn output signal is asserted low for 100 ms. The SYSRST_OUTn signal may be connected externally to the device’s SYSRSTn input signal asserting the device’s internal reset signal. In addition, the SYSRST_OUTn signal may be used in this case as the POR generator for the entire board. 7.5 Reset Configuration The device uses certain pins as configuration inputs to set certain critical parameters following a reset. The definition of the sampled at reset configuration pins revert immediately after reset to their regular function. 7.5.1 Pin Sampling Configuration The following pins are sampled during SYSRSTn de-assertion. Some of the device’s pins integrate an internal pull-up/pull-down resistors to set a default mode. Smaller external pull-up/pull-down resistors are required to change the default mode of operation, if required. These signals must remain pulled up or down until SYSRSTn de-assertion (zero Hold time in respect to SYSRSTn de-assertion). Note If external logic is used instead of pull-up and pull-down resistors, the logic must drive all of these signals to the desired values during SYSRSTn assertion. To prevent bus contention on these pins, the external logic must float the bus no later than the third TCLK cycle after SYSRSTn de-assertion. All reset sampled values are registered in the Sample at Reset register (see the MPP Registers in the device’s Functional Specifications). This is useful for board debug purposes and identification of board and system settings for the host software. If a signal is pulled up on the board for reset sampling, it must be pulled to the appropriate voltage level of the power domain that the signal is assigned to. For example, if MPP[X] should be pulled up for reset sampling, it should be pulled to the voltage level of the VDDO who is feeding MPP[X] according to the pin description table. If an external device is driving any of the pins that are used as sampled at reset signals, make sure to keep this external device in reset state (prevent it from driving) or use glue logic to disconnect it from the device as long as the device SYSRSTn input is asserted. Doc. No. MV-S106687-00 Rev. H Page 80 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization Reset Configuration Table 36 lists the reset configuration pins for the device. Table 36: Reset Configuration Pins Pi n s P ow e r R a i l C o n fi gu r a t io n F u nc t io n SAR Register1 B it L o c a t i o n UA0_TXD VDDO_MISC I2C0 Serial ROM Initialization [0] 0x0 = Disabled 0x1 = Enabled NOTE: Internally pulled down to 0x0. UA1_TXD VDDO_MISC I2C1 Debug Port [1] 0x0 = Disabled 0x1 = Enabled NOTE: Internally pulled down to 0x0. DEV_AD[7] VDDO_DEV PCI Express Clock (100 MHz Differential Clock) Configuration [2] 0x0 = PCIe clock input enable. The device uses an external source for PCI Express clock. Pins PEX0_CLK_N/P are inputs. PEX1_CLK_N/P are not used. 0x1 = PCIe clock output enable. The device uses an internally generated clock for PCI Express clock. Pins PEX0_CLK_N/P and PEX1_CLK_N/P are outputs, driving out the PCI Express differential clock. NOTE: Internally pulled to 0x1. DEV_AD[15] VDDO_DEV Boot Device Width [3] For boot via NOR/NAND flash: 0x0 = 8 bits 0x1 = 16 bits For boot via SPI flash: 0x0 = SPI 32 bits 0x1 = SPI 24 bits NOTE: Internally pulled down to 0x0. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 81 MV78230 Hardware Specifications Table 36: Reset Configuration Pins (Continued) Pi n s P ow e r R a i l C o n fi gu r a t io n F u nc t io n SAR Register1 B it L o c a t i o n DEV_AD[14:11] VDDO_DEV Boot Device Type Selection [8:5] 0x0 = BootROM enabled, Boot from Device (NOR) flash 0x1 = BootROM enabled, Boot from NAND flash (see NAND Flash Page Type Initialization Sequence / SERDES Selection for more details) 0x2 = BootROM enabled, Boot from UART 0x3 = BootROM enabled, Boot from SPI0 (CS0) 0x4 = BootROM enabled, Boot from PCIe Port 0.0 0x5 = BootROM enabled, Boot from SATA Port (see NAND Flash Page Type Initialization Sequence / SERDES Selection for more details) 0x6 = Reserved 0x7 = BootROM enabled, UART debug prompt mode NOTE: 1. If DEV_AD[14:11] are set to 0x3, MPP[39:36] pins wake up as SPI flash signals (affect default value of MPPSel registers). 2. Internally pulled to 0x0. MPP[0] VDDO_A VDDO_C Voltage Select [9] 0x0 = 1.8V 0x1 = 3.3V NOTE: Internally pulled up to 0x1. MPP[36] VDDO_D VDDO_DEV Voltage Select [10] 0x0 = 1.8V 0x1 = 3.3V NOTE: Internally pulled up to 0x1. MPP[2:1] VDDO_A NAND Flash Page Type Initialization Sequence / SERDES Selection [12:11] Only relevant if booting with NAND Flash. 0x0 = 512B 0x1 = 2KB 0x2 = 4KB 0x3 = 8KB If booting with SATA, select the SERDES lane that the initialization sequence uses: 0x0 = Lane 4 (SATA0) 0x1 = Lane 5 (SATA1) 0x2 = Lane 6 (SATA0) 0x3 = Reserved NOTE: Internally pulled down to 0x0. Doc. No. MV-S106687-00 Rev. H Page 82 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization Reset Configuration Table 36: Reset Configuration Pins (Continued) Pi n s P ow e r R a i l C o n fi gu r a t io n F u nc t io n SAR Register1 B it L o c a t i o n MPP[4] VDDO_A DEV_WEn and DEV_OEn multiplexing option for A[16:15] bits. [13] In case boot device is a NOR flash, defines if OE and WE are latched at first ALE cycle as A[15] and A[16]. This fact influences the OEn and WEn signal as follows: 0 = A[16:15] bits are not multiplexed on OE and WE signals. Whenever CS is inactive OE and WE are inactive. 1 = A[16:15] bits are multiplexed on OE and WE signals. Whenever CS is inactive and ALE[1:0] are high, OE and WE are inactive. NOTE: Internally pulled down to 0x0. MPP[13:12] VDDO_B NAND Flash ECC Algorithm [15:14] In case boot device is NAND flash, defines the type of ECC algorithm that is used by the internal bootROM for ECC calculation on the boot NAND flash: 0x0 = 4-bit ECC 0x1 = 8-bit ECC 0x2 = 12-bit ECC 0x3 = 16-bit ECC NOTE: Internally pulled down to 0x2. MPP[3] VDDO_A Reserved [16] This signal must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled up to 0x1. MPP[38] VDDO_D Reserved [17] This signal must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled up to 0x1. MPP[14] VDDO_B SSCG Disable [18] 0 = Enable 1 = Disable NOTE: Internally pulled to 0x1. {MPP[27], MPP[15]} MPP[27]: VDDO_C MPP[15]: VDDO_B Reserved [20:19] These signals must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled to 0x3. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 83 MV78230 Hardware Specifications Table 36: Reset Configuration Pins (Continued) Pi n s P ow e r R a i l C o n fi gu r a t io n F u nc t io n SAR Register1 B it L o c a t i o n {DEV_ALE[0], DEV_AD[10:8]} VDDO_DEV CPU0 Clock Frequency Select {[52], [23:21]} {GE_MDC, DEV_AD[6:3]} GE_MDC: VDDO_A DEV_AD[6:3]: VDDO_DEV Determines the frequency of CPU(0): 0x0 = 1000 MHz 0x1 = 1066 MHz 0x2 = 1200 MHz 0x3 = 1333 MHz 0x4 = 1500 MHz 0x9 = 667 MHz 0xA = 800 MHz 0xB = 1600 MHz All other options are reserved. NOTE: Internally pulled to 0x3. Fabric Frequency Options [51, 27:24] Determines the ratios between PCLK0, NBCLK, and DRAMCLK clock. For full details about the various options, refer to Section 5, Clocking, on page 64. NOTE: Internally pulled to 0x5. MPP[24] VDDO_C Reserved [28] This signal must be sampled as 0x0 at reset de-assertion. NOTE: Internally pulled down to 0x0. DEV_AD[2:1] VDDO_DEV Reserved [30:29] This signal must be sampled as 0x0 at reset de-assertion. These signals must be sampled as 0x0 at reset de-assertion. NOTE: Internally pulled down to 0x0. DEV_A[1:0] VDDO_DEV Reserved [32:31] These signals must be sampled as 0x3 at reset de-assertion. NOTE: Internally pulled down to 0x0. DEV_AD[0] VDDO_DEV Reserved [33] NOTE: This signal must be sampled as 0x0 at reset de-assertion. DEV_ALE[1] VDDO_DEV CPU0 Non-maskable Fast Interrupt Enable [34] Disables fast interrupt software masking. 0 = Software masking for fast interrupts 1 = Software cannot mask fast interrupts NOTE: Internally pulled down to 0x0. Doc. No. MV-S106687-00 Rev. H Page 84 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization Serial ROM Initialization Table 36: Reset Configuration Pins (Continued) Pi n s P ow e r R a i l C o n fi gu r a t io n F u nc t io n SAR Register1 B it L o c a t i o n MPP[48] VDDO_DEV Reserved [35] This signal must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled down to 0x0. DEV_A[2] VDDO_DEV CPU0 Pclk WFI Enable [38] Enable wake-up from interrupt through a debugger. 0 = Disable 1 = Enable NOTE: With WFI enabled, there is no effective power saving. This feature is used for Debug mode only. Internally pulled down to 0x0. DEV_OEn VDDO_DEV Reserved [39] This signal must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled up to 0x1. DEV_WEn[0] VDDO_DEV Reserved [41] This signal must be sampled as 0x1 at reset de-assertion. NOTE: Internally pulled up to 0x1. DEV_WEn[1] VDDO_DEV Reserved [42] This signal must be sampled as 0x0 at reset de-assertion. NOTE: Internally pulled down to 0x0. 1. Bits[31:0] refer to the Sample at Reset register (offset: 0x00018230). Bits[63:32] refer to the Sample at Reset High register (offset:0x00018234). Both registers are defined in the device’s Functional Specifications. 7.6 Serial ROM Initialization The device supports initialization of ALL of its internal and configuration registers through the I2C0 master interface. If serial ROM initialization is enabled by pulling up I2C0 Serial ROM Initialization during SYSRSTn assertion, the device I2C0 master starts reading initialization data from serial ROM and writes it to the appropriate registers. 7.6.1 Serial ROM Data Structure The Serial ROM data structure consists of a sequence of 32-bit address and 32-bit data pairs, as shown in Figure 7. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 85 MV78230 Hardware Specifications Figure 7: Serial ROM Data Structure Start MSB LSB address0[31:24] address0[23:16] address0[15:8] address0[7:0] data0[31:24] data0[23:16] data0[15:8] data0[7:0] address1[31:24] address1[23:16] address1[15:8] address1[7:0] data1[31:24] data1[23:16] data1[15:8] data1[7:0] The serial ROM initialization logic reads eight bytes at a time. It performs address decoding on the 32-bit address being read, and based on address decoding result, writes the next four bytes to the required target. The Serial Initialization Last Data Register contains the expected value of last serial data item (default value is 0xFFFFFFFF). When the device reaches last data, it stops the initialization sequence. Note 7.6.2 Users must not generate requests through the I2C0 auto-loader to addresses that are not 32-bit aligned. Serial ROM Initialization Operation On SYSRSTn de-assertion, the device starts the initialization process. It first performs a dummy write access to the serial ROM, with data byte(s) of 0x0, to set the ROM byte offset to 0x0. Then, it performs a sequence of reads, until it reaches last data item, as shown in Figure 8. Doc. No. MV-S106687-00 Rev. H Page 86 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Reset and Initialization Boot Sequence Figure 8: Serial ROM Read Example s t a r t w r i t e s 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 ROM Address 0 0 0 0 0 0 0 0 Data from ROM r e a d s 1 0 1 0 0 0 0 1 a c k a c k a c k s t a r t Lower Byte Offset Upper Byte Offset ROM Address A A A A A A A A a c k A A A A a c k Last Data from ROM 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 a c k 1 1 1 1 1 1 1 1 a c k s t o p 1 1 1 1 1 1 1 1 a c k x x x x x x x x a c k p n a c k Implementation Notes: Initialization data must be programmed in the serial ROM starting at offset 0x0. The serial EEPROM must contain two address offset bytes (16-bits). These bytes must not be less than a 256 byte ROM. The device assumes 7-bit serial ROM address of ‘b1010000. After receiving the last data identifier (default value is 0xFFFFFFFF), the device receives an additional byte of dummy data. It responds with no-ack, and then asserts the stop bit. For a detailed description of I2C implementation, see the I2C Interface section in the device’s Functional Specifications. 7.7 Boot Sequence The device requires that SYSRSTn stay asserted for at least 100 ms after power and clocks are stable. The following procedure describes the boot sequence starting with SYSRSTn assertion: 1. While SYSRSTn is asserted, the CPU PLL and the core PLL are locked. 2. Upon SYSRSTn de-assertion, the pad drive auto-calibration process starts and the DRAM PHY DLL starts to lock on the target frequency speed. It requires 3ms to gain lock indication and be ready for normal operation. 3. If Serial ROM initialization is enabled, an initialization sequence is started. Upon completing the above sequence, the internal CPU reset is de-asserted, and the CPU starts executing boot code from the internal Boot ROM, according to sample at reset setting of Boot Device Type Selection. For boot sequence details, see the BootROM Firmware section in the device’s Functional Specifications. As part of the CPU boot code, the CPU typically performs these steps: 1. Configures the PCI Express address map. 2. Configure device bus timing parameters, according to devices attached to device bus. 3. Configures the proper SDRAM controller parameters, and then triggers SDRAM initialization. 4. Sets <InitEn> bit [0] to 1 in the SDRAM Initialization Control register. Initializes proper ECC to the entire SDRAM space. 5. Sets the <PEXxEn> bits in the SoC Control register to wake up the PCI Express link. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 87 MV78230 Hardware Specifications 8 JTAG Interface The MV78230 JTAG interface is used for chip boundary scan, and for CPU core debugging and tracing. The device supports the following test modes: Boundary scan The JT_TMS_CPU is kept high. This state resets the CPUs and the ETM DAP controllers, and multiplexes the boundary scan TDO signal on the JT_TDO pin. CPU debugger and trace The JT_TMS_CORE is kept high. This state resets the MV78230 TAP controller, and multiplexes the ETM DAP controller TDO signal on the JT_TDO pin. Figure 9 shows the connection between the JTAG signals, between the ETM DAP controller, and the device’s AP controller. Figure 9: ETM-JTAG-AP-Parallel Mode CSTDI[1] DAP nCSTRST[1] CSTCK[1] JT_TDI JT_RSTn JT_CLK JT_TMS_CPU CPU1-CP14 AP Controller CSTMS[1] CSTDO[1] ETM DAP DAP Controller CSTDI[0] nCSTRST[0] CSTCK[0] CPU0-CP14 AP Controller CSTMS[0] CSTDO[0] Debug TDO JT_RSTn JT_CLK JT_TMS_CORE JT_TDO Core DAP Controller Boundary Scan TDO JT_TDI ICE JTAG Chain mode 8.1 Instruction Register The Instruction register (IR) is a 4-bit, two-stage register. It contains the command that is shifted in when the DAP FSM is in the Shift-IR state. When the DAP FSM is in the Capture-IR state, the IR outputs all four bits in parallel. Doc. No. MV-S106687-00 Rev. H Page 88 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary JTAG Interface Bypass Register Table 37 lists the instructions supported by the device. Table 37: Supported JTAG Instructions 8.2 In s t r u c t io n C o de D es c r ip t i o n HIGH-Z 00011 Select the single bit Bypass register between TDI and TDO. Sets the device output pins to high-impedance state. IDCODE 00010 Selects the Identification register between TDI and TDO. This 32-bit register is used to identify the device. EXTEST 00000 Selects the Boundary Scan register between TDI and TDO. Outputs the boundary scan register cells to drive the output pins of the device. Inputs the boundary scan register cell to sample the input pin of the device. SAMPLE/ PRELOAD 00001 Selects the Boundary Scan register between TDI and TDO. Samples input pins of the device to input boundary scan register cells. Preloads the output boundary scan register cells with the Boundary Scan register value. BYPASS 11111 Selects the single bit Bypass register between TDI and TDO. This allows for rapid data movement through an untested device. Bypass Register The Bypass register (BR) is a single bit serial shift register that connects TDI to TDO, when the IR holds the Bypass command, and the DAP FSM is in Shift-DR state. Data that is driven on the TDI input pin is shifted out one cycle later on the TDO output pin. The Bypass register is loaded with 0 when the DAP FSM is in the Capture-DR state. 8.3 JTAG Scan Chain The JTAG Scan Chain is a serial shift register used to sample and drive all of the device pins during the JTAG tests. It is a 2-bit per pin shift register in the device, thereby allowing the shift register to sequentially access all of the data pins both for driving and strobing data. For further details, refer to the BSDL Description file for the device. 8.4 ID Register The ID register is a 32-bit deep serial shift register. The ID register is loaded with vendor and device information when the DAP FSM is in the Capture-DR state. The Identification code format of the ID register is shown in Table 38, which describes the various ID Code fields. Table 38: IDCODE Register Map B i ts Va l u e Description 31:28 0x2 Version 27:12 0x8230 Part number 11:1 0x1AB Manufacturer ID 0 1 Mandatory Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 89 MV78230 Hardware Specifications 9 Electrical Specifications 9.1 Absolute Maximum Ratings Table 39: Absolute Maximum Ratings Parameter Min Max Units C o m m e n ts VDD -0.5 1.1 V Core voltage VDD_CPU -0.5 1.32 V CPU core and CPU subsystem voltage CORE_TDM_PLL_AVDD -0.5 2.2 V Analog supply for the internal PLL CPU_PLL_AVDD -0.5 2.2 V Analog supply for the CPU PLL VDDO_M -0.5 2.2 V I/O voltage for: SDRAM interface VDDO_A, VDDO_B, VDDO_C, VDDO_D -0.5 4 V I/O voltage for: SMI interface, Device Bus interface, and MPP[47:0] VDDO_DEV -0.5 4 V I/O voltage for: Device Bus interface and MPP[48] VDDO_MISC -0.5 4 V I/O voltage for: I2C0/1, UART0/1/2/3, SPI0/1, and JTAG interfaces and the following signals: • SYSRSTn • SYSRST_OUTn • MRn • CDRn VDDO_FPD -0.5 2.2 V I/O voltage for: Flat Panel Display interface USB_AVDD -0.5 4 V I/O voltage for: USB interface USB_AVDDL -0.5 2.2 V I/O voltage for: USB interface SRD_AVDD -0.5 2.2 V I/O voltage for: SERDES interface RTC_AVDD -0.5 4 V I/O voltage for: RTC interface XTAL_AVDD -0.5 2.2 V I/O voltage for: XTAL interface Doc. No. MV-S106687-00 Rev. H Page 90 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Absolute Maximum Ratings Table 39: Absolute Maximum Ratings (Continued) Parameter Min Max Units C o m m e n ts AVS_SSCG_AVDD -0.5 2.2 V I/O voltage for: SSCG, CPU AVS, and Core AVS blocks VHV -0.5 2.2 V I/O voltage for: eFuse (for eFuse burning only) TC -40 125 °C Case temperature TSTG -40 125 °C Storage temperature Caution Note Exposure to conditions at or beyond the maximum rating can damage the device. Operation beyond the recommended operating conditions (Table 40) is neither recommended nor guaranteed. Before designing a system, it is recommended that you read application note AN-63: Thermal Management for Marvell® Technology Products. This application note presents basic concepts of thermal management for Integrated Circuits (ICs) and includes guidelines to ensure optimal operating conditions for Marvell Technology's products. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 91 MV78230 Hardware Specifications 9.2 Recommended Operating Conditions Table 40: Recommended Operating Conditions Parameter Min Ty p Max Units C om m e nts VDD 0.85 0.9 0.95 V Core voltage VDD_CPU 1 1.05 1.10 V NOTE: CPU core and CPU voltage The 1.1V is supported by the AVS feature for specific clock configurations. The power source must be set to 1.05V. The AVS unit will drive the power source to adjust the voltage to 1.1V. For additional details, see Table 30, Clock Frequency Options, on page 65. 1.05 1.1 1.15 V CORE_TDM_PLL_ AVDD 1.7 1.8 1.9 V Analog supply for the internal PLL CPU_PLL_AVDD 1.7 1.8 1.9 V Analog supply for the CPU PLL VDDO_M 1.283 1.35 1.418 V 1.425 1.5 1.575 V I/O voltage for: SDRAM DDR3 (1.5/1.35V) NOTE: If DDR3 is configured to 800 MHz, VDDO_M must be operating at 1.5V. 1.7 1.8 1.9 V 1.7 1.8 1.9 V 2.375 2.5 2.625 I/O voltage for: SMI interface and MPP[23:0] pins 3.15 3.3 3.45 1.7 1.8 1.9 V 3.15 3.3 3.45 I/O voltage for: MPP[35:24] pins VDDO_D 3.15 3.3 3.45 V I/O voltage for: MPP[47:36] pins VDDO_DEV 1.7 1.8 1.9 V 3.15 3.3 3.45 I/O voltage for: Device Bus interface and MPP[48] VDDO_A, VDDO_B VDDO_C Doc. No. MV-S106687-00 Rev. H Page 92 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Recommended Operating Conditions Table 40: Recommended Operating Conditions (Continued) Parameter Min Ty p Max Units C om m e nts VDDO_MISC 3.15 3.3 3.45 V I/O voltage for: I2C0/1, UART0/1/2/3, SPI0/1, and JTAG interfaces and the following signals: • SYSRSTn • SYSRST_OUTn • MRn • CDRn VDDO_FPD 1.7 1.8 1.9 V I/O voltage for: Flat Panel Display interface USB_AVDD 3.15 3.3 3.45 V I/O voltage for: USB interface USB_AVDDL 1.7 1.8 1.9 V I/O voltage for: USB interface SRD_AVDD 1.7 1.8 1.9 V Voltage for: SERDES interface RTC_AVDD 3.15 3.3 3.45 V I/O voltage for: RTC interface (via the board) 2.6 3 3.6 V I/O voltage for: RTC interface (via the battery) XTAL_AVDD 1.7 1.8 1.9 V I/O voltage for: XTAL interface AVS_SSCG_AVDD 1.7 1.8 1.9 V I/O voltage for: SSCG, CPU AVS, and Core AVS blocks VHV 1.7 1.8 1.9 V I/O voltage for: eFuse (for eFuse burning only) TJ 0 105 °C Junction Temperature Caution Operation beyond the recommended operating conditions is neither recommended nor guaranteed. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 93 MV78230 Hardware Specifications 9.3 Thermal Power Dissipation Note The device was characterized and tested for production at 105°C. The other data points are for reference purposes only. Table 41: Core and CPU Thermal Power Dissipation In t e r f a c e Sy m b o l P a r a m e te r Power U n i ts Core PVDD Core at 250 MHz, VDD=0.9V, Tj=85°C 1.5 W Core at 250 MHz, VDD=0.9V, Tj=105°C 1.9 W CPU0/1 at 800 MHz, L2 at 400 MHz, VDD_CPU=1.05V, Tj=85°C 3.3 W CPU0/1 at 800 MHz, L2 at 400 MHz, VDD_CPU=1.05V, Tj=105°C 4.2 W CPU0/1 at 1066 MHz, L2 at 533 MHz, VDD_CPU=1.05V, Tj=85°C 3.6 W CPU0/1 at 1066 MHz, L2 at 533 MHz, VDD_CPU=1.05V, Tj=105°C 4.6 W CPU0/1 at 1333 MHz, L2 at 667 MHz, VDD_CPU=1.05V, Tj=85°C 4 W CPU0/1 at 1333 MHz, L2 at 667 MHz, VDD_CPU=1.05V, Tj=105°C 5 W CPU0/1 at 1600 MHz, L2 at 800 MHz, VDD_CPU=1.1V, Tj=85°C 4.9 W CPU0/1 at 1600 MHz, L2 at 800 MHz, VDD_CPU=1.1V, Tj=105°C 5.9 W Embedded CPU0, CPU1, and 1 MB L2 cache PVDD_CPU Doc. No. MV-S106687-00 Rev. H Page 94 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Thermal Power Dissipation Table 42: I/O Interface Thermal Power Dissipation In t e r f a c e Sy m b o l P a r a m e te r Power U n i ts DDR3 interface (40-bit, 400 MHz, 1.5V) PVDDO_M M_CLKOUT = 400 MHz, 4 DRAM ranks,75 ohm internal termination, 40 ohm DRAM termination 0.6 W DDR3 interface (40-bit, 667 MHz, 1.35V) M_CLKOUT = 667 MHz, 2 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 0.5 W DDR3 interface | (40-bit, 667 MHz, 1.5V) M_CLKOUT = 667 MHz, 4 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 0.7 W DDR3 interface (40-bit, 800 MHz, 1.5V) M_CLKOUT = 800 MHz, 2 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 0.7 W One Port, VDDO = 3.3V 100 mW RGMII 2.5V interface One Port, VDDO = 2.5V 60 mW RGMII 1.8V interface One Port, VDDO = 1.8V 35 mW VDDO = 3.3V, Trace Length = 5 inches 360 mW VDDO = 1.8V Trace Length = 5 inches 110 mW RGMII 3.3V interface LCD 3.3V interface PRGMII PLCD LCD 1.8V interface SERDES interface PSRD_AVDD Single Serdes Port 95 mW USB interface PUSB_AVDD Three USB Ports 99 mW USB interface PUSB_AVDDL 180 mW Notes: 1. The power dissipation values are for a device operating at the nominal recommended voltage. 2. The Trace length is 3 inches, unless otherwise specified. 3. The power values for each interface are stated relevant to the common application usage. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 95 MV78230 Hardware Specifications 9.4 SoC Power Dissipation for Power Management Unit Low Power Modes The MV78230 Power Management Unit (PMU) controls power management functions and enables the optimization of the device’s overall power consumption and performance. The PMU allows for Idle, Deep Idle, and Sleep low power modes that supply different levels of power consumption, with hardware controlling wake-up events and power mode transitions. Table 43 lists the MV78230 power dissipation for specific SoC configurations, and not the total power of the device. The following system configuration were used for testing: Dual core CPU @ 1600 MHz DDR 32-bit (ECC and dual CS), 1.5V@ 800 MHz 1 SGMII SERDES 2 x PCIe x1 1 SATA 1 USB SPI Note For more details on the MV78230 power modes and additional PMU features, refer to the Power Management Unit section of the MV78230 Functional Specifications. To calculate the overall power for any other SoC configuration, use the power values in Table 41 on page 94 and Table 42. . Table 43: SoC Power Dissipation Po w er M o d e Run Thermal P o w e r Wa t ts ( W ) N o te s CPU Subsystem SoC Core DDR S E R D ES O th e r i n t e r f ac e s 1 Tota l 5.9 1.9 0.7 0.4 0.5 9.4 2 4.9 1.5 0.7 0.4 0.5 8 3 2.4 1.5 0.7 0.4 0.5 5.5 4 0.07 1.5 0.7 0.4 0.5 3.17 5 0.07 0.8 0 0 0.2 1.07 6 CPU/L2 – On SERDES – On DDR – On Run Typical CPU/L2 – On SERDES – On DDR – On Idle CPU/L2 – WFI SERDES – On DDR – On Deep Idle CPU/L2 – Off SERDES – On DDR – On Sleep CPU/L2 – Off SERDES – Off DDR – Self-Refresh Doc. No. MV-S106687-00 Rev. H Page 96 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications SoC Power Dissipation for Power Management Unit Low Power Modes Notes: 1. 2. 3. 4. 5. 6. Other interfaces include: 1xUSB, GPIO, PLLs, XTAL, RTC, JTAG, I2C, and UART. Run Thermal: Voltages are in nominal values, Tj=105°C, CPU is running stress test Run Typical: Voltages are in nominal values, Tj=85°C Idle: Voltage are in nominal values, Tj=85°C, CPU is in Wait for Interrupt (WFI) mode Deep Idle: voltage are in nominal values, Tj=85°C, CPU is in Deep Idle mode Sleep: User Activated mode. Tj=35°C, CPU in Deep Idle mode, SERDES are Powered down, USB PHY is shutdown, DDR in Self Refresh mode. Peripheral interfaces are set as clock gated, and wake from GPIO. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 97 MV78230 Hardware Specifications 9.5 Current Consumption . Table 44: Current Consumption In t e r f a c e S y m b ol Te s t C o nd i ti on s Max Units Core IVDD Core at 250 MHz, VDD=0.9V, Tj=85°C 1.6 A Core at 250 MHz, VDD=0.9V, Tj=105°C 2 A CPU0/1 at 800 MHz, L2 at 400 MHz, VDD_CPU=1.05V, Tj=85°C 3.6 A CPU0/1 at 800 MHz, L2 at 400 MHz, VDD_CPU=1.05V, Tj=105°C 4.6 A CPU0/1 at 1066 MHz, L2 at 533 MHz, VDD_CPU=1.05V, Tj=85°C 4.2 A CPU0/1 at 1066 MHz, L2 at 533 MHz, VDD_CPU=1.05V, Tj=105°C 5.1 A CPU0/1 at 1333 MHz, L2 at 667 MHz, VDD_CPU=1.05V, Tj=85°C 4.7 A CPU0/1 at 1333 MHz, L2 at 667 MHz, VDD_CPU=1.05V, Tj=105°C 5.6 A CPU0/1 at 1600 MHz, L2 at 800 MHz, VDD_CPU=1.1V, Tj=85°C 5.4 A CPU0/1 at 1600 MHz, L2 at 800 MHz, VDD_CPU=1.1V, Tj=105°C 6.4 A M_CLKOUT = 400 MHz, 4 DRAM ranks, 75 ohm internal termination, 150 ohm DRAM termination 1 A DDR3 interface (40-bit, 667 MHz, 1.35V) M_CLKOUT = 667 MHz, 2 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 0.9 A DDR3 interface (40-bit, 667 MHz, 1.5V) M_CLKOUT = 667 MHz, 4 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 1.2 A DDR3 interface (40-bit, 800 MHz, 1.5V) M_CLKOUT = 800 MHz, 2 DRAM ranks, 75 ohm internal termination, 40 ohm DRAM termination 1.2 A One Port, VDDO = 3.3V 60 mA RGMII 2.5V interface One Port, VDDO = 2.5V 50 mA RGMII 1.8V interface One Port, VDDO = 1.8V 40 mA Embedded CPU0, CPU1, and 1 MB L2 cache DDR3 interface (40-bit, 400 MHz, 1.5V) RGMII 3.3V interface IVDD_CPU IVDDO_M IRGMII NOTE: IVDDO_A and IVDDO_B can be reduced to equal IRGMII when the GbE interface is configured to RGMII mode. Doc. No. MV-S106687-00 Rev. H Page 98 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Current Consumption Table 44: Current Consumption In t e r f a c e S y m b ol Te s t C o nd i ti on s Max Units LCD 3.3V interface ILCD VDDO = 3.3V, Trace Length = 5 inches 450 mA VDDO = 1.8V, Trace Length = 5 inches 250 mA LCD 1.8V interface NOTE: IVDDO_A, IVDDO_B, and IVDDO_C can be reduced to equal ILCD when the MPP pins are configured to support the LCD interface. SERDES interface ISRD_AVDD For a single SERDES port 60 mA USB interface IUSB_AVDD For three ports 30 mA 100 mA 3V battery supply 4 uA 3.3V battery supply 5 uA IVDDO_A MPP[11:0], GE_MDC, GE_MDIO 96 mA IVDDO_B MPP[23:12] 96 mA IVDDO_C MPP[35:24] 96 mA IVDDO_D MPP[47:36] 96 mA IVDDO_DEV MPP[48] and Device interface 50 mA Miscellaneous Signals IVDDO_MISC 3.3V JTAG, UART, TWSI, SPI, and reset signals 40 mA VHV (eFuse) Power Supply IVHV 1.8V for programming 30 mA PLL ICORE_TDM_ 1.8V Core PLL and TDM PLL 20 mA 1.8V CPU PLL 20 mA IUSB_AVDDL RTC Interface IRTC_AVDD MPP NOTE: All MPP pins are configured as GPIOs and consume the current as tested in Section 9.6.1, General 3.3V (CMOS) DC Electrical Specifications, on page 100. PLL_AVDD ICPU_PLL_ AVDD XTAL IXTAL_AVDD 1.8V XTAL 50 mA LVDS IVDDO_FPD 1.8V Flat Panel Display 40 mA IAVS_SSCG_ 1.8V SSCG, CPU AVS, and Core AVS blocks 25 mA AVS AVDD Notes: 1. 2. 3. 4. 5. Trace is 3 inches, unless otherwise specified. Current in mA is calculated using maximum recommended voltage specification for each power rail. All output clocks toggling at their specified rate. Maximum drawn current from the power supply. The typical RTC_AVDD current at 3V is 1.5 uA. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 99 MV78230 Hardware Specifications 9.6 DC Electrical Specifications See the Pin Description Section for internal pullup/pulldown information. Note 9.6.1 General 3.3V (CMOS) DC Electrical Specifications The DC electrical specifications in Table 45 are applicable for the following interfaces and signals: Device JTAG MPP SMI UART SYSRSTn SYSRST_OUTn MRn CDRn Table 45: General 3.3V Interface (CMOS) DC Electrical Specifications Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.3 0.8 V - Input high level VIH 2.0 VDDIO+0.3 V - Output low level VOL IOL = 8 mA - 0.6 V - Output high level VOH IOH = -8 mA 2.2 - V - 0 < VIN < VDDIO -10 10 uA 1, 2 pF - Input leakage current Pin capacitance IIL Cpin 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Doc. No. MV-S106687-00 Rev. H Page 100 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications DC Electrical Specifications 9.6.2 General 2.5V (CMOS) DC Electrical Specifications The DC electrical specifications in Table 46 are applicable for the following interfaces and signals: MPP[23:0] SMI Table 46: General 2.5V Interface (CMOS) DC Electrical Specifications Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.3 0.7 V - Input high level VIH 1.7 VDDIO+0.3 V - Output low level VOL IOL = 8 mA - 0.6 V - Output high level VOH IOH = -8 mA 1.8 - V - Input leakage current IIL 0 < VIN < VDDIO -10 10 uA 1, 2 Pin capacitance Cpin pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. 9.6.3 General 1.8V (CMOS) DC Electrical Specifications The DC electrical specifications in Table 47 are applicable for the following interfaces and signals: eFuse MPP[35:0] Device Bus Table 47: General 1.8V Interface (CMOS) DC Electrical Specifications Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.3 0.35*VDDIO V - Input high level VIH 0.65*VDDIO VDDIO+0.3 V - Output low level VOL IOL = 8 mA - 0.45 V - Output high level VOH IOH = -8 mA VDDIO-0.45 - V - Input leakage current IIL 0 < VIN < VDDIO -10 10 uA 1, 2 Pin capacitance Cpin pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 101 MV78230 Hardware Specifications 9.6.4 Flat Panel Display (LVDS) DC Electrical Specifications Table 48: Flat Panel Display Interface (LVDS) DC Electrical Specifications Param eter Sym bol Test Condition Min Output high level single ended VOH RL = 50 Ohm Output low level single ended VOL RL = 50 Ohm 850 Output differential voltage VOD RL = 50 Ohm 500 Output common mode voltage VOS RL = 50 Ohm Input leakage current IIL 0 < VIN < VDDIO Pin capacitance Cpin Typ Max 1550 Units Notes mV - mV - 900 mV - 1050 1350 mV - -20 20 uA 1, 2 pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Doc. No. MV-S106687-00 Rev. H Page 102 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications DC Electrical Specifications 9.6.5 SDRAM DDR3 (1.5V) Interface DC Electrical Specifications VDDIO refers to the VDDO_M pin. Note Table 49: SDRAM DDR3 (1.5V) Interface DC Electrical Specifications Param eter Sym bol Single ended input low level Test Condition Min Typ Max VDDIO/2 0.100 VIL -0.3 Single ended input high level VIH VDDIO/2 + 0.100 Differential input low level VDIL Note 6 Differential input high level VDIH 0.2 0.2*VDDIO Output low level VOL IOL = 8.8 mA Units Notes V - V - -0.2 V 6 Note 6 V 6 V 7 V 7 VDDIO + 0.3 Output high level VOH IOH = -8.8 mA Rtt effective impedance value RTT See note 2 50 70 ohm 1,2 Deviation of VM w ith respect to VDDIO/2 dVm See note 3 -5 5 % 3 0 < VIN < VDDIO -10 10 uA 4, 5 pF - Input leakage current IIL Pin capacitance Cpin 0.8*VDDIO - 60 5 Notes: 1. See SDRAM functional description section for ODT configuration. 2. Measurement definition for RTT: Apply (VDDIO/2) +/- 0.15 to input pin separately, then measure current I(VDDIO/2 + 0.15) and I(VDDIO/2 - 0.15) respectively. RTT I ( 0 .30 I VDDIO 0 . 15 ) 2 ( VDDIO 0 . 15 ) 2 3. Measurement definition for VM: Measured voltage (VM) at input pin (midpoint) w ith no load. 2 Vm dVM 1 100 % VDDIO 4. While I/O is in High-Z. 5. This current does not include the current flow ing through the pullup/pulldow n resistor. 6. Limitations are same as for single ended signals. 7. Defined w hen driver impedance is calibrated to 35 ohms. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 103 MV78230 Hardware Specifications 9.6.6 SDRAM DDR3L (1.35V) Interface DC Electrical Specifications Note VDDIO refers to the VDDO_M pin. VREF is VDDO_M/2. Table 50: SDRAM DDR3L (1.35V) Interface DC Electrical Specifications Param eter Sym bol Single ended input low level Test Condition Min Typ Max VDDIO/2 0.09 VIL -0.3 Single ended input high level VIH VDDIO/2 + 0.09 VDDIO + 0.3 Differential input low level VDIL Note 6 Differential input high level VDIH 0.16 Output low level VOL IOL = 8.8 mA Output high level VOH IOH = -8.8 mA Rtt effective impedance value RTT See note 2 50 Deviation of VM w ith respect to VDDIO/2 dVm See note 3 -5 0 < VIN < VDDIO -10 Input leakage current IIL Pin capacitance Cpin V - V - -0.16 V 6 Note 6 V 6 0.2*VDDIO V 7 V 7 70 ohm 1,2 5 % 3 10 uA 4, 5 pF - 0.8*VDDIO - 60 5 Units Notes Notes: 1. See SDRAM functional description section for ODT configuration. 2. Measurement definition for RTT: Apply (VDDIO/2) +/- 0.15 to input pin separately, then measure current I(VDDIO/2 + 0.15) and I(VDDIO/2 - 0.15) respectively. RTT I ( VDDIO 2 0 .30 I 0 . 15 ) ( VDDIO 2 0 . 15 ) 3. Measurement definition for VM: Measured voltage (VM) at input pin (midpoint) w ith no load. 2 Vm dVM 1 100 % VDDIO 4. While I/O is in High-Z. 5. This current does not include the current flow ing through the pullup/pulldow n resistor. 6. Limitations are same as for single ended signals. 7. Defined w hen driver impedance is calibrated to 35 ohms. Doc. No. MV-S106687-00 Rev. H Page 104 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications DC Electrical Specifications I2C Interface 3.3V DC Electrical Specifications 9.6.7 Table 51: I2C Interface 3.3V DC Electrical Specifications Param eter Sym bol Test Condition Input low level VIL Input high level VIH Output low level VOL IOL = 3 mA Input leakage current IIL 0 < VIN < VDDIO Pin capacitance Cpin Min Typ Max Units Notes -0.5 0.3*VDDIO V - 0.7*VDDIO VDDIO+0.5 V - - 0.4 V - -10 10 uA 1, 2 pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. 9.6.8 Serial Peripheral Interface (SPI) 3.3V DC Electrical Specifications Table 52: SPI Interface 3.3V DC Electrical Specifications Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.5 0.3*VDDIO V - Input high level VIH 0.7*VDDIO VDDIO+0.5 V - Output low level VOL IOL = 4 mA - 0.4 V - Output high level VOH IOH = -4 mA VDDIO-0.6 - V - Input leakage current IIL 0 < VIN < VDDIO -10 10 uA 1, 2 Pin capacitance Cpin pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 105 MV78230 Hardware Specifications 9.6.9 Time Division Multiplexing (TDM) 3.3V DC Electrical Specifications Table 53: TDM Interface 3.3V DC Electrical Specifications Param eter Sym bol Test Condition Input low level VIL Input high level VIH Output low level VOL IOL = 4 mA Output high level VOH IOH = -4 mA Input leakage current IIL 0 < VIN < VDDIO Pin capacitance Cpin Min Typ Max Units Notes -0.5 0.3*VDDIO V - 0.7*VDDIO VDDIO+0.5 V - - 0.4 V - VDDIO-0.6 - V - -10 10 uA 1, 2 pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. 9.6.10 NAND Flash 3.3V DC Electrical Specification VDDIO refers to the VDDO_DEV pin. Note Table 54: NAND Flash 3.3V DC Electrical Specification Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.3 0.8 V - Input high level VIH 2.0 VDDIO+0.3 V - Output low level VOL IOL = 2 mA - 0.4 V - Output high level VOH IOH = -2 mA 0.85 * VDDIO - V - -10 10 uA 1, 2 pF - Input leakage current Pin capacitance IIL Cpin 0 < VIN < VDDIO 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Doc. No. MV-S106687-00 Rev. H Page 106 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications DC Electrical Specifications 9.6.11 NAND Flash 1.8V DC Electrical Specification VDDIO refers to the VDDO_DEV pin. Note Table 55: NAND Flash 1.8V DC Electrical Specification Param eter Sym bol Test Condition Min Typ Max Units Notes Input low level VIL -0.3 0.35*VDDIO V - Input high level VIH 0.65*VDDIO VDDIO+0.3 V - Output low level VOL IOL = 2 mA - 0.45 V - Output high level VOH IOH = -2 mA 0.85 * VDDIO - V - Input leakage current IIL 0 < VIN < VDDIO -10 10 uA 1, 2 Pin capacitance Cpin pF - 5 Notes: 1. While I/O is in High-Z. 2. This current does not include the current flow ing through the pullup/pulldow n resistor. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 107 MV78230 Hardware Specifications 9.7 AC Electrical Specifications See Section 9.8, Differential Interface Electrical Characteristics, on page 145 for differential interface specifications. 9.7.1 Reference Clock and Reset AC Timing Specifications Table 56: Reference Clock and Reset AC Timing Specifications D e s c r i p t io n S y m b ol M in Max U n i ts N ot e s CPU and Core Reference Clock 25 MHz Frequency FREF_CLK_XIN Accuracy PPMREF_CLK_XIN -50 50 PPM Duty cycle DCREF_CLK_XIN 40 60 % Slew rate SRREF_CLK_XIN Pk-Pk jitter 0.5 V/ns 1 0.7 V/ns 1, 2 120 ps 2, 5 200 ps JRREF_CLK_XIN R e f er e n c e C l o c k O u t 25 MHz Frequency FREFCLK_OUT Accuracy PPMREFCLK_OUT -50 50 PPM Duty cycle DCREFCLK_OUT DCREF_CLK_XIN - 5% DCREF_CLK_XIN + 5% % Pk-Pk jitter JRREFCLK_OUT JRREF_CLK_XIN + 50 ps ps 3, 4 2, 3, 5 E t h er n e t I n t e r f a c e in M II /M M II - M a c m o d e Frequency FGE0_TXCLK 2.5 50 MHz -100 100 PPM 35 65 % FGE0_RXCLK Accuracy PPMGE0_TXCLK PPMGE0_RXCLK Duty cycle DCGE0_TXCLK DCGE0_RXCLK Slew rate SRGE0_TXCLK 0.7 V/ns 1 SRGE0_RXCLK SM I Cl ock SMI output MDC clock FGE_MDC TCLK/128 TCLK/8 Doc. No. MV-S106687-00 Rev. H Page 108 MHz Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Table 56: Reference Clock and Reset AC Timing Specifications D e s c r i p t io n S y m b ol M in Max U n i ts N ot e s 100 kHz 7 50 MHz 8 I2C Master Mode Clock SCK output clock FTWSI0_SCK FTWSI1_SCK SP I O ut pu t C l o c k SPI output clock TCLK/1920 FSPI0_SCK FSPI1_SCK D E V _C L K _ O U T R ef e r e n c e C l o c k 6 Frequency FDEV_CLK_OUT TCLK/15 TCLK/4 MHz Duty cycle DCDEV_CLK_OUT 40 60 % 4 PT P R e fe r e n c e C lo c k Frequency FPTP_CLK 12.5 125 MHz Accuracy PPMPTP_CLK -100 100 PPM Duty cycle DCPTP_CLK 40 60 % Slew rate SRPTP_CLK 0.7 Pk-Pk jitter JRPTP_CLK V/ns 100 ps 1 LCD Reference Clock Frequency FLCD_EXT_REF_CLK 2.5 27 MHz Accuracy PPMLCD_EXT_REF_CLK -50 50 PPM Clock duty cycle DCLCD_EXT_REF_CLK 45 55 % Slew rate SRLCD_EXT_REF_CLK 0.7 Pk-Pk jitter JRLCD_EXT_REF_CLK 150 ps FLCD_CLK 100 MHz V/ns 1 LCD Output Clock LCD Output Frequency RTC Reference Clock RTC_XIN crystal frequency FRTC_XIN 32.768 kHz 9 M M C R ef e r e n c e C lo c k Frequency FSD0_CLK 50 MHz 15 MHz J TA G R e f e r e n c e C lo c k Frequency FJT_CLK Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 109 MV78230 Hardware Specifications Table 56: Reference Clock and Reset AC Timing Specifications D e s c r i p t io n S y m b ol M in Max U n i ts N ot e s R e s e t Sp e c if ic a t i o n s Refer to Section 7, Reset and Initialization, on page 76. Notes: 1. 2. 3. 4. 5. 6. 7. 8. 9. Slew rate is defined from 20% to 80% of the reference clock signal. This value is required when using the internal PLL to drive the SERDES. The REFCLK_OUT duty cycle/jitter is driven by the REF_CLK_XIN duty cycle/jitter. There is a 5% degradation of the output duty cycle. There is a 50 ps degradation of the output jitter. The load is CL = 15 pF. This value is assumed to contain above 95% random components characterized by 1/f behavior, defined with a BER = 1e-12. It is possible to use this reference clock when working in source synchronous device bus mode. For additional information regarding configuring this clock, see the Inter-Integrated Circuit Registers in the device’s Functional Specification. For additional information regarding configuring this clock, see the SPI Interface Configuration Register in the device’s Functional Specification. The RTC design was optimized for a standard CL = 12.5 pF crystal. No passive components are provided internally. Connect the crystal and the passive network as recommended by the crystal manufacturer. Figure 10: DEV_CLK_OUT and REFCLK_OUT Reference Clock Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 110 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Figure 11: DEV_CLK_OUT and REFCLK_OUT AC Timing Diagram Cycle Time VDDIO/2 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 111 MV78230 Hardware Specifications 9.7.2 Flat Panel Display (FPD) Interface AC Timing Note 9.7.2.1 Before designing a system implementing the Flat Panel Display (FPD) interface, contact a Marvell® Field Applications Engineer (FAE). FPD AC Timing Table Table 57: FPD AC Timing Table Description Sym bol Min Max Transmitter output clock frequency fCK - 65 MHz Transmitter clock jitter cycle-to-cycle tJCC - 0.23 ns - Transmitter clock output rise/fall time tR/tF - 1.5 ns 2 Transmitter output pulse position for Bit 0 tPPos0 -0.2 0.2 ns - Transmitter output pulse position for Bit 1 tPPos1 1/7*tCK - 0.2 1/7*tCK + 0.2 ns - Transmitter output pulse position for Bit 2 tPPos2 2/7*tCK - 0.2 2/7*tCK + 0.2 ns - Transmitter output pulse position for Bit 3 tPPos3 3/7*tCK - 0.2 3/7*tCK + 0.2 ns - Transmitter output pulse position for Bit 4 tPPos4 4/7*tCK - 0.2 4/7*tCK + 0.2 ns - Transmitter output pulse position for Bit 5 tPPos5 5/7*tCK - 0.2 5/7*tCK + 0.2 ns - Transmitter output pulse position for Bit 6 tPPos6 6/7*tCK - 0.2 6/7*tCK + 0.2 ns - tCCS - 0.25 ns - Transmitter channel-to-channel skew Units Notes 1 Notes: General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General comment: tCK = 1/fCK. 1. See functional specification for available operating frequencies. 2. Defined from 20% to 80% of the transition. Doc. No. MV-S106687-00 Rev. H Page 112 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.2.2 FPD AC Timing Diagram Figure 12: FPD AC Timing Diagram tF tR 80% Clock (Differential) 20% 80% Data (Differential) 20% tPPos0 tPPos1 tPPos2 tPPos3 tPPos4 tPPos5 tPPos6 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 113 MV78230 Hardware Specifications 9.7.3 Liquid Crystal Display Interface AC Timing Note 9.7.3.1 Before designing a system implementing the Liquid Crystal Display (LCD) interface, contact a Marvell® Field Applications Engineer (FAE). LCD AC Timing Table Table 58: LCD AC Timing Table Description Sym bol DCLK clock frequency fCK Min Max See note 2 Units Notes MHz 2 DCLK clock high time tWCH 0.45 0.55 tCK 1 DCLK clock low time tWCL 0.45 0.55 tCK 1 Output Data & Data Enable invalid relative to DCLK rise time tOIV -1.25 1.25 ns 1, 3 Output Data & Data Enable valid granularity tOVG - 0.1 ns 1, 3 Notes: General comment: General comment: All values w ere measured from vddio/2 to vddio/2, unless otherw ise specified. General comment: tCK = 1/fCK. 1. For all signals, the load is CL = 10 pF. 2. See "Reference Clocks" table for more details. 3. The granularity should be considered w hen changing default data w indow position. See functional specification for more information. 9.7.3.2 LCD Test Circuit Figure 13: LCD Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 114 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.3.3 LCD AC Timing Diagram Figure 14: LCD Transmit AC Timing Diagram tWCL tWCH Output Clock Output Data tOIVmin tOIVmax Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 115 MV78230 Hardware Specifications 9.7.4 Reduced Gigabit Media Independent Interface (RGMII) AC Timing 9.7.4.1 RGMII AC Timing Table Table 59: RGMII AC Timing Table Description Sym bol Clock frequency Data to Clock output skew Tskew T Data to Clock input skew Min Max 125.0 fCK -0.50 0.50 Units Notes MHz - ns 2 Tskew R 1.00 2.60 ns - Tcyc 7.20 8.80 ns 1,2 Duty cycle for Gigabit Duty_G 0.45 0.55 tCK 2 Duty cycle for 10/100 Megabit Duty_T 0.40 0.60 tCK 2 Clock cycle duration Notes: General comment: All values w ere measured from vddio/2 to vddio/2, unless otherw ise specified. General comment: tCK = 1/fCK. General comment: If the PHY does not support internal-delay mode, the PC board design requires routing clocks so that an additional trace delay of greater than 1.5 ns and less than 2.0 ns is added to the associated clock signal. For 10/100 Mbps RGMII, the Max value is unspecified. 1. For RGMII at 10 Mbps and 100 Mbps, Tcyc w ill scale to 400 ns +/-40 ns and 40 ns +/-4 ns, respectively. 2. For all signals, the load is CL = 5 pF. 9.7.4.2 RGMII Test Circuit Figure 15: RGMII Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 116 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.4.3 RGMII AC Timing Diagram Figure 16: RGMII AC Timing Diagram TX CLOCK (At Transmitter) TX DATA TskewT RX CLOCK (At Receiver) RX DATA TskewR Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 117 MV78230 Hardware Specifications 9.7.5 Gigabit Media Independent Interface (GMII) AC Timing 9.7.5.1 GMII AC Timing Table Table 60: GMII AC Timing Table 125 MHz Sym bol Min Max Units Notes tCK 7.5 8.5 ns - RX_CLK cycle time tCKrx 7.5 - ns - GTX_CLK and RX_CLK high level w idth tHIGH 2.5 - ns 1 GTX_CLK and RX_CLK low level w idth tLOW 2.5 - ns 1 tR - 1.0 ns 1, 2 Description GTX_CLK cycle time GTX_CLK and RX_CLK rise time GTX_CLK and RX_CLK fall time tF - 1.0 ns 1, 2 Data input setup time relative to RX_CLK rising edge tSETUP 2.0 - ns - Data input hold time relative to RX_CLK rising edge tHOLD 0.0 - ns - Data output valid before GTX_CLK rising edge tOVB 2.5 - ns 1 Data output valid after GTX_CLK rising edge tOVA 0.5 - ns 1 Notes: General comment: All values w ere measured from VIL(max) to VIH(min), unless otherw ise specified. 1. For all signals, the load is CL = 5 pF. 2. Rise time measured from VIL(max) to VIH(min), fall time measured from VIH(min) to VIL(max). 9.7.5.2 GMII Test Circuit Figure 17: GMII Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 118 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.5.3 GMII AC Timing Diagrams Figure 18: GMII Output AC Timing Diagram tLOW tHIGH VIH(min) GTX_CLK VIL(max) VIH(min) TXD, TX_EN, TX_ER VIL(max) tOVB tOVA Figure 19: GMII Input AC Timing Diagram tLOW tHIGH VIH(min) RX_CLK VIL(max) VIH(min) RXD, RX_EN, RX_ER VIL(max) tSETUP tHOLD Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 119 MV78230 Hardware Specifications 9.7.6 Media Independent Interface (MII/MMII) AC Timing 9.7.6.1 MII/MMII MAC Mode AC Timing Table Table 61: MII/MMII MAC Mode AC Timing Table Description Sym bol Min Max Units Notes Data input setup relative to RX_CLK rising edge tSU 3.5 - ns - Data input hold relative to RX_CLK rising edge tHD 2.0 - ns - Data output delay relative to MII_TX_CLK rising edge tOV 0.0 10.0 ns 1 Notes: General comment: All values w ere measured from VIL(max) to VIH(min), unless otherw ise specified. 1. For all signals, the load is CL = 5 pF. 9.7.6.2 MII/MMII MAC Mode Test Circuit Figure 20: MII/MMII MAC Mode Test Circuit Test Point CL 9.7.6.3 MII/MMII MAC Mode AC Timing Diagrams Figure 21: MII/MMII MAC Mode Output Delay AC Timing Diagram Vih(min) MII_TX_CLK Vil(max) Vih(min) TXD, TX_EN, TX_ER Vil(max) TOV Doc. No. MV-S106687-00 Rev. H Page 120 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Figure 22: MII/MMII MAC Mode Input AC Timing Diagram Vih(min) RX_CLK Vih(min) RXD, RX_EN, RX_ER Vil(max) tSU tHD Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 121 MV78230 Hardware Specifications 9.7.7 Serial Management Interface (SMI) AC Timing 9.7.7.1 SMI Master Mode AC Timing Table Table 62: SMI Master Mode AC Timing Table Description Sym bol MDC clock frequency Min fCK Max See note 2 Units Notes MHz 2 MDC clock duty cycle tDC 0.4 0.6 tCK - MDIO input setup time relative to MDC rise time tSU 12.0 - ns - MDIO input hold time relative to MDC rise time tHO 0.0 - ns 3 MDIO output valid before MDC rise time tOVB 12.0 - ns 1 MDIO output valid after MDC rise time tOVA 12.0 - ns 1 Notes: General comment: All timing values w ere measured from VIL(max) and VIH(min) levels, unless otherw ise specified. General comment: tCK = 1/fCK. 1. For all signals, the load is CL = 10 pF. 2. See "Reference Clocks" table for more details. 3. For this parameter, the load is CL = 2 pF. 9.7.7.2 SMI Master Mode Test Circuit Figure 23: MDIO Master Mode Test Circuit VDDIO Test Point 2 kilohm MDIO CL Doc. No. MV-S106687-00 Rev. H Page 122 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Figure 24: MDC Master Mode Test Circuit Test Point MDC CL 9.7.7.3 SMI Master Mode AC Timing Diagrams Figure 25: SMI Master Mode Output AC Timing Diagram VIH(min) MDC VIH(min) MDIO VIL(max) tOVB tOVA Figure 26: SMI Master Mode Input AC Timing Diagram VIH(min) MDC VIH(min) MDIO VIL(max) tSU tHO Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 123 MV78230 Hardware Specifications 9.7.8 SDRAM DDR3 Interface AC Timing 9.7.8.1 SDRAM DDR3 Interface Timing Tables The timing values in the following table are based on a tuning algorithm that runs automatically during the device initialization. For more information, contact your local Marvell® representative. Note Table 63: SDRAM DDR3 (667 MHz) Interface AC Timing Table 667 MHz Description Sym bol Clock frequency Min Max 667.0 fCK Units Notes MHz - DQ and DM valid output time before DQS transition tDOVB 215 - ps - DQ and DM valid output time after DQS transition tDOVA 215 - ps - CLK-CLKn Period Jitter tJIT(per) -80 80 ps 1 DQS falling edge setup time to CLK-CLKn rising edge tDSS 0.34 - tCK(avg) - DQS falling edge hold time from CLK-CLKn rising edge tDSH 0.34 - tCK(avg) - DQS latching rising transitions to associated clock edges tDQSS -0.11 0.11 tCK(avg) - Address and Control valid output time before CLK-CLkn rising edge tAOVB 440 - ps 2 Address and Control valid output time after CLK-CLKn rising edge tAOVA 450 - ps 2 DQ input setup time relative to DQS in transition tDSI -275 - ps - DQ input hold time relative to DQS in transition tDHI 475 - ps - Notes: General comment: All timing values are defined from VREF to VREF, unless otherw ise specified. General comment: All input timing values assume minimum slew rate of 1 V/ns (slew rate defined from VREF +/-100 mV). General comment: All timing parameters w ith DQS signal are defined on DQS-DQSn crossing point. General comment: All timing parameters w ith CLK signal are defined on CLK-CLKn crossing point. General comment: For all signals, the load is CL = 10 pF. General comment: tCK = 1/fCK. 1. tJIT(per) = Min/max of {tCKi - tCK w here i = 1 to 200}. 2. This timing value is defined w hen Address and Control signals are output on CLK-CLKn falling edge. Note The timing values in the following table are based on a tuning algorithm that runs automatically during device initialization. For more information, contact your local Marvell® representative. Doc. No. MV-S106687-00 Rev. H Page 124 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Table 64: SDRAM DDR3 (800 MHz) Interface AC Timing Table 800 MHz Description Sym bol Clock frequency Min Max 800.0 fCK Units Notes MHz - DQ and DM valid output time before DQS transition tDOVB 185 - ps - DQ and DM valid output time after DQS transition tDOVA 185 - ps - CLK-CLKn Period Jitter tJIT(per) -70 70 ps 1 DQS falling edge setup time to CLK-CLKn rising edge tDSS 0.32 - tCK(avg) - DQS falling edge hold time from CLK-CLKn rising edge tDSH 0.32 - tCK(avg) - tDQSS -0.13 0.13 tCK(avg) - DQS latching rising transitions to associated clock edges Address and Control valid output time before CLK-CLkn rising edge tAOVB 420 - ps 2 Address and Control valid output time after CLK-CLKn rising edge tAOVA 350 - ps 2 DQ input setup time relative to DQS in transition tDSI -260 - ps - DQ input hold time relative to DQS in transition tDHI 365 - ps - Notes: General comment: All timing values are defined from VREF to VREF, unless otherw ise specified. General comment: All input timing values assume minimum slew rate of 1 V/ns (slew rate defined from VREF +/-100 mV). General comment: All timing parameters w ith DQS signal are defined on DQS-DQSn crossing point. General comment: All timing parameters w ith CLK signal are defined on CLK-CLKn crossing point. General comment: For all signals, the load is CL = 4.6 pF. General comment: tCK = 1/fCK. 1. tJIT(per) = Min/max of {tCKi - tCK w here i = 1 to 200}. 2. This timing value is defined w hen Address and Control signals are output on CLK-CLKn falling edge. 9.7.8.2 SDRAM DDR3 Interface Test Circuit Figure 27: SDRAM DDR3 Interface Test Circuit VDDIO/2 Test Point 50 ohm CL Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 125 MV78230 Hardware Specifications 9.7.8.3 SDRAM DDR3 Interface AC Timing Diagrams Figure 28: SDRAM DDR3 Interface Write AC Timing Diagram tDQSS CLK tCH tCL CLKn DQSn DQS DQ tDOVB tDOVA Figure 29: SDRAM DDR3 Interface Address and Control AC Timing Diagram CLK tCH tCL CLKn ADDRESS/ CONTROL tAOVB tAOVA Doc. No. MV-S106687-00 Rev. H Page 126 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications Figure 30: SDRAM DDR3 Interface Read AC Timing Diagram DQS DQSn DQ tDSI tDHI Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 127 MV78230 Hardware Specifications 9.7.9 Secure Digital Input/Output (SDIO) Interface AC Timing 9.7.9.1 Secure Digital Input/Output (SDIO) AC Timing Table Table 65: SDIO Host in High-Speed Mode AC Timing Table Description Symbol Min Max Units Notes fCK 0 50 MHz - Clock high/low level pulse w idth tWL/tWH 0.35 - tCK 1, 3 Clock rise/fall time tTLH/tTHL - 3.0 ns 1, 3 CMD, DAT output valid before CLK rising edge tDOVB 6.5 - ns 2, 3 CMD, DAT output valid after CLK rising edge tDOVA 2.5 - ns 2, 3 CMD, DAT input setup relative to CLK rising edge tISU 7.0 - ns 2 CMD, DAT input hold relative to CLK rising edge tIHD 0.0 - ns 2, 4 Clock frequency in Data Transfer Mode Notes: General comment: tCK = 1/fCK. 1. Defined on VIL(max) and VIH(min) levels. 2. Defined on VDDIO/2 for Clock signal, and VIL(max) / VIH(min) for CMD & DAT signals. 3. For all signals, the load is CL = 10 pF. 4. For this parameter, the load is CL = 2 pF. 9.7.9.2 Secure Digital Input/Output (SDIO) Test Circuit Figure 31: Secure Digital Input/Output (SDIO) Test Circuit VDDIO Test Point 50 KOhm CL Doc. No. MV-S106687-00 Rev. H Page 128 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.9.3 Secure Digital Input/Output (SDIO) AC Timing Diagrams Figure 32: SDIO Host in High Speed Mode Output AC Timing Diagram tWL tWH VIH(min) VDDIO/2 CLK VIL(max) VIH(min) DAT, CMD VIL(max) tDOVB tDOVA Figure 33: SDIO Host in High Speed Mode Input AC Timing Diagram tWL tWH VIH(min) VDDIO/2 CLK VIL(max) VIH(min) DAT, CMD VIL(max) tISU tIHD Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 129 MV78230 Hardware Specifications 9.7.10 Multimedia Card (MMC) Interface AC Timing 9.7.10.1 MMC AC Timing Table Table 66: MMC Host AC Timing Table Description Sym bol Clock frequency in Data Transfer mode fCK Clock high/low level pulse w idth tWL/tWH Clock rise/fall time Min Max See note 5 0.34 - Units Notes MHz 5 tCK 1, 3 tTLH/tTHL - 3.0 ns 1, 3 CMD, DAT output valid before CLK rising edge tDOVB 3.5 - ns 2, 3 CMD, DAT output valid after CLK rising edge tDOVA 3.5 - ns 2, 3 CMD, DAT input setup relative to CLK rising edge tISU 6.5 - ns 2 CMD, DAT input hold relative to CLK rising edge tIHD 0.0 - ns 2, 4 Notes: General comment: tCK = 1/fCK. 1. Defined on VIL(max) and VIH(min) levels. 2. Defined on VDDIO/2 for Clock signal, and VIL(max) / VIH(min) for CMD and DAT signals. 3. For all signals, the load is CL = 10 pF. 4. For this parameter, the load is CL = 2 pF. 5. See "Reference Clocks" table for more details. 9.7.10.2 MMC Test Circuit Figure 34: MMC Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 130 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.10.3 MMC AC Timing Diagrams Figure 35: MMC High-Speed Host Output AC Timing Diagram tWL tWH VIH(min) VDDIO/2 CLK VIL(max) VIH(min) DAT, CMD VIL(max) tDOVB tDOVA Figure 36: MMC High-Speed Host Input AC Timing Diagram tWL tWH VIH(min) VDDIO/2 CLK VIL(max) VIH(min) DAT, CMD VIL(max) tISU tIHD Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 131 MV78230 Hardware Specifications 9.7.11 Device Bus Interface AC Timing 9.7.11.1 Device Bus Interface AC Timing Table Table 67: Device Bus Interface AC Timing Table Sym bol Min Max Units Notes Data/READYn input setup relative to clock rising edge Description tSU 7.0 - ns - Data/READYn input hold relative to clock rising edge tHD 1.0 - ns - Address/Data output delay relative to clock rising edge tOV 0.8 8.0 ns 1 Address output valid before ALE signal falling edge tAOAB 10.0 - ns 1,2 Address output valid after ALE signal falling edge tAOAA 6.0 - ns 1,2 Notes: General comment: All timing values are for interfacing synchronous devices. General comment: All values w ere measured from VIL(max) to VIH(min), unless otherw ise specified. 1. For all signals, the load is CL = 10 pF. 2. The AD bus is normally loaded w ith high capacitance. Make sure to w ork according to hardw are design guidelines or simulations to meet the latch AC timing requirements. 9.7.11.2 Device Bus Interface Test Circuit Figure 37: Device Bus Interface Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 132 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.11.3 Device Bus Interface AC Timing Diagram Figure 38: Device Bus Interface Output Delay AC Timing Diagram Vih(min) CLOCK Vil(max) Vih(min) DATA Vil(max) TOV(min) TOV(max) Vih(min) ALE Vil(max) Vih(min) AD Bus Vil(max) TAOAB TAOAA Figure 39: Device Bus Interface Input AC Timing Diagram Vih(min) CLOCK Vil(max) Vih(min) DATA Vil(max) tSU tHO Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 133 MV78230 Hardware Specifications 9.7.12 Serial Peripheral Interface (SPI) AC Timing 9.7.12.1 SPI (Master Mode) AC Timing Table Table 68: SPI (Master Mode) AC Timing Table SPI Description Sym bol Min Max Units Notes MHz 3 SCLK clock frequency fCK SCLK high time tCH 0.46 - tCK 1, 2 SCLK low time tCL 0.46 - tCK 1, 2 SCLK slew rate tSR 0.5 - V/ns 1 tDOV -2.5 2.5 ns 1 Data out valid relative to SCLK falling edge See Note 3 CS active before first SCLK rising edge tCSB 0.4 - tCK 1, 4 CS not active after SCLK rising edge tCSA 0.4 - tCK 1, 4 Data in setup time relative to SCLK rising edge tSU 0.2 - tCK 2 Data in hold time relative to SCLK rising edge tHD 5.0 - ns 2 Notes: General comment: All values w ere measured from 0.3*vddio to 0.7*vddio, unless otherw ise specified. General comment: tCK = 1/fCK. 1. For all signals, the load is CL = 10 pF. 2. Defined from vddio/2 to vddio/2. 3. See "Reference Clocks" table for more details. 4. When w orking w ith CPOL=1 mode, the CS is relative to first SCLK falling edge. 9.7.12.2 SPI (Master Mode) Test Circuit Figure 40: SPI (Master Mode) Test Circuit Test Point CL Doc. No. MV-S106687-00 Rev. H Page 134 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.12.3 SPI (Master Mode) Timing Diagrams Figure 41: SPI (Master Mode) AC Timing Diagram tCL tCH CPOL=1 SCLK CPOL=0 CS tCSB MOSI tCSA CPHA=0 tDOVmin tDOVmax MOSI CPHA=1 tDOVmin tDOVmax MISO CPHA=0 tSU tHD MISO CPHA=1 tSU tHD Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 135 MV78230 Hardware Specifications 9.7.13 Time Division Multiplexing (TDM) Interface AC Timing 9.7.13.1 TDM Interface AC Timing Table Table 69: TDM Interface AC Timing Table 8.192 MHz Description Sym bol Min Max Units Notes 1/tC 0.256 8.192 MHz 1, 3 PCLK accuracy tPPM -50 50 ppm 1 PCLK period jitter tCJIT -8 8 ns 1 PCLK duty cycle tDTY 0.4 0.6 tC 1 PCLK rise/fall time tR/tF - 3 ns 1, 2, 8 PCLK frequency 125 FSYNC period tFS us 1 FSYNC period jitter tFJIT -120 120 ns 1 tD 0 20 ns 1, 4, 6 DRX and FSYNC setup time relative to PCLK falling edge tSU 10 - ns 5, 7 DRX and FSYNC hold time relative to PCLK falling edge tHD 10 - ns 5, 7 DTX and FSYNC valid after PCLK rising edge Notes: General comment: All values w ere measured from vddio/2 to vddio/2, unless otherw ise specified. 1. For all signals, the load is CL = 20 pF. 2. Rise and Fall times are referenced to the 20% and 80% levels of the w aveform. 3. PCLK can be configured to several frequency options. Refer to the Functional Specifications or to the Clock settings for details. 4. This parameter is relevant for the FSYNC signal in Master mode only. 5. This parameter is relevant for the FSYNC signal in Slave mode only. 6. In negative-mode, the DTX signal is relative to PCLK falling edge. 7. In negative-mode, the DRX signal is relative to PCLK rising edge. 8. This parameter is relevant w hen the PCLK pin is output. Doc. No. MV-S106687-00 Rev. H Page 136 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.13.2 High Level Data Link Control (HDLC) AC Timing Table Table 70: HDLC Interface AC Timing Table Description Sym bol Min Max Units Notes PCLK frequency 1/tC See note #3 MHz 1, 3 PCLK accuracy tPPM -50 50 ppm 1 PCLK duty cycle tDTY 0.4 0.6 tC 1 PCLK rise/fall time tR/tF - 3 ns 1, 2 tD 1 10 ns 1, 4 DTX and FSYNC valid after PCLK rising edge DRX and FSYNC setup time relative to PCLK falling edge tSU 4 - ns 5 DRX and FSYNC hold time relative to PCLK falling edge tHD 1 - ns 5 Notes: General comment: All values w ere measured from vddio/2 to vddio/2, unless otherw ise specified. 1. For all signals, the load is CL = 10 pF. 2. Rise and Fall times are referenced to the 20% and 80% levels of the w aveform. 3. PCLK can be configured to several frequency options. Refer to the Functional Specifications or to the Clock settings for details. 4. In negative-mode, the DTX signal is relative to PCLK falling edge. 5. In negative-mode, the DRX signal is relative to PCLK rising edge. 9.7.13.3 TDM Interface Test Circuit Figure 42: TDM Interface Test Circuit Test Point CL Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 137 MV78230 Hardware Specifications 9.7.13.4 TDM Interface Timing Diagrams Figure 43: TDM Interface Output Delay AC Timing Diagram tC PCLK DTX tD tD Figure 44: TDM Interface Input Delay AC Timing Diagram tC PCLK DRX tSU tHD Doc. No. MV-S106687-00 Rev. H Page 138 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.14 Inter-integrated Circuit Interface (I2C) AC Timing 9.7.14.1 I2C AC Timing Table Table 71: I2C Master AC Timing Table Description Sym bol SCK clock frequency fCK Min Max See note 1 Units Notes kHz 1 SCK minimum low level w idth tLOW 0.47 - tCK 2 SCK minimum high level w idth tHIGH 0.40 - tCK 2 SDA input setup time relative to SCK rising edge tSU 250.0 - ns - SDA input hold time relative to SCK falling edge tHD 0.0 - ns 4 SDA and SCK rise time tr - 1000.0 ns 2, 3 SDA and SCK fall time tf - 300.0 ns 2, 3 tOV 0.0 0.4 tCK 2 SDA output delay relative to SCK falling edge Notes: General comment: All values referred to VIH(min) and VIL(max) levels, unless otherw ise specified. General comment: tCK = 1/fCK. 1. See "Reference Clocks" table for more details. 2. For all signals, the load is CL = 100 pF, and RL value can be 500 ohm to 8 kilohm. 3. Rise time measured from VIL(max) to VIH(min), fall time measured from VIH(min) to VIL(max). 4. For this parameter, the load is CL = 10 pF. Table 72: I2C Slave AC Timing Table 100 kHz (Max) Sym bol Min Max Units Notes SCK minimum low level w idth tLOW 4.7 - us 1 SCK minimum high level w idth Description tHIGH 4.0 - us 1 SDA input setup time relative to SCK rising edge tSU 250.0 - ns - SDA input hold time relative to SCK falling edge tHD 0.0 - ns - tr - 1000.0 ns 1, 2 tf - 300.0 ns 1, 2 tOV 0.0 4.0 us 1 SDA and SCK rise time SDA and SCK fall time SDA output delay relative to SCK falling edge Notes: General comment: All values referred to VIH(min) and VIL(max) levels, unless otherw ise specified. 1. For all signals, the load is CL = 100 pF, and RL value can be 500 ohm to 8 kilohm. 2. Rise time measured from VIL(max) to VIH(min), fall time measured from VIH(min) to VIL(max). Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 139 MV78230 Hardware Specifications 9.7.14.2 I2C Test Circuit Figure 45: I2C Test Circuit VDDIO Test Point RL CL 9.7.14.3 I2C AC Timing Diagrams Figure 46: I2C Output Delay AC Timing Diagram tHIGH tLOW Vih(min) SCK Vil(max) Vih(min) SDA Vil(max) tOV(min) tOV(max) Figure 47: I2C Input AC Timing Diagram tLOW tHIGH Vih(min) SCK Vil(max) Vih(min) SDA Vil(max) tSU tHD Doc. No. MV-S106687-00 Rev. H Page 140 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.15 JTAG Interface AC Timing 9.7.15.1 JTAG Interface AC Timing Table Table 73: JTAG Interface AC Timing Table Description Sym bol Min Max Units Notes MHz - JTClk frequency fCK JTClk minimum pulse w idth Tpw 0.45 0.55 tCK - JTClk rise/fall slew rate Sr/Sf 0.5 - V/ns 2 JTRSTn active time Trst 1.0 - ms - Tsetup 0.2*tCK - ns - TMS, TDI input hold relative to JTClk rising edge Thold 0.4*tCK - ns - JTClk falling edge to TDO output delay Tprop 1.0 0.25*tCK ns 1 TMS, TDI input setup relative to JTClk rising edge See Note 3 Notes: General comment: All values w ere measured from vddio/2 to vddio/2, unless otherw ise specified. General comment: tCK = 1/fCK. 1. For TDO signal, the load is CL = 10 pF. 2. Defined from VIL to VIH for rise time, and from VIH to VIL for fall time. 3. See "Reference Clocks" table for more details. 9.7.15.2 JTAG Interface Test Circuit Figure 48: JTAG Interface Test Circuit Test Point CL Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 141 MV78230 Hardware Specifications 9.7.15.3 JTAG Interface AC Timing Diagrams Figure 49: JTAG Interface Output Delay AC Timing Diagram Tprop (max) JTCK VIH VIL TDO Tprop (min) Figure 50: JTAG Interface Input AC Timing Diagram JTCK TMS,TDI Tsetup Doc. No. MV-S106687-00 Rev. H Page 142 Thold Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications AC Electrical Specifications 9.7.16 NAND Flash Interface AC Timing 9.7.16.1 NAND Flash AC Timing Table Table 74: NAND Flash AC Timing Table Description Sym bol Min Max Units Notes WEn cycle time tWC 35 - ns 1 WEn minimum low pulse w idth tWP 15 - ns 1, 2 WEn minimum high pulse w idth tWH 17 - ns 1, 2 ALE to WEn skew factor tASK -3.5 3.5 ns 2, 3 CLE to WEn skew factor tCLSK -3.5 3.5 ns 2, 3 CEn to WEn skew factor tCSK -3.5 3.5 ns 2, 3 Data output bus to WEn skew factor tDSK -3.5 3.5 ns 2, 3 REn cycle time tRC 35 - ns 1 REn minimum low pulse w idth tRP 15 - ns 1, 2 REn minimum high pulse w idth tREH 17 - ns 1, 2 Data input to REn rising edge skew factor tISK -3.5 3.5 ns 2, 3 Notes: General comment: All values w ere measured from VIL(max) to VIH(min), unless otherw ise specified. 1. See functional specifications for configuration options. 2. For all signals, the load is CL = 10 pF. 3. Skew factor should be taken into consideration as a timing degradation in addition to register settings. Refer to functional specifications for more information about timing adjustment possibilities. 9.7.16.2 NAND Flash Test Circuit Figure 51: NAND Flash Test Circuit Test Point CL Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 143 MV78230 Hardware Specifications 9.7.16.3 NAND Flash AC Timing Diagrams Figure 52: NAND Flash Input AC Timing Diagram tRC tRP tREH VIH(min) REn VIL(max) VIH(min) Data VIL(max) tISK tISK Figure 53: NAND Flash Output AC Timing Diagram tWC tWP tWH VIH(min) WEn VIL(max) VIH(min) Data / CEn / CLE / ALE VIL(max) t*SK t*SK Doc. No. MV-S106687-00 Rev. H Page 144 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8 Differential Interface Electrical Characteristics This section provides the reference clock, AC, and DC characteristics for the following differential interfaces: PCI Express (PCIe) Interface Electrical Characteristics SATA Interface Electrical Characteristics USB Electrical Characteristics Serial Gigabit Media Independent Interface (SGMII) Interface Electrical Characteristics Double Rated-SGMII (DR-SGMII) Electrical Characteristics Quad Serial Gigabit Media Independent Interface (QSGMII) Electrical Characteristics Serial Embedded Trace Macrocell (sETM) Interface Electrical Characteristics Note The Tx and Rx timing parameters are defined with the relevant reference clock specifications as specified in the Hardware Specifications. 9.8.1 Differential Interface Reference Clock Characteristics 9.8.1.1 PCI Express Interface Differential Reference Clock Characteristics Table 75 is relevant for PEX0_CLK_P/N and PEX1_CLK_P/N. Note Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 145 MV78230 Hardware Specifications Table 75: PCI Express Interface Differential Reference Clock Characteristics Description Sym bol Clock frequency Min Max Units Notes MHz - 100 fCK Clock duty cycle DCrefclk 0.4 0.6 tCK - Differential rising/falling slew rate SRrefclk 0.6 4 V/ns 3 Differential high voltage VIHrefclk 150 - mV - Differential low voltage VILrefclk - -150 mV - Vcross 250 550 mV 1 Variation of Vcross over all rising clock edges Vcrs_dlta - 140 mV 1 Rise-Fall matching dTRrefclk - 20 % 1 Average differential clock period accuracy Tperavg -300 2800 ppm - Absolute differential clock period Tperabs 9.8 10.2 ns 2 Tccjit - 150 ps - Clock high frequency RMS jitter Thfrms - 3.1 ps RMS 4 Clock low frequency RMS jitter Tlfrms - 3 ps RMS 4 Absolute crossing point voltage Differential clock cycle-to-cycle jitter Notes: General Comment: The reference clock timings are based on 100 ohm test circuit. General Comment: Refer to the PCI Express Card Electromechanical Specification, Revision 2.0, April 2007, section 2.1.3 for more information. 1. Defined on a single-ended signal. 2. Including jitter and spread spectrum. Table 76: PCI Express Interface Spread Spectrum Requirements Sym bol Min Max Units Notes Fmod 0.0 33.0 kHz 1 Fspread -0.5 0.0 % 1 Notes: 1. Defined on linear sw eep or “Hershey’s Kiss” (US Patent 5,631,920) modulations. Note The PCIe Spread-Spectrum Clocking (SSC) only works with a PCIe reference clock input. Doc. No. MV-S106687-00 Rev. H Page 146 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.2 PCI Express (PCIe) Interface Electrical Characteristics 9.8.2.1 PCI Express Interface Driver and Receiver Characteristics Table 77: PCI Express 1.1 Interface Driver and Receiver Characteristics Description Sym bol Min Max Units Notes Baud rate BR 2.5 Gbps - Unit interval UI 400 ps - ppm 2 Baud rate tolerance Bppm -300 300 Driver parameters Differential peak to peak output voltage VTXpp 0.8 1.2 V - Minimum TX eye w idth TTXeye 0.75 - UI - Differential return loss TRLdiff 10 - dB 1 Common mode return loss TRLcm 6 - dB 1 ZTXdiff 80 120 Ohm - DC differential TX impedance Receiver parameters Differential input peak to peak voltage VRXpp 0.175 1.2 V - Minimum receiver eye w idth TRXeye 0.4 - UI - Differential return loss RRLdiff 10 - dB 1 Common mode return loss RRLcm 6 - dB 1 DC differential RX impedance ZRXdiff 80 120 Ohm - DC single-ended input impedance ZRXcm 40 60 Ohm - Notes: General Comment: For more information, refer to the PCI Express Base Specification, Revision 1.1, March, 2005. 1. Defined from 50 MHz to 1.25 GHz. Return loss includes contributions from on-chip circuitry, chip packaging, and off-chip optimized components related to the driver/receiver breakout. 2. Does not account for SSC dictated variations. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 147 MV78230 Hardware Specifications Table 78: PCI Express 2 Interface Driver and Receiver Characteristics Description Sym bol Baud rate Min Max BR Unit interval 5 UI Baud rate tolerance Bppm Units Notes Gbps - ps - -300 300 ppm 1 V - 200 Driver parameters Differential peak to peak output voltage VTXpp 0.8 1.2 Minimum TX eye w idth TTXeye 0.75 - UI - Differential return loss [50 MHz to 1.25 GHz] TRLdiff 10 - dB - Differential return loss [1.25 GHz to 2.5 GHz] TRLdiff 8 - dB - Common mode return loss TRLcm 6 - dB 2 DC differential TX impedance ZTXdiff - 120 Ohm - V - Receiver parameters Differential input peak to peak voltage VRXpp 0.1 1.2 Minimum receiver eye w idth TRXeye 0.4 - UI - Differential return loss [50 MHz to 1.25 GHz] RRLdiff 10 - dB - Differential return loss [1.25 GHz to 2.5 GHz] RRLdiff 8 - dB - Common mode return loss RRLcm 6 - dB 2 DC single-ended input impedance ZRXcm 40 60 Ohm - Notes: General Comment: For more information, refer to the PCI Express Base Specification, Revision 2.0, December 2007. 1. Does not account for SSC dictated variations. 2. Defined from 50 MHz to 2.5 GHz. Return loss includes contributions from on-chip circuitry, chip packaging, and off-chip optimized components related to the driver/receiver breakout. Doc. No. MV-S106687-00 Rev. H Page 148 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.2.2 PCI Express Interface Test Circuit Figure 54: PCI Express Interface 1.1 Test Circuit Test Points - + C_TX D+ D- C_TX 50 ohm 50 ohm When measuring Transmitter output parameters, C_TX is an optional portion of the Test/Measurement load. When used, the value of C_TX must be in the range of 75 nF to 200 nF. C_TX must not be used when the Test/Measurement load is placed in the Receiver package reference plane. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 149 MV78230 Hardware Specifications Figure 55: PCI Express Interface 2.0 Test Circuit Test Points + C_TX D+ D- C_TX 50 ohm 50 ohm When measuring Transmitter output parameters, C_TX is an optional portion of the Test/Measurement load. When used, the value of C_TX must be in the range of 75 nF to 200 nF. C_TX must not be used when the Test/Measurement load is placed in the Receiver package reference plane. Doc. No. MV-S106687-00 Rev. H Page 150 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.3 SATA Interface Electrical Characteristics Note 9.8.3.1 The tables below specify the SATA electrical characteristics at the SATA connector. Refer to the device design guide for connectivity and layout guidelines of the SATA interface. SATA I Interface Gen1 Mode Driver and Receiver Characteristics Table 79: SATA I Interface Gen1i Mode Driver and Receiver Characteristics Description Sym bol Baud Rate Min Max 1.5 BR Units Notes Gbps - Baud rate tolerance Bppm -350.0 350.0 ppm - Spread spectrum modulation frequency Fssc 30.0 33.0 kHz - Spread spectrum modulation Deviation SSCtol -5000.0 0.0 ppm - ps - Unit Interval 666.67 UI Driver Parameters Differential impedance Zdifftx 85.0 115.0 Ohm - Single ended impedance Zsetx 40.0 - Ohm - Differential return loss (75 MHz-150 MHz) RLOD 14.0 - dB - Differential return loss (150 MHz-300 MHz) RLOD 8.0 - dB - Differential return loss (300 MHz-1.2 GHz) RLOD 6.0 - dB - Differential return loss (1.2 GHz-2.4 GHz) RLOD 3.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLOD 1.0 - dB - Output differential voltage Vdifftx 400.0 600.0 mV 2 1, 3 Total jitter at connector data-data, 5UI TJ5 - 0.355 UI Deterministic jitter at connector data-data, 5UI DJ5 - 0.175 UI 3 Total jitter at connector data-data, 250UI TJ250 - 0.470 UI 1, 3 Deterministic jitter at connector data-data, 250UI DJ250 - 0.220 UI 3 - Receiver Parameters Differential impedance Zdiffrx 85.0 115.0 Ohm Single ended impedance Zsetx 40.0 - Ohm - Differential return loss (75 MHz-150 MHz) RLID 18.0 - dB - Differential return loss (150 MHz-300 MHz) RLID 14.0 - dB - Differential return loss (300 MHz-600 MHz) RLID 10.0 - dB - Differential return loss (600 MHz-1.2 GHz) RLID 8.0 - dB - Differential return loss (1.2 GHz-2.4 GHz) RLID 3.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLID 1.0 - dB - Vdiffrx 325.0 600.0 mV 1, 3 Input differential voltage Total jitter at connector data-data, 5UI TJ5 - 0.430 UI Deterministic jitter at connector data-data, 5UI DJ5 - 0.250 UI 3 Total jitter at connector data-data, 250UI TJ250 - 0.600 UI 1, 3 Deterministic jitter at connector data-data, 250UI DJ250 - 0.350 UI 3 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 151 MV78230 Hardware Specifications Notes: General Comment: For more information, refer to SATA II Revision 2.6 Specification, February, 2007. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. Total jitter is defined as TJ = (14 * RJσ) + DJ w here Rjσ is random jitter. 2. Output Differential Amplitude and Pre-Emphasis are configurabile. See the functional register description for more details. 3. The value is informative only, and it can be achieved by using a proper board layout. Refer to the hardw are design guidelines for more information. Doc. No. MV-S106687-00 Rev. H Page 152 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.3.2 SATA II Interface Gen2 Mode Driver and Receiver Characteristics Table 80: SATA II Interface Gen2i Mode Driver and Receiver Characteristics Description Sym bol Baud Rate Min Max BR Baud rate tolerance Bppm 3.0 -350.0 350.0 Units Notes Gbps - ppm - Spread spectrum modulation frequency Fssc 30.0 33.0 kHz - Spread spectrum modulation deviation SSCtol -5000.0 0.0 ppm - ps - Unit Interval UI 333.33 Driver Parameters Output differential voltage Vdifftx 400.0 700.0 mV 1,2 Differential return loss (150 MHz-300 MHz) RLOD 14.0 - dB - Differential return loss (300 MHz-600 MHz) RLOD 8.0 - dB - Differential return loss (600 MHz-2.4 GHz) RLOD 6.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLOD 3.0 - dB - Differential return loss (3.0 GHz-5.0 GHz) RLOD 1.0 - dB - Total jitter at connector clock-data TJ - 0.37 UI 4, 5 Deterministic jitter at connector clock-data DJ - 0.19 UI 5 Receiver Parameters Input differential voltage Vdiffrx 275.0 750.0 mV 3 Differential return loss (150 MHz-300 MHz) RLID 18.0 - dB - Differential return loss (300 MHz-600 MHz) RLID 14.0 - dB - Differential return loss (600 MHz-1.2 GHz) RLID 10.0 - dB - Differential return loss (1.2 GHz-2.4 GHz) RLID 8.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLID 3.0 - dB - Differential return loss (3.0 GHz-5.0 GHz) RLID 1.0 - dB - Total jitter at connector clock-data TJ - 0.60 UI 4, 5 Deterministic jitter at connector clock-data DJ - 0.42 UI 5 Notes: General Comment: For more information, refer to SATA II Revision 2.6 Specification, February, 2007. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. 0.45-0.55 UI is the range w here the signal meets the minimum level. 2. Output Differential Amplitude and Pre-Emphasis are configurabile. See the functional register description for more details. 3. 0.5 UI is the point w here the signal meets the minimum level. 4. The jitter is defined using a recovered clock w ith characteristics that meet the desired Jitter Transfer Function (JTF). The JTF is the ratio betw een the jitter defined using the recovered clock and the jitter defined using an ideal clock. It should have a high pass function w ith the follow ing characteristics: - The -3 dB corner frequency of the JTF shall be 2.1 MHz +/- 1 MHz. - The magnitude peaking of the JTF shall be 3.5 dB maximum. - The attenuation at 30 kHz +/- 1% shall be 72 dB +/- 3 dB. 5. The value is informative only, and it can be achieved by using a proper board layout. Refer to the hardw are design guidelines for more information. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 153 MV78230 Hardware Specifications Table 81: SATA II Interface Gen2m Mode Driver and Receiver Characteristics Description Sym bol Baud Rate Min Max BR Baud rate tolerance Bppm 3.0 -350.0 350.0 Units Notes Gbps - ppm - Spread spectrum modulation frequency Fssc 30.0 33.0 kHz - Spread spectrum modulation deviation SSCtol -5000.0 0.0 ppm - ps - Unit Interval UI 333.33 Driver Parameters Output differential voltage Vdifftx 400.0 700.0 mV 1,2 Differential return loss (150 MHz-300 MHz) RLOD 14.0 - dB - Differential return loss (300 MHz-600 MHz) RLOD 8.0 - dB - Differential return loss (600 MHz-2.4 GHz) RLOD 6.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLOD 3.0 - dB - Total jitter at connector clock-data TJ - 0.37 UI 4, 5 Deterministic jitter at connector clock-data DJ - 0.19 UI 5 Receiver Parameters Input differential voltage Vdiffrx 240.0 750.0 mV 3 Differential return loss (150 MHz-300 MHz) RLID 18.0 - dB - Differential return loss (300 MHz-600 MHz) RLID 14.0 - dB - Differential return loss (600 MHz-1.2 GHz) RLID 10.0 - dB - Differential return loss (1.2 GHz-2.4 GHz) RLID 8.0 - dB - Differential return loss (2.4 GHz-3.0 GHz) RLID 3.0 - dB - Total jitter at connector clock-data TJ - 0.60 UI 4, 5 Deterministic jitter at connector clock-data DJ - 0.42 UI 5 Notes: General Comment: For more information, refer to SATA II Revision 2.6 Specification, February, 2007. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. 0.45-0.55 UI is the range w here the signal meets the minimum level. 2. Output Differential Amplitude and Pre-Emphasis are configurabile. See the functional register description for more details. 3. 0.5 UI is the point w here the signal meets the minimum level. 4. The jitter is defined using a recovered clock w ith characteristics that meet the desired Jitter Transfer Function (JTF). The JTF is the ratio betw een the jitter defined using the recovered clock and the jitter defined using an ideal clock. It should have a high pass function w ith the follow ing characteristics: - The -3 dB corner frequency of the JTF shall be 2.1 MHz +/- 1 MHz. - The magnitude peaking of the JTF shall be 3.5 dB maximum. - The attenuation at 30 kHz +/- 1% shall be 72 dB +/- 3 dB. 5. The value is informative only, and it can be achieved by using a proper board layout. Refer to the hardw are design guidelines for more information. Doc. No. MV-S106687-00 Rev. H Page 154 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.4 USB Electrical Characteristics 9.8.4.1 USB Driver and Receiver Characteristics Table 82: USB Low Speed Driver and Receiver Characteristics Low Speed Description Baud Rate Baud rate tolerance Ouput single ended high Ouput single ended low Output signal crossover voltage Data fall time Data rise time Rise and fall time matching Source jitter total: to next transition Source jitter total: for paired transitions Input single ended high Input single ended low Differential input sensitivity Sym bol BR Bppm Driver Parameters VOH VOL VCRS TLR TLF TLRFM TUDJ1 TUDJ2 Receiver Parameters VIH VIL VDI Min Max 1.5 -15000.0 15000.0 Units Mbps ppm Notes - 2.8 0.0 1.3 75.0 75.0 80.0 -95.0 -150.0 3.6 0.3 2.0 300.0 300.0 125.0 95.0 150.0 V V V ns ns % ns ns 1 2 3 3, 4 3, 4 5 5 2.0 0.2 0.8 - V V V - Notes: General Comment: For more information, refer to Universal Serial Bus Specification, Revision 2.0, April 2000. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. Defined w ith 1.425 kilohm pull-up resistor to 3.6V. 2. Defined w ith 14.25 kilohm pull-dow n resistor to ground. 3. See "Data Signal Rise and Fall Time" w aveform. 4. Defined from 10% to 90% for rise time and 90% to 10% for fall time. 5. Including frequency tolerance. Timing difference betw een the differential data signals. Defined at crossover point of differential data signals. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 155 MV78230 Hardware Specifications Table 83: USB Full Speed Driver and Receiver Characteristics Full Speed Description Sym bol BR Bppm Driver Parameters Ouput single ended high VOH Ouput single ended low VOL Output signal crossover voltage VCRS Output rise time TFR Output fall time TFL Source jitter total: to next transition TDJ1 Source jitter total: for paired transitions TDJ2 Source jitter for differential transition to SE0 transition TFDEOP Receiver Parameters Input single ended high VIH Input single ended low VIL Differential input sensitivity VDI Receiver jitter : to next transition tJR1 Receiver jitter: for paired transitions tJR2 Baud Rate Baud rate tolerance Min Max 12.0 -2500.0 2500.0 Units Mbps ppm Notes - 2.8 0.0 1.3 4.0 4.0 -3.5 -4.0 -2.0 3.6 0.3 2.0 20.0 20.0 3.5 4.0 5.0 V V V ns ns ns ns ns 1 2 4 3, 4 3, 4 5, 6 5, 6 6 2.0 0.2 -18.5 -9.0 0.8 18.5 9.0 V V V ns ns 6 6 Notes: General Comment: For more information, refer to Universal Serial Bus Specification, Revision 2.0, April 2000. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. Defined w ith 1.425 kilohm pull-up resistor to 3.6V. 2. Defined w ith 14.25 kilohm pull-dow n resistor to ground. 3. Defined from 10% to 90% for rise time and 90% to 10% for fall time. 4. See "Data Signal Rise and Fall Time" w aveform. 5. Including frequency tolerance. Timing difference betw een the differential data signals. 6. Defined at crossover point of differential data signals. Doc. No. MV-S106687-00 Rev. H Page 156 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics Table 84: USB High Speed Driver and Receiver Characteristics High Speed Description Baud Rate Baud rate tolerance Data signaling high Data signaling low Data rise time Data fall time Data source jitter Sym bol BR Bppm Driver Parameters VHSOH VHSOL THSR THSF Min Max 480.0 -500.0 500.0 Units Mbps ppm Notes - 360.0 440.0 -10.0 10.0 500.0 500.0 See note 2 mV mV ps ps 1 1 2 Receiver Parameters Differential input signaling levels Data signaling common mode voltage range Receiver jitter tolerance VHSCM See note 3 -50.0 500.0 See note 3 mV 3 3 Notes: General Comment: For more information, refer to Universal Serial Bus Specification, Revision 2.0, April 2000. General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: To comply w ith the values presented in this table, refer to your local Marvell representative for register settings. 1. Defined from 10% to 90% for rise time and 90% to 10% for fall time. 2. Source jitter specified by the "TX eye diagram pattern template" figure. 3. Receiver jitter specified by the "RX eye diagram pattern template" figure. 9.8.4.2 USB Interface Driver Waveforms Figure 56: Low/Full Speed Data Signal Rise and Fall Time Rise Time Fall Time 90% VCRS 90% 10% Differential Data Lines 10% TR Copyright © 2014 Marvell July 29, 2014, Preliminary TF Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 157 MV78230 Hardware Specifications Figure 57: High Speed TX Eye Diagram Pattern Template +525mV +475mV +400mV Differential +300mV 0 Volts Differential -300mV - 400mV Differential -475mV -525mV 7.5% 37.5% 92.5% 62.5% 0% 100% Figure 58: High Speed RX Eye Diagram Pattern Template +525mV +475mV +400mV Differential +175mV 0 Volts Differential -175mV - 400mV Differential -475mV -525mV 12.5% 0% 35 65 Doc. No. MV-S106687-00 Rev. H Page 158 87.5% 100% Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.5 Serial Gigabit Media Independent Interface (SGMII) Interface Electrical Characteristics 9.8.5.1 SGMII Driver and Receiver Characteristics Table 85: SGMII Interface Driver and Receiver Characteristics (1000BASE-X) Description Sym bol Baud rate Min BR Baud rate tolerance Bppm Unit interval Max Units Notes Gbps - ppm 1 ps - 1.25 -100 UI 100 800 Driver parameters for 1000BASE-X Backplane M ode Output differential minimum eye opening Vodppe 850 - mV - Output differential maximum peak-to-peak Vodpp - 1350 mV - Vos -0.4 1.6 V - Absolute output limits Output differential skew Tosk - 20 ps 2 Return loss differential output RLOD 10 - dB 3, 9 Jttx - 0.1 UI 4 Jttxpp - 0.24 UI 6 Output jitter - deterministic, peak-to-peak Output jitter - total, peak-to-peak Receiver parameters for 1000BASE-X Backplane M ode Input differential sensitivity Vidppe 180 - mV 8 Input differential voltage Vidpp - 2000 mV 8 Input differential skew Tisk - 180 ps 5 Return loss differential input RLID 10 - dB 3, 9 Return loss common mode input RLIC 6 - dB 7, 9 Input jitter - deterministic, peak-to-peak Jtrx - 0.462 UI 4 Jtrxpp - 0.749 UI 6 Input jitter - total, peak-to-peak Notes: General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. 1. Defines the allow able reference clock difference from nominal. 2. This is a single ended parameter and is defined at the 50% point on the signal sw ing. 3. Defined from 50 MHz to 625 MHz. For 650 MHz - 1.25 GHz: -10dB+10log(Freq/625) (Freq defined in MHz). 4. Jitter specifications include all but 10^-12 of the jitter population. 5. This value assumes total eye jitter budget is still maintained. 6. Total jitter is composed of both deterministic and random components. The allow ed random jitter equals the allow ed total jitter minus the actual deterministic at that point. 7. Defined from 50 MHz to 625 MHz. For 650 MHz - 1.25 GHz: -6dB+10log(Freq/625) (Freq defined in MHz). 8. Vidppe refers to the internal eye opening w hile Vidpp refers to the peak-to-peak. 9. Return loss includes contributions from on-chip circuitry, chip packaging, and off-chip optimized components related to the driver/receiver breakout. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 159 MV78230 Hardware Specifications 9.8.5.2 SGMII Interface Driver Waveforms Figure 59: Tri-Speed Interface Driver Output Voltage Limits And Definitions V [Single Ended] Max Absolute Output Output Common Min Absolute Output Ground V [Differential] Differential Peak-to-Peak Time Figure 60: Driver Output Differential Amplitude and Eye Opening Page 160 Differential Amplitude Differential Eye Opening Doc. No. MV-S106687-00 Rev. H Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.6 Double Rated-SGMII (DR-SGMII) Electrical Characteristics 9.8.6.1 DR-SGMII Short Reach (SR) Driver and Receiver Characteristics Table 86: DR-SGMII Short Reach (SR) Driver and Receiver Characteristics Description Baud Rate Baud rate tolerance Unit Interval Sym bol Min BR Bppm Max 3.125 -100 100 320 UI Units Notes Gbps - ppm 1 ps - Driver parameters Output differential minimum eye opening Vodppe 800 - mV - Output differential maximum peak-to-peak Vodpp - 1600 mV - Vos -0.4 2.3 V - Absolute output limits Output differential skew Tosk - 15 ps 2 Output differential transition time Tr/Tf - 130 ps 3 Return loss differential output RLOD 10 - dB 4 Jttx - 0.17 UI - Jttxpp - 0.35 UI 5, 8 Output jitter - Deterministic, peak-to-peak Output jitter - Total, peak-to-peak Receiver parameters Input differential sensitivity Vidpps 200 - mV 9 Input differential voltage Vidpp - 1600 mV 9 Input differential skew Tisk - 75 ps 6 Return loss differential input RLID 10 - dB 7 Return loss common mode input RLIC 6 - dB 7 Input jitter - Deterministic, peak-to-peak Jtrx - 0.47 UI 10 Input jitter - Sinusoidal, low frequency Jtrlsx - 8.5 UI 11 Input jitter - Sinusoidal, high frequency Jtrsx - 0.1 UI 12 Input jitter - Total, peak-to-peak Jtrxpp - 0.65 UI 5, 8 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 161 MV78230 Hardware Specifications Notes: General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. 1. Defines the allow able reference clock difference from nominal. 2. This is a single ended parameter and is defined at the 50% point on the signal sw ing. 3. Defined from 20% to 80% of the signal's voltage levels. 4. Defined from 312.5 MHz to 625 MHz. 5. Defined w ith a BER of 10^-12. 6. This value assumes total eye jitter budget is still maintained. 7. Relative to 100 ohm differential and 25 ohm common mode. Defined from 100 MHz to 2.5 GHz. Return loss includes contributions from on-chip circuitry, chip packaging, and off-chip optimized components related to the driver/receiver breakout. 8. Total jitter is composed of both deterministic and random components. The allow ed random jitter equals the allow ed total jitter minus the actual deterministic at that point. 9. Vidpps refers to the internal eye opening w hile Vidpp refers to the peak-to-peak. 10. Deterministic jitter includes sinusoidal, high frequency (Jtrsx), component. 11. Defined below 22.1 kHz. 12. Defined from 1.875 MHz to 20 MHz. DR-SGMII Driver Output Waveforms 9.8.6.2 Figure 61: DR-SGMII Driver Output Voltage Limits and Definitions V [Single Ended] Max Absolute Output Output Common Min Absolute Output Ground Doc. No. MV-S106687-00 Rev. H Page 162 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics V [Differential] Differential Peak-to-Peak Figure 62: DR-SGMII Driver Output Differential Voltage under Pre-emphasis Vodp Vodd Vodd Vodp Bit Time Bit Time Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 163 MV78230 Hardware Specifications Figure 63: DR-SGMII Driver Output Differential Amplitude and Eye Opening Page 164 Differential Amplitude Differential Eye Opening Doc. No. MV-S106687-00 Rev. H Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.7 Quad Serial Gigabit Media Independent Interface (QSGMII) Electrical Characteristics 9.8.7.1 QSGMII Driver and Receiver Characteristics Table 87: QSGMII Driver and Receiver Characteristics Description Sym bol Baud rate Min Max BR Baud rate tolerance Bppm Unit Interval 5.0 -100.0 UI 100.0 200.0 Units Notes Gbps - ppm 1 ps - Driver parameters Output differential minimum eye opening Vodppe 400.0 - mV - Output differential maximum peak-to-peak Output emphasis Vodpp - 900.0 mV - Emph 3.0 4.0 dB - Output differential resistance Rdo 80.0 120.0 Ohm - Absolute output limits Vos -0.1 1.9 V - Output differential transition time Tr/Tf 30.0 - ps 2 Return loss differential output RLOD 8.0 - dB 3, 4 Return loss common mode output RLOC 6.0 - dB 3, 4 Jttx - 0.15 UI 17 Output duty cycle distortion Jdcdtx - 0.05 UI - Output jitter - Total, peak-to-peak Jttxpp - 0.30 UI 5, 6, 13 Output jitter - Deterministic, peak-to-peak Interconnect parameters (Informative only) Interconnect differential insertion loss: 50 MHz ILOD - 1.0 dB 7, 8 Interconnect differential insertion loss: 500 MHz ILOD - 2.0 dB 7, 8 Interconnect differential insertion loss: 2500 MHz ILOD - 6.6 dB 7, 8 Interconnect differential insertion loss: 5000 MHz ILOD - 12.3 dB 7, 8 100.0 - mV 9 Receiver parameters Input differential sensitivity Vidpps Input differential voltage Vidpp - 900.0 mV 9 Input differential resistance Rdi 80.0 120.0 Ohm - Return loss differential input RLID 8.0 - dB 3, 4 Return loss common mode input RLIC 6.0 - dB 3, 4 Input sinusoidal jitter, low frequency Js - 5.0 UI 14 Input sinusodial jitter, high frequency Jshf - 0.05 UI 15 Input jitter - Deterministic, peak-to-peak Jtrx - 0.45 UI 12 Jtrxuc - 0.15 UI 10 Input correlated bounded high probability jitter Jtrxisi - 0.30 UI 11 Input jitter - Total, peak-to-peak Jtrxpp - 0.60 UI 5, 16 Input uncorrelated bounded high probability jitter Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 165 MV78230 Hardware Specifications General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. General Comment: DC blocker is mandatory since the TX and RX common mode voltage differs. 1. Defines the allow able reference clock difference from nominal. 2. Defined from 20% to 80% of the signal's voltage levels. 3. Defined from 100 MHz to 2.5 GHz. For 2.5 GHz -5.0 GHz RLOD> 8dB-16.6log(Freq/2.5) (Freq defined in GHz). 4. Relative to 100 ohm differential and 25 ohm common mode. Return loss includes contributions from on-chip circuitry, chip packaging, and off-chip optimized components related to the driver/receiver breakout. 5. Defined w ith a Bit Error Rate (BER) of 10^-15. 6. Total jitter is composed of both deterministic and random components. The allow ed random jitter equals the allow ed total jitter minus the actual deterministic jitter and duty cycle distortion at that point. 7. The interconnect insertion loss specification is defined from the TX pins (w ith zero pre-emphasis) to the RX pins. The interconnect value betw een the frequencies should be extrapolated using linear extrapolation on a logarithmic loss scale. 8. The interconnect definition w as determined to allow a maximum insertion loss value at a frequency equal to half the bit rate. The insertion loss value must vary w ithout notch-like behavior up to a maximum frequency as defined by the interconnect definition. 9. Vidpps refers to the internal eye opening w hile Vidpp refers to the peak-to-peak. 10. Jitter distribution w here the value of the jitter show s no correlation to any signal level being transmitted. 11. Jitter distribution w here the value of the jitter show s a strong correlation to the signal level being transmitted. This jitter may be considered as being equalizable due to its correlation to the signal level (ISI). 12. This is the sum of Jtrxuc and Jtrxisi. 13. The clock for output TX jitter is generated using a golden PLL. The PLL loop bandw idth is BR/1667 w ith a 20 dB/dec rolloff. 14. Defined up to f = 30 kHz. 15. Defined betw een f = BR/1667 to f = 20 MHz. 16. Does not include sinusoidal jitter. 17. Driver jitter does not include correlated bounded jitter created by the driver emphasis. Doc. No. MV-S106687-00 Rev. H Page 166 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.7.2 QSGMII Interface Driver Waveforms Figure 64: QSGMII Driver Output Voltage Limits and Definitions V [Single Ended] Max Absolute Output Output Common Min Absolute Output Ground V [Differential] Differential Peak-to-Peak Figure 65: Interconnect Insertion Loss Insertion Loss [dB] 50 500 2500 -1.0 -2.0 5000 Frequency [MHz] -6.6 -12.3 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 167 MV78230 Hardware Specifications Figure 66: Driver Output Differential Amplitude and Eye Opening Page 168 Differential Amplitude Differential Eye Opening Doc. No. MV-S106687-00 Rev. H Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Electrical Specifications Differential Interface Electrical Characteristics 9.8.8 Serial Embedded Trace Macrocell (sETM) Interface Electrical Characteristics 9.8.8.1 sETM Interface Driver and Receiver Characteristics Table 88: sETM Interface Driver and Receiver Characteristics Description Sym bol Min Max Units Notes BR - 6 Gbps - Bppm -100 100 ppm 1 UI 166.667 - ps - 400 - mV - Baud Rate Baud rate tolerance Unit Interval Driver parameters Output differential minimum eye opening Vodppe Output differential maximum peak-to-peak Vodpp - 1200 mV - Absolute output limits Vos -0.4 1.9 V - Output common mode voltage Vcm 1.45 1.55 V - Output de-emphasis voltage range Emph 0.0 50 % 5 Output de-emphasis voltage accuracy Empha - 10 % - Output differential resistance Rdo 85 115 Ohm - Output differential skew Tosk - 15 ps 2 Output differential transition time Tr/Tf 46 64 ps 3 Output lane to lane skew Tlskew - 5 UI - Output jitter - Total, peak-to-peak Jttxpp - 0.26 UI 4 Notes: General Comment: The load is 100 ohm differential for these parameters, unless otherw ise specified. 1. Defines the allow able reference clock difference from nominal. 2. This is a single ended parameter and is defined at the 50% point on the signal sw ing. 3. Defined from 20% to 80% of the signal's voltage levels. 4. Defined w ith a BER of 10^-12 and PRBS7 pattern. 5. Precent reduced from the TX differential peak-to-peak voltage. Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 169 MV78230 Hardware Specifications 9.8.8.2 sETM Interface Driver Output Waveforms Figure 67: Driver Output Voltage Limits and Definitions V [Single Ended] Max Absolute Output Output Common Min Absolute Output Ground V [Differential] Differential Peak-to-Peak Figure 68: Driver Output Differential Amplitude and Eye Opening Page 170 Differential Amplitude Differential Eye Opening Doc. No. MV-S106687-00 Rev. H Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Thermal Data 10 Thermal Data Table 89provides the package thermal data for the MV78230. This data is derived from simulations that were run according to the JEDEC standard. The documents listed below provide a basic understanding of thermal management of integrated circuits (ICs) and guidelines to ensure optimal operating conditions for Marvell products. Before designing a system, it is recommended to refer to these documents: Application Note, AN-63 Thermal Management for Selected Marvell® Products, Document Number MV-S300281-00 White Paper, ThetaJC, ThetaJA, and Temperature Calculations, Document Number MV-S700019-00 Table 89: Thermal Data for the MV78230 in FCBGA Package Sy m b o l D e fin i ti on A ir fl ow Va l ue (° C / W ) 0 [ m /s ] 1 [ m / s] 2[m/s] JA Thermal resistance: junction to ambient 14.66 12.54 11.66 JT Thermal characterization parameter: junction to top center 0.77 0.67 0.67 JB Thermal characterization parameter: junction to board 6.77 6.13 5.92 JC Thermal resistance: junction to case (not air-flow dependent) 0.5 JB Thermal resistance: junction to board (not air-flow dependent) 6.7 Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 171 MV78230 Hardware Specifications 11 Package Mechanical Dimensions The ARMADA® XP Highly Integrated Multi-Core ARMv7 Based System-on-Chip Processors use a 732-pin 23 mm x 23 mm FCBGA package with a 0.65 mm pitch. Figure 69: 732-Pin FCBGA Package and Dimensions Doc. No. MV-S106687-00 Rev. H Page 172 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Part Order Numbering/Package Marking Part Order Numbering 12 Part Order Numbering/Package Marking 12.1 Part Order Numbering Figure 70 shows the part order numbering scheme for the MV78230. Refer to Marvell Field Application Engineers (FAEs) or representatives for further information when ordering parts. Figure 70: Sample Part Number MV78230 –xx–BJR2C000–xxxx Custom code (optional) Frequency 080 = 800 MHz 106 = 1066 MHz 120 = 1200 MHz 133 = 1333 MHz 160 = 1600 MHz Part number MV78230 Temperature code C = Commercial Die revision Environmental code 2 = Green (RoHS 6/6 and Halogen-free) Custom code Package code BJR = 732-pin FCBGA R. Table 90: MV78230 Part Order Options P a c k a g e Ty p e P a r t O r de r N um b e r 732-pin FCBGA MV78230-xx-BJR2C080 (Green, RoHS 6/6 and Halogen-free package, 800 MHz) 732-pin FCBGA MV78230-xx-BJR2C106 (Green, RoHS 6/6 and Halogen-free package, 1066 MHz) 732-pin FCBGA MV78230-xx-BJR2C120 (Green, RoHS 6/6 and Halogen-free package, 1200 MHz) 732-pin FCBGA MV78230-xx-BJR2C133 (Green, RoHS 6/6 and Halogen-free package, 1333 MHz) 732-pin FCBGA MV78230-xx-BJR2C160 (Green, RoHS 6/6 and Halogen-free package, 1600 MHz) Copyright © 2014 Marvell July 29, 2014, Preliminary Doc. No. MV-S106687-00 Rev. H Document Classification: Proprietary Information Page 173 MV78230 Hardware Specifications 12.2 Package Marking This section provides the package markings for the MV78230 FCBGA package. Figure 71 shows a sample flip chip die marking and pin 1 location for the FCBGA package. Figure 71: Package Marking and Pin 1 Location (Top View) Country of origin (Contained in the mold ID or marked as the last line on the package.) Part number and revision Pin 1 location Marvell logo MV78-XXXe Lot Number YYWW xx@ Country of Origin MV78230-xx CZZZ Temperature code C = Commercial, ZZZ = Custom) Part number prefix, Package code, environmental code MV78 = Part number prefix XXX = Package code e = Environmental code Date code, custom code, assembly plant code YYWW = Date code (YY = year, WW = Work Week) xx = Custom code/Die revision @ = Assembly plant code Doc. No. MV-S106687-00 Rev. H Page 174 Copyright © 2014 Marvell Document Classification: Proprietary Information July 29, 2014, Preliminary Contact Information Marvell Semiconductor, Inc. 5488 Marvell Lane Santa Clara, CA 95054, USA Tel: 1.408.222.2500 Fax: 1.408.988.8279 www.marvell.com Marvell. Moving Forward Faster