York Sun | 667ab1a | 2012-10-11 07:13:37 +0000 | [diff] [blame] | 1 | Overview |
| 2 | -------- |
| 3 | The T4240QDS is a high-performance computing evaluation, development and test |
| 4 | platform supporting the T4240 QorIQ™ Power Architecture™ processor. T4240QDS is |
| 5 | optimized to support the high-bandwidth DDR3 memory ports, as well as the |
| 6 | highly-configurable SerDes ports. The system is lead-free and RoHS-compliant. |
| 7 | |
| 8 | Board Features |
| 9 | SERDES Connections |
| 10 | 32 lanes grouped into four 8-lane banks |
| 11 | Two “front side” banks dedicated to Ethernet |
| 12 | - High-speed crosspoint switch fabric on selected lanes |
| 13 | - Two PCI Express slots with side-band connector supporting |
| 14 | - SGMII |
| 15 | - XAUI |
| 16 | - HiGig |
| 17 | - I-pass connectors allow board-to-board and loopback support |
| 18 | Two “back side” banks dedicated to other protocols |
| 19 | - High-speed crosspoint switch fabric on all lanes |
| 20 | - Four PCI Express slots with side-band connector supporting |
| 21 | - PCI Express 3.0 |
| 22 | - SATA 2.0 |
| 23 | - SRIO 2.0 |
| 24 | - Supports 4X Aurora debug with two connectors |
| 25 | DDR Controllers |
| 26 | Three independant 64-bit DDR3 controllers |
| 27 | Supports rates of 1866 up to 2133 MHz data-rate |
| 28 | Supports two DDR3/DDR3LP UDIMM/RDIMMs per controller |
| 29 | DDR power supplies 1.5V to all devices with automatic tracking of VTT. |
| 30 | Power software-switchable to 1.35V if software detects all DDR3LP devices. |
| 31 | MT9JSF25672AZ-2G1KZESZF has been tested at 1333, 1600, 1867, 2000 and |
| 32 | 2133MT/s speeds. For 1867MT/s and above, read-to-write turnaround time |
| 33 | increases by 1 clock. |
| 34 | |
| 35 | IFC/Local Bus |
| 36 | NAND flash: 8-bit, async or sync, up to 2GB. |
| 37 | NOR: 16-bit, Address/Data Multiplexed (ADM), up to 128 MB |
| 38 | NOR: 8-bit or 16-bit, non-multiplexed, up to 512MB |
| 39 | - NOR devices support 16 virtual banks |
| 40 | GASIC: Minimal target within Qixis FPGA |
| 41 | PromJET rapid memory download support |
| 42 | Address demultiplexing handled within FPGA. |
| 43 | - Flexible demux allows 8 or 16 bit evaluation. |
| 44 | IFC Debug/Development card |
| 45 | - Support for 32-bit devices |
| 46 | Ethernet |
| 47 | Support two on-board RGMII 10/100/1G ethernet ports. |
| 48 | SGMII and XAUI support via SERDES block (see above). |
| 49 | 1588 support via Symmetricom board. |
| 50 | QIXIS System Logic FPGA |
| 51 | Manages system power and reset sequencing |
| 52 | Manages DUT, board, clock, etc. configuration for dynamic shmoo |
| 53 | Collects V-I-T data in background for code/power profiling. |
| 54 | Supports legacy TMT test features (POSt, IRS, SYSCLK-synchronous assertion) |
| 55 | General fault monitoring and logging |
| 56 | Runs from ATX “hot” power rails allowing operation while system is off. |
| 57 | Clocks |
| 58 | System and DDR clock (SYSCLK, “DDRCLK”) |
| 59 | - Switch selectable to one of 16 common settings in the interval 33MHz-166MHz. |
| 60 | - Software selectable in 1MHz increments from 1-200MHz. |
| 61 | SERDES clocks |
| 62 | - Provides clocks to all SerDes blocks and slots |
| 63 | - 100, 125 and 156.25 MHz |
| 64 | Power Supplies |
| 65 | Dedicated regulators for VDD |
| 66 | - Adjustable from (0.7V to 1.3V at 80A |
| 67 | - Regulators can be controlled by VID and/or software |
| 68 | Dedicated regulator for GVDD_PL: 1.35/1.5V at 22A |
| 69 | - VTT/MVREF automatically track operating voltage |
| 70 | Dedicated regulators/filters for AVDD supplies |
| 71 | Dedicated regulators for other supplies: OVDD, BVDD, DVDD, LVDD, POVDD, etc. |
| 72 | USB |
| 73 | Supports two USB 2.0 ports with integrated PHYs |
| 74 | - One type A, one type micro-AB with 1.0A power per port. |
| 75 | Other IO |
| 76 | eSDHC/MMC |
| 77 | - SDHC card slot |
| 78 | eSPI port |
| 79 | - High-speed serial flash |
| 80 | Two Serial port |
| 81 | Four I2C ports |
| 82 | |
| 83 | Memory map |
| 84 | ---------- |
| 85 | The addresses in brackets are physical addresses. |
| 86 | |
| 87 | 0x0_0000_0000 (0x0_0000_0000) - 0x0_7fff_ffff 2GB DDR (more than 2GB is initialized but not mapped under with TLB) |
| 88 | 0x0_8000_0000 (0xc_0000_0000) - 0x0_dfff_ffff 1.5GB PCIE memory |
Stephen George | 45bc119 | 2013-03-25 07:40:12 +0000 | [diff] [blame] | 89 | 0x0_f000_0000 (0xf_0000_0000) - 0x0_f1ff_ffff 32MB DCSR (includes trace buffers) |
York Sun | 667ab1a | 2012-10-11 07:13:37 +0000 | [diff] [blame] | 90 | 0x0_f400_0000 (0xf_f400_0000) - 0x0_f5ff_ffff 32MB BMan |
| 91 | 0x0_f600_0000 (0xf_f600_0000) - 0x0_f7ff_ffff 32MB QMan |
| 92 | 0x0_f800_0000 (0xf_f800_0000) - 0x0_f803_ffff 256KB PCIE IO |
| 93 | 0x0_e000_0000 (0xf_e000_0000) - 0x0_efff_ffff 256MB NOR flash |
| 94 | 0x0_fe00_0000 (0xf_fe00_0000) - 0x0_feff_ffff 16MB CCSR |
| 95 | 0x0_ffdf_0000 (0xf_ffdf_0000) - 0x0_ffdf_03ff 4KB QIXIS |
| 96 | 0x0_ffff_f000 (0x0_7fff_fff0) - 0x0_ffff_ffff 4KB Boot page translation for secondary cores |
| 97 | |
| 98 | The physical address of the last (boot page translation) varies with the actual DDR size. |
York Sun | 844944c | 2013-03-25 07:40:01 +0000 | [diff] [blame] | 99 | |
| 100 | Voltage ID and VDD override |
| 101 | -------------------- |
| 102 | T4240 has a VID feature. U-boot reads the VID efuses and adjust the voltage |
| 103 | accordingly. The voltage can also be override by command vdd_override. The |
| 104 | syntax is |
| 105 | |
| 106 | vdd_override <voltage in mV>, eg. 1050 is for 1.050v. |
| 107 | |
| 108 | Upon success, the actual voltage will be read back. The value is checked |
| 109 | for safety and any invalid value will not adjust the voltage. |
| 110 | |
| 111 | Another way to override VDD is to use environmental variable, in case of using |
| 112 | command is too late for some debugging. The syntax is |
| 113 | |
| 114 | setenv t4240qds_vdd_mv <voltage in mV> |
| 115 | saveenv |
| 116 | reset |
| 117 | |
| 118 | The override voltage takes effect when booting. |
| 119 | |
| 120 | Note: voltage adjustment needs to be done step by step. Changing voltage too |
| 121 | rapidly may cause current surge. The voltage stepping is done by software. |
| 122 | Users can set the final voltage directly. |