Emerson ATCA-F140 Installation And Use Manual
  1. Manuals
  2. Brands
  3. Emerson Manuals
  4. Network Hardware
  5. ATCA-F140
  6. Installation and use manual

Emerson ATCA-F140 Installation And Use Manual

Hide thumbs
Table of Contents

Quick Links

ATCA-F140
Installation and Use
P/N: 6806800M67H
November 2013
Embedded Computing for
Business-Critical Continuity
TM
Table of Contents
loading

Related Manuals for Emerson ATCA-F140

Summary of Contents for Emerson ATCA-F140

  • Page 1 Embedded Computing for Business-Critical Continuity ATCA-F140 Installation and Use P/N: 6806800M67H November 2013...
  • Page 2 Emerson reserves the right to revise this document and to make changes from time to time in the content hereof without obligation of Emerson to notify any person of such revision or changes.
  • Page 3 Faceplate ................50 ATCA-F140 Installation and Use (6806800M67H)
  • Page 4 4.7.2 ShMC Cross-Connect ............81 ATCA-F140 Installation and Use (6806800M67H)
  • Page 5 Using the Persistent Memory Feature ..........105 ATCA-F140 Installation and Use (6806800M67H)
  • Page 6 5.10 ATCA-F140-Specific U-Boot Environment Variables ........

  • Page 7: Table Of Contents

    Tested SFP+ Modules ............85 ATCA-F140 Installation and Use (6806800M67H)
  • Page 8 ATCA-F140 Specific U-Boot Commands ........
  • Page 9 ATCA-F140 Block Diagram ........
  • Page 10 List of Figures ATCA-F140 Installation and Use (6806800M67H)
  • Page 11 German translation of the Safety Notes chapter.  Abbreviations This document uses the following abbreviations: Abbreviation Description ATCA Advanced Telecom Computing Architecture Advanced Mezzanine Card BITS Building Integrated Timing Supply Base Interface Switch Backplane Block Transfer Core Complex Bus ATCA-F140 Installation and Use (6806800M67H)
  • Page 12 LVPECL Low-Voltage Positive Emitter Coupled Logic Machine Check Processor M-LVDS Multipoint Low-Voltage Differential Signals Module Management Controller Multi Mode Fiber Port Bypass Circuit Peripheral Component Interconnect Bus PCIE PCI Express PCI-SIG PCI Special Interest Group ATCA-F140 Installation and Use (6806800M67H)
  • Page 13 Static Random Access Memory Solid State Disk Synchronization Supply Unit TSEC Triple Speed Ethernet Controller UART Universal Asynchronous Receiver / Transmitter Unconditional Debug Event Universal Serial Bus Very Low Profile XAUI 10 Gigabit Attachment Unit Interface ATCA-F140 Installation and Use (6806800M67H)
  • Page 14 Repeated item for example node 1, node 2, ..., node Omission of information from example/command that is not necessary at the time being Ranges, for example: 0..4 means one of the integers 0,1,2,3, and 4 (used in registers) Logical OR ATCA-F140 Installation and Use (6806800M67H)
  • Page 15 6806800M67E May 2013 Updated Table 3-1 on page 6806800M67F October 2013 Updated Table 2-2 on page 6806800M67G November 2013 Updated the section Accessing U-Boot on page 101. 6806800M67H November 2013 Updated Table 2-1 on page ATCA-F140 Installation and Use (6806800M67H)
  • Page 16 About this Manual About this Manual ATCA-F140 Installation and Use (6806800M67H)
  • Page 17 Introduction Features The ATCA-F140 is a hub board as defined in PICMG 3.0 Revision 3.0 Advanced TCA Base Specification and PICMG 3.1 Revision 1.0 Specification Ethernet/Fiber Channel for AdvancedTCA Systems. It supports several Base and Fabric Channel Ethernet interfaces to the Zone 2 backplane.

  • Page 18: Table 1-1 Standard Compliances

    ETSI public transportation requirement on system level Class 2.3 Telcordia GR-1089-CORE Electromagnetic Compatibility and Electrical Safety - Generic Criteria for Network Telecommunications Equip- ment Telcordia GR-63-CORE NEBS Requirements: Physical Protection Telcordia SR-3580 NEBSCriteria Level 3 ATCA-F140 Installation and Use (6806800M67H)

  • Page 19: Mechanical Data

    The following table provides details about the blade's mechanical data, such as dimensions and weight. Table 1-2 Mechanical Data Data Value Dimensions 30 mm x 351 mm x 312 mm (8U form factor) Weight 2.8 kg ATCA-F140 Installation and Use (6806800M67H)

  • Page 20: Table 1-3 Blade Variants - Ordering Information

    Ordering Information The following table lists the blade variants that were available as of the time of writing this manual. Consult your local Emerson sales representative for the availability of further variants. Table 1-3 Blade Variants - Ordering Information Product Name...
  • Page 21 Introduction Table 1-4 Blade Accessories - Ordering Information Accessory Description HDD-500G-SATA Direct mount 500GB HDD for ATCA-F125 & ATCA-F140, high durability - SATA PRAMC-7311 AMC with INTEL COREI7 Processor, 4GB DDR3 - mid size SW-WR-PRAMC-7311 CD with WR PNE 3.0 and BBS for the PRAMC-7311, single blade license...

  • Page 22: Figure 1-1 Serial Number Location

    Introduction Product Identification The following graphic shows the location of the serial number label. Figure 1-1 Serial Number Location ATCA-F140 Installation and Use (6806800M67H)
  • Page 23 Chapter 2 Hardware Preparation and Installation Overview This chapter provides the information that you need to install the ATCA-F140 and its accessories into your AdvancedTCA system. Removal procedures are also included. To install the blade, follow these steps: 1. Unpack and inspect the blade.
  • Page 24 Improper disposal of used products may harm the environment.  Always dispose of used products according to your country’s legislation and manufac-  turer’s instructions. Requirements This section shows the environmental and power requirements of the ATCA-F140. ATCA-F140 Installation and Use (6806800M67H)
  • Page 25 Operating temperatures refer to the temperature of the air circulating around the blade, and not to component temperatures. If you integrate the blade in your own non-Emerson system, please contact your local sales representative for further safety information. Blade Damage High humidity and condensation on the blade surface may cause it to short circuit.

  • Page 26: Table 2-1 Environmental Requirements

    Random 20-200Hz at 3 m Shock Half-sine, 11 ms at 30 m/s Blade level packaging Half-sine, 6 ms at 180 m/s Free Fall 1.2 m/ packaged (according to ETSI 300 019-2-2) 100 mm unpackaged (according to Telcordia GR-63-core) ATCA-F140 Installation and Use (6806800M67H)
  • Page 27 Hardware Preparation and Installation 2.3.2 Thermal Requirements In order for the ATCA-F140 to cool properly when the operating temperature is at the maximum (55 C), the chassis must meet or exceed CP-TA B.3 ATCA Chassis Specification. CP- ° TA B.4 compliance is preferred.

  • Page 28: Table 2-2 Power Requirements

    -48VDC to -60VDC, US and -48VDC, Canada Operating Voltage -39VDC to -72VDC, US and -39VDC to -60VDC, Canada Max. power consumption of ATCA-F140 with SATA 200W max, 135W typ drive and RTM-ATCA-F140 no AMC installed Max. power consumption of ATCA-F140 with SATA...
  • Page 29 Hardware Preparation and Installation Rear Transition Modules If applicable, install a rear transition module. For more information, see the RTM-ATCA-F140 Installation and Use. You can obtain an electronic copy of the manual from our web site: 1. Go to www.emersonnetworkpower.com/embeddedcomputing.
  • Page 30 2.5.1 SATA Drive Installation An optional SATA drive can be installed on the ATCA-F140. This is a 2.5 inch form factor drive, designed for extreme temperature and vibration environments and has been tested and approved for use on the ATCA-F140. The hard drive kits available at the time of release are...
  • Page 31 If there is a Rear Transition Module (RTM) to install, install and secure the RTM first as described in the RTM-ATCA-F140 Installation and Use Guide, then install the front blade. If an RTM is already installed, make sure that the RTM faceplate screws are fully tightened to secure the RTM to the shelf.
  • Page 32 Continue to gently push the blade until the blade connectors engage. 5. Squeeze the lever and the latch together and hook the lower and the upper handle into the shelf rail recesses. ATCA-F140 Installation and Use (6806800M67H)
  • Page 33 If an RTM is connected to the front blade, make sure that the handles of both the RTM and the front blade are closed in order to power up the blade’s payload. ATCA-F140 Installation and Use (6806800M67H)
  • Page 34 ESD-safe environment. Damage of the blade Incorrect installation of the blade can cause damage of the blade.  Only use handles when installing/removing the blade to avoid damage/deformation to  the face plate and/or PCB. ATCA-F140 Installation and Use (6806800M67H)
  • Page 35 If the LED continues to blink, it is possible that the upper layer software has rejected the blade extraction request. 3. Remove the face plate cables, if applicable. 4. Remove the blade from the shelf. ATCA-F140 Installation and Use (6806800M67H)
  • Page 36 AMC Module Damage The AMC bay should only be used with AMC modules that are officially supported by  Emerson. Installing and operating other AMC modules may damage the AMC bay and the blade. Limitation of Operating Temperature Range Installing AMC modules with small operating temperature ranges into the ATCA-F140 ...
  • Page 37 LED. 1. Remove any cables that are connected to the AMC module face plate connectors. 2. Gently pull the module latch outwards, approximately 3 mm away from its locked position. ATCA-F140 Installation and Use (6806800M67H)
  • Page 38 4. Once the blue LED glows steadily, gently pull the AMC module handles outwards to disconnect the module from the AMC connectors. Continue to gently slide the module outwards along the guide rails. Install the filler panel. ATCA-F140 Installation and Use (6806800M67H)
  • Page 39 The presence and also the type of SFP modules is automatically detected. The maximum power consumption of each SFP module should be 1W. The maximum power consumption of each SFP+ module should be 1.5W. ATCA-F140 Installation and Use (6806800M67H)
  • Page 40 1. Slide the SFP module into the slot until it locks into position. The SFP/SFP+ module will only fully insert if installed in the proper orientation. If it does not fully insert, rotate it 180 degrees and re-install. ATCA-F140 Installation and Use (6806800M67H)
  • Page 41 SFP module inoperable. Only remove the optical plug when you are ready to connect a cable to the SFP module.  When no cable is connected, cover the port with an optical port plug. ATCA-F140 Installation and Use (6806800M67H)
  • Page 42 Hardware Preparation and Installation 3. Connect the network cable to the SFP module ATCA-F140 Installation and Use (6806800M67H)
  • Page 43 In order to remove an SFP module, proceed as follows. 1. Remove any connected cable from the SFP module. 2. Open the SFP latch. Note that the latch mechanism of your SFP module may be ATCA-F140 Installation and Use (6806800M67H)
  • Page 44 Hardware Preparation and Installation slightly different compared to the latch shown in the following figure. ATCA-F140 Installation and Use (6806800M67H)
  • Page 45 SFP module inoperable. Only remove the optical plug when you are ready to connect a cable to the SFP module.  When no cable is connected, cover the port with an optical port plug. ATCA-F140 Installation and Use (6806800M67H)
  • Page 46 When installing and using optical QSFP+ modules which are classified as laser products,  make sure to comply to the respective regulations. The maximum power consumption of each QSFP+ module should be 2W. ATCA-F140 Installation and Use (6806800M67H)
  • Page 47 QSFP+ transceiver connects with the socket electrical connector. For QSFP+ transceivers with a bail-clasp latch, keep it aligned in a vertical position.  For QSFP+ transceivers with a pull-tab, make sure that the identifier label is on top.  ATCA-F140 Installation and Use (6806800M67H)
  • Page 48 Install the dust plug into the transceiver’ optical bore.  Hold the tab and pull the receiver gently to release the transceiver from the socket.  Slide the transceiver from the socket.  Place the QSFP+ transceiver into an anti-static bag. ATCA-F140 Installation and Use (6806800M67H)

  • Page 49: Figure 3-1 Atca-F140 Face Plate

    Chapter 3 Controls, LEDs, and Connectors Mechanical Layout The following figure illustrates the mechanical layout of the blade. Figure 3-1 ATCA-F140 Face Plate ATCA-F140 Installation and Use (6806800M67H)
  • Page 50 Controls, LEDs, and Connectors Faceplate This section describes the details of the ATCA-F140 faceplate LEDs. 3.2.1 LEDs The following table describes the functions of the front panel LEDs. Table 3-1 Front Panel LEDs Color Function Out of Service Blade out of service Amber Not used.

  • Page 51: Table

    Table 3-2 Service Processor Ethernet RJ45 Connector Pin Assignment (J9) RJ45 Pin 10Base-T or 100Base-TX 1000Base-T ETH_TX+ ETH_DA+ ETH_TX- ETH_DA- ETH_RX+ ETH_DB+ ETH_DC+ ETH_DC- ETH_RX- ETH_DB- ETH_DD+ ETH_DD- Table 3-3 Service Processor Serial RS232 RJ45 Connector (J1) RJ45 Pin Function (RS232) Not used ATCA-F140 Installation and Use (6806800M67H)

  • Page 52: Table

    Table 3-4 QSFP+ Connector Pin Assignment Contact Contact Number Function Number Function TX2n TX1n TX2p TX1p TX4n TX3n TX4p TX3p ModselL LPMode ResetL Vcc1 VccRx VccTx IntL ModPrsL RX3p RX4p RX3n RX4n RX1p RX2p RX1n RX2n ATCA-F140 Installation and Use (6806800M67H)

  • Page 53: Table 3-5 Sfp+ Connector Pin Assignment

    Table 3-5 SFP+ Connector Pin Assignment Contact Contact Number Function Number Function TX_FAULT TX_DISABLE I2C_SDA I2C_SCL VCCr (+3.3V) MOD_ABS VCCt (+3.3V) Table 3-6 Master/Slave Sync Connector (J12-U1) RJ45 Pin Function Transmit + Transmit - Receive + ATCA-F140 Installation and Use (6806800M67H)

  • Page 54: Table 3-7 Inter-Shelf Connectors (J12-L1, L2, L3, U2, U3)

    Port 3 + Port 3 - Port 2 - Port 4 + Port 4 - Table 3-8 T1/E1 Port Connectors (J12-L4 and J12-U4) RJ45 Pin Function RX Ring RX Tip TX Ring TX Tip Port 2 - ATCA-F140 Installation and Use (6806800M67H)

  • Page 55: Table 3-9 Zone 1 Connector P10 Pin Assignment

    Hardware Address Bit 4 Hardware Address Bit 5 Hardware Address Bit 6 Hardware Address Bit 7 IPMB Clock Port A IPMB Data Port A IPMB Clock Port B IPMB Data Port A 17 - 24 Not used ATCA-F140 Installation and Use (6806800M67H)

  • Page 56: Table 3-10 Connector J20 Pin Assignment

    CLK3A- CLK3B+ CLK3B- UC_P2_TX+ UC_P2_TX- UC_P2_RX+ UC_P2_RX- UC_P3_TX+ UC_P3_TX- UC_P3_RX+ UC_P3_RX- UC_P0_TX+ UC_P0_TX- UC_P0_RX+ UC_P0_RX- UC_P1_TX+ UC_P1_TX- UC_P1_RX+ UC_P1_RX- FIX_P12_TX2+ FIX_P12_TX2- FIX_P12_RX2+ FIX_P12_RX2- FIX_P12_TX3+ FIX_P12_TX3- FIX_P12_RX3+ FIX_P12_RX3- FIX_P12_TX0+ FIX_P12_TX0- FIX_P12_RX0+ FIX_P12_RX0- FIX_P12_TX1+ FIX_P12_TX1- FIX_P12_RX1+ FIX_P12_RX1- ATCA-F140 Installation and Use (6806800M67H)

  • Page 57: Table 3-11 Connector J21 Pin Assignment

    FIX_P4_TX0+ FIX_P4_TX0- FIX_P4_RX0+ FIX_P4_RX0- FIX_P4_TX1+ FIX_P4_TX1- FIX_P4_RX1+ FIX_P4_RX1- FIX_P3_TX2+ FIX_P3_TX2- FIX_P3_RX2+ FIX_P3_RX2- FIX_P3_TX3+ FIX_P3_TX3- FIX_P3_RX3+ FIX_P3_RX3- FIX_P3_TX0+ FIX_P3_TX0- FIX_P3_RX0+ FIX_P3_RX0- FIX_P3_TX1+ FIX_P3_TX1- FIX_P3_RX1+ FIX_P3_RX1- FIX_P2_TX2+ FIX_P2_TX2- FIX_P2_RX2+ FIX_P2_RX2- FIX_P2_TX3+ FIX_P2_TX3- FIX_P2_RX3+ FIX_P2_RX3- FIX_P2_TX0+ FIX_P2_TX0- FIX_P2_RX0+ FIX_P2_RX0- FIX_P2_TX1+ FIX_P2_TX1- FIX_P2_RX1+ FIX_P2_RX1- ATCA-F140 Installation and Use (6806800M67H)

  • Page 58: Table 3-13 Connector J23 Pin Assignment

    BIX_P12_DA+ BIX_P12_DA- BIX_P12_DB+ BIX_P12_DB- BIX_P12_DC+ BIX_P12_DC- BIX_P12_DD+ BIX_P12_DD- BIX_P13_DA+ BIX_P13_DA- BIX_P13_DB+ BIX_P13_DB- BIX_P13_DC+ BIX_P13_DC- BIX_P13_DD+ BIX_P13_DD- BIX_P14_DA+ BIX_P14_DA- BIX_P14_DB+ BIX_P14_DB- BIX_P14_DC+ BIX_P14_DC- BIX_P14_DD+ BIX_P14_DD- BIX_P15_DA+ BIX_P15_DA- BIX_P15_DB+ BIX_P15_DB- BIX_P15_DC+ BIX_P15_DC- BIX_P15_DD+ BIX_P15_DD- BIX_P16_DA+ BIX_P16_DA- BIX_P16_DB+ BIX_P16_DB- BIX_P16_DC+ BIX_P16_DC- BIX_P16_DD+ BIX_P16_DD- ATCA-F140 Installation and Use (6806800M67H)

  • Page 59: Table 3-15 Connector J30 Pin Assignment

    Column C Column D Column E Column F Column G Column H BIX_XG0_TX2+ BIX_XG0_TX2- BIX_XG0_RX2+ BIX_XG0_RX2- BIX_XG0_TX3+ BIX_XG0_TX3- BIX_XG0_RX3+ BIX_XG0_R BIX_XG0_TX0+ BIX_XG0_TX0- BIX_XG0_RX0+ BIX_XG0_RX0- BIX_XG0_TX1+ BIX_XG0_TX1- BIX_XG0_RX1+ BIX_XG0_R BIX_XG1_TX2+ BIX_XG1_TX2- BIX_XG1_RX2+ BIX_XG1_RX2- BIX_XG1_TX3+ BIX_XG1_TX3- BIX_XG1_RX3+ BIX_XG1_R ATCA-F140 Installation and Use (6806800M67H)

  • Page 60: Table 3-17 Connector J32 Pin Assignment

    Column G Column H FIX_P15_TX2+ FIX_P15_TX2- FIX_P15_RX2+ FIX_P15_RX2- FIX_P15_TX3+ FIX_P15_TX3- FIX_P15_RX3 FIX_P15_RX3 FIX_P15_TX0+ FIX_P15_TX0- FIX_P15_RX0+ FIX_P15_RX0- FIX_P15_TX1+ FIX_P15_TX1- FIX_P15_RX1 FIX_P15_RX1 FIX_P14_TX2+ FIX_P14_TX2- FIX_P14_RX2+ FIX_P14_RX2- FIX_P14_TX3+ FIX_P14_TX3- FIX_P14_RX3 FIX_P14_RX3 FIX_P14_TX0+ FIX_P14_TX0- FIX_P14_RX0+ FIX_P14_RX0- FIX_P14_TX1+ FIX_P14_TX1- FIX_P14_RX1 FIX_P14_RX1 ATCA-F140 Installation and Use (6806800M67H)
  • Page 61 Column B Column C Column D Column E Column F Column G Column H RTM_SCL RTM_SDA SPI_CS2_L RTM_RST_L RTM_SW_CLOS RTM_PWRGOOD BIX_P19_RTM BIX_P19_RTM ED_L _TX+ _TX- +12V_RTM +12V_RTM SPI_MISO SPI_MOSI SPI_SCK RTM_PS0_L BIX_P19_RTM BIX_P19_RTM _RX+ _RX- ATCA-F140 Installation and Use (6806800M67H)

  • Page 62: Figure 3-2 Module Connectors Locations

    Controls, LEDs, and Connectors Module Connectors Figure 3-2 Module Connectors Locations ATCA-F140 Installation and Use (6806800M67H)

  • Page 63: Table 3-18 Amc Bay Connector Pin Assignment

    146 GND 82571EB) AMC_TX0+ (to AMC_TX4- BIX_P18) Unus 8257 1EB) AMC_TX0- PCIe_CLK+ Unused 148 Unused BIX_P18) AMC_RX4+ (to PCIe_CLK- Unused 149 GND 82571EB) AMC_RX0+ AMC_RX4- (to 150 Unused BIX_P18) 82571EB) AMC_RX0- PS0# Unused 151 Unused BIX_P18) ATCA-F140 Installation and Use (6806800M67H)
  • Page 64 Unused 166 TMS SATA mux) AMC_TX7+ (to AMC_RX10- (to Unused 167 TRST# 82571EB) RTM) AMC_RX2+ (to AMC_TX7- (to 100 AMC_RX10+ (to 168 TDO SATA mux) 82571EB) RTM) AMC_RX2- 101 GND TCLKC- 169 TDI SATA mux) ATCA-F140 Installation and Use (6806800M67H)

  • Page 65: Table 3-19 J2/J3 Memory Socket Pin Assignment

    DQ52 DQ58 DQ28 DQ53 DQ59 DQ29 CK0# DQ32 +1.5V DQ33 EVENT# 222 DQS4# 119 +1.5V DQ54 DQS1# 50 CKE0 DQS4 DQ30 DQ55 DQS1 +1.5V DQ31 +1.5V DQ34 RAS# DQ60 DQ10 ERROUT 88 DQ35 CS0# DQ61 ATCA-F140 Installation and Use (6806800M67H)

  • Page 66: Table 3-20 J11 Sas/Sata Connector Pin Assignment

    The following table shows the pinout assignment for the SAS/SATA connector. The board only supports SATA drives. Table 3-20 J11 SAS/SATA Connector Pin Assignment Contact Number Description Contact Number Description GE21 DRIVE_RX+ (input) DRIVE_RX- (input) ATCA-F140 Installation and Use (6806800M67H)

  • Page 67: Table 3-21 P8 Eusb Header Pin Assignment

    DRIVE_TX- (output) DRIVE_TX+ (output) 3.5.4 Embedded USB Connector The ATCA-F140 contains a 10-pin 2mm header for an embedded USB module. The following table shows the pinout assignment for the eUSB header. Table 3-21 P8 eUSB Header Pin Assignment Contact Number...

  • Page 68: Table 3-22 P50 Cop Header Pin Assignment

    No Pin Key COP_CHKSTP_OU 3.5.6 Asset JTAG Header The ATCA-F140 contains a 20-pin 0.1" header for an Asset JTAG header. The pinout for the header is given in the following table. Table 3-23 P12 Asset JTAG Header Pin Assignment Contact...

  • Page 69: Table 3-24 P9 H8S Console Header Pin Assignment

    3.5.7 H8S Console and Programming Header The ATCA-F140 contains an 8-pin 0.1" header to provide access to the H8S serial console and to enable the H8S boot loader for initial programming. The H8S boot loader is enabled when shunts are installed shorting pins 2 to pin 4 and pin 6 to pin 8. The following table shows the pinout assignment for this header.

  • Page 70: Table 3-25 Mechanical Switches

    Boot flash select if SW2.1 is ON N/A (when SW2.1 is OFF) OFF: Boot from Flash #1 ON: Boot from Flash #2 SW2.3 OFF: Watchdog enabled Watchdog timer enabled ON: Watchdog disabled SW2.4 Not used - reserved for future use reserved ATCA-F140 Installation and Use (6806800M67H)

  • Page 71: Figure 4-1 Atca-F140 Block Diagram

    Chapter 4 Functional Description Block Diagram The following block diagram provides a high level functional view of the ATCA-F140 board and its interfaces to the front panel, backplane, and RTM. Figure 4-1 ATCA-F140 Block Diagram Processor The ATCA-F140 utilizes a Freescale P2020 QorIQ processor. The speed grade used on the ATCA- F140 is 1.0 GHz.
  • Page 72 64-bit data interface  Full ECC support  Sleep mode support for self-refresh SDRAM  On-die termination support when using DDR3  Supports auto refreshing  Registered DIMM support  +1.5 V DDR3 compatible interface  ATCA-F140 Installation and Use (6806800M67H)
  • Page 73 4.3.2 Memory Sockets Two 240-pin DDR3 DIMM sockets are provided on the ATCA-F140 to host up to 2 GB of memory in each DIMM socket using readily available single or dual rank DDR3 registered DIMMs. The memory sockets are keyed for DDR3 modules using a 1.5 V supply voltage.
  • Page 74  IPMI The IPMI function of the ATCA-F140 is implemented using the Emerson common ATCA base IPMI design. This building block is based on the Pigeon Point Systems IPMI implementation using the Renesas HD64F2166 microcontroller which is part of the H8S controller family. The...

  • Page 75: Figure 4-2 Ipmi Block Diagram

    Functional Description Hot swap control  Temperature Sensors  Figure 4-2 IPMI Block Diagram ATCA-F140 Installation and Use (6806800M67H)

  • Page 76: Table 4-1 Temperature Sensors

    Local Bus Interface  Local Bus Decoder  Low pin count interface between Host and IPMC  Interrupt Routing Unit  Reset Controller  Local Bus to SPI Interface  Telecom Clocking Support  ATCA-F140 Installation and Use (6806800M67H)
  • Page 77 The FPGA is configured at power up by loading the contents of the SPI PROM device. This configuration uses standard SPI flashes. For applications that demand fault recovery during remote upgrade of the FPGA PROM, the ATCA-F140 board provides a build option to install a backup device. Both PROMs are programmed with identical images during production process.
  • Page 78 4.6.1 Boot Flash On the ATCA-F140, two 256 Mbit NOR Flash devices are used as boot devices for the service processor. The flash devices used will be Micron PC28F256P33BF or equivalent devices. The data bus width to the flash devices is 16 bit, supporting word accesses only.

  • Page 79: Table 4-2 Boot Bank Write Protection

    IPMC reads the status of BOOT_BANK before driving it again. During debugging, it is possible to disconnect the BOOT_BANK signal driven by IPMC and select its value by a mechanical switch setting. ATCA-F140 Installation and Use (6806800M67H)
  • Page 80 Some of the 1GbE SGMII ports from the BCM56334 have the option of being routed through muxes to two different destinations as seen in the block diagram above. The ATCA-F140 board uses 2 channel or 4 channel high speed broadband 2:1 multiplexer/demultiplexer switches to perform this function.

  • Page 81: Table 4-3 Base Switch Mapping

    Base Ch 1A (ShMC) ge15 Base Ch 1B (ShMC) ge16 Base Ch 2 (other SW) ge17 AMC Port 0 ge18 Backplane UC0/1 ge19 Topsync ge20 RTM SFP RTM ETH8 ge21 RTM SFP RTM ETH9 ATCA-F140 Installation and Use (6806800M67H)

  • Page 82: Table 4-4 Fabric Switch Mapping (Default Axp1440 Chassis Configuration)

    640Gbps network switch with 18 integrated warpCores (16 active). Each warpCore has four integrated 10G SerDes allowing native support of one 40GbE or four 10GbE ports. On the ATCA-F140, the BCM56846 is used to provide sixteen 40G ports and four 1G ports.
  • Page 83 Fabric Ch 13 (LS 14) wc12-1 xe21 Fabric Ch 13 (LS 14) wc12-2 xe22 Fabric Ch 13 (LS 14) wc12-3 xe23 Fabric Ch 13 (LS 14) wc13 not used wc14 xe24 RTM QSFP+ RTM ETH7 ATCA-F140 Installation and Use (6806800M67H)
  • Page 84 Front QSFP+ Front ETH2 SFP+ and QSFP+ Modules The ATCA-F140 provides two SFP+ and two QSFP+ module receptacles on the front panel, the SFP+ for base uplinks and the QSFP+ for fabric uplinks. 4.9.1 SFP+ Modules The SFP+ signals RX_LOS, TX_FAULT and MOD_ABS are monitored for status by the BCM8727 PHY.

  • Page 85: Table 4-5 Tested Sfp+ Modules

    I2C interfaces, accessed through the PHY management port, to read the module's on-board EEPROM information to determine type and vendor specific information. QSFP+ status and control registers can also be accessed through the I2C interface. ATCA-F140 Installation and Use (6806800M67H)

  • Page 86: Table 4-6 Tested Qsfp+ Modules And Cables

    Functional Description The ATCA-F140 board is designed to be compatible with QSFP+ modules up to Power Level 2, corresponding to a maximum power of 2W each. Table 4-6 Tested QSFP+ Modules and Cables Emerson Part Number Vendor Part Number Vendor...

  • Page 87: Table

    Functional Description The ATCA-F140 provides current limited power control to the AMC. An electronic circuit breaker device is used to control the 12V payload power and 3.3V management power to the AMC as well as providing current limiting. Table 4-7 AMC Bay Port Usage AMC.0 Regions...

  • Page 88: Figure 4-4 Base Channel Cross-Connect

    The 82571EB uses an external SPI flash device to store configuration data, MAC addresses, etc. An Atmel AT25128B device is used for this purpose. 4.10.2 Channel Cross-Connect The base and fabric channel cross-connect scheme using the 82571EB is shown in the figures below Figure 4-4 Base Channel Cross-Connect ATCA-F140 Installation and Use (6806800M67H)

  • Page 89: Figure 4-5 Fabric Channel Cross-Connect

    Fabric Channel Cross-Connect 4.10.3 Storage Hard Disk Drive The ATCA-F140 provides a SATA connector and mounting features to install a 2.5" SATA hard disk drive on the board. This HDD can be used to store system management data, configuration data, and boot images for the service processor or the PrAMC.
  • Page 90 Functional Description Routing of telecom clocks to AMC site  Statum 3 oscillator  ATCA-F140 Installation and Use (6806800M67H)

  • Page 91: Figure 4-6 Telecom Clocking Subsystem

    Functional Description 4.11.1 Telecom Clocking Subsystem This section shows an overall block diagram of the telecom clocking subsystem. Later sections elaborate on the functionality of each block. Figure 4-6 Telecom Clocking Subsystem ATCA-F140 Installation and Use (6806800M67H)
  • Page 92 Functional Description 4.11.2 BIT/SSU Support Many offices where the ATCA-F140 is likely to be deployed includes a central Building Integrated Timing Supply (BITS) or Source Synchronization Unit (SSU). A BITS is typically an output-only device that provides a precision timing reference, known as the T[3] clock, to shelf-level products that use this for synchronizing the local telecom clocks.
  • Page 93 Functional Description The following figure illustrates the clock flow in a system employing a BITS or SSU. Figure 4-7 BITS/SSU Clock Flow ATCA-F140 Installation and Use (6806800M67H)

  • Page 94: Figure 4-8 Reset Structure Diagram

    Functional Description 4.12 Reset Structure The resets for the ATCA-F140 are controlled by the FPGA. Figure 4-8 Reset Structure Diagram ATCA-F140 Installation and Use (6806800M67H)

  • Page 95: Table 4-8 Reset Sources Versus Reset Outputs

    HRST_L may be asserted at any time completely asynchronously. HRST_L needs to be asserted during power- on reset. During HRST_L assertion, the configuration input signals are sampled into registers inside the P2020 QorIQ Integrated Processor. ATCA-F140 Installation and Use (6806800M67H)
  • Page 96 A power-on or hard reset is initiated by an active low pulse on the RESET_L signal of the Broadcom BCM56334 Base Channel Switch. The initialization process loads all the pin configurable modes, clears all switching tables and places the switch in a disabled and idle state. ATCA-F140 Installation and Use (6806800M67H)
  • Page 97 4.12.4 AMC Bay The IPMC on the ATCA-F140 is responsible for resetting the AMC bay. It initiates a reset cycle after an AMC module is plugged in or if the payload power of the carrier board is in a power cycle.

  • Page 98: Table

    BCM54680-1 (ORed) BIX Octal PHY 2 IRQ_L BCM54680-2 BIX PHY 3 IRQ_L BCM54616S-1 TopSync PHY IRQ_L BCM54616S-2 Front Panel PHY IRQ_L BCM54616S-3 P2020 – UC2 PHY IRQ_L BCM54616S-4 BCM56846 INTA P2020 PCIE 3 INTA Internal ATCA-F140 Installation and Use (6806800M67H)
  • Page 99 The ATCA-F140 JTAG configuration consists of multiple JTAG chains controlled by a JTAG multiplexer. This device has 7 local JTAG slave ports. The ATCA-F140 has devices which reside in the 3.3V management power and the 12V payload power domains. The JTAG multiplexer, the power control CPLD and the H8S processor are powered from 3.3V management power.
  • Page 100 Functional Description ATCA-F140 Installation and Use (6806800M67H)
  • Page 101  Update Linux kernel and U-boot images  This section describes U-Boot features and procedures that are specific to the ATCA-F140. For general information on U-Boot, see http://www.denx.de/wiki/UBoot/WebHome. Accessing U-Boot The U-boot can be accessed using the serial interface connector at the faceplate of the ATCA- F140.
  • Page 102 This procedure assumes that the ATCA-F140 is connected to a TFTP server and that the U-Boot command nfsboot has been defined. The external TFTP server must be connected using the ATCA-F140 face plate connector "ETH5", which is the Ethernet management interface.
  • Page 103 U-Boot For more information, see the U-Boot documentation. 1. Execute the following commands to specify the IP addresses of the ATCA-F140 and the TFTP server by entering the following commands: setenv ipaddr setenv serverip ...
  • Page 104 This section describes how to configure U-boot to boot a Linux kernel stored in the boot flash and to mount the root file system in the user flash. The procedure uses the U-Boot script flashboot, which has been predefined by Emerson. Configure U-boot to boot from flash: setenv bootcmd $flashboot 2.
  • Page 105 This feature is enabled by default on the ATCA-F140. This feature can be useful in many situations, including: Analyzing kernel logs after a Linux kernel panic ...
  • Page 106 Analyzing Kernel Log Files after a Kernel Panic If the Linux OS running on the ATCA-F140 indicates a kernel panic and you wish to analyze the cause, then you can issue a reset (using the face plate button for example) and subsequently analyze kernel log files.

  • Page 107: Table 5-1 Physical Address Map

    U-Boot Memory Map The following table shows the physical address map of the ATCA-F140. Table 5-1 Physical Address Map Device Start Address Size DDR3-RAM 0x00000000 Max. 4 GByte Active boot flash 0xE0000000 32 Mbytes Stand-by boot flash 0xE2000000 32 Mbytes...

  • Page 108: Table

    FPGA Power-On Self Test When the ATCA-F140 is booted, U-boot executes a series of Power-On Self test (POST) routines. These routines check the functionality of different controllers and other on-board resources. The result is stored in memory and has the following format.

  • Page 109: Table 5-4 Post Results In Sys Fw Progress Ipmi Sensor Reading Data

    Memory error. The address and data line test failed. 0x0b U-boot image CRC mismatch detected 0x0D Wrong CPU speed 0xfd Emerson specific POST error code. For more information, see Table "SYS FW PROGRESS IPMI Sensor - POST Error Event Codes" on page 110. 0x00 One of the remaining POST errors was detected.

  • Page 110: Table 5-5 Sys Fw Progress Ipmi Sensor - Post Error Event Codes

    Perform walking-one test on first memory-  mapped register Base interface Data test on LED register page 0, offset 0x12 extender/SPI I2C buses Check whether bus addresses 0x50,0x51, 0x52 are accessible on bus 0 and 0x50, 0x6E on bus 1. ATCA-F140 Installation and Use (6806800M67H)

  • Page 111: Table 5-7 Environment Variable Post_Control

    Boot sequence failure  Software  Face plate reset key  A hard reset is NOT an CPU internal reset, such as a reset issued through the U-Boot command reset or the Linux command reboot. ATCA-F140 Installation and Use (6806800M67H)

  • Page 112: Table 5-8 Atca-F140 Specific U-Boot Commands

    Description bparams_set Allows to configure IPMI system boot options hreset Issues a hard reset on the ATCA-F140. A hard reset resets the entire payload. bootsel 0|1|switch Selects the boot flash which the ATCA-F140 is to boot from after the next restart. 0 selects boot flash 0, 1 selects boot flash 1, and switch selects the currently not selected boot flash, i.e.
  • Page 113 U-Boot Table 5-9 ATCA-F140 Specific U-Boot Environment Variables (continued) Environment Variable Description Can be used to define a command sequence to be executed at inicmd the end of the boot sequence, i.e. before the shell or bootcmd are executed Contains blade-specific values for the Linux kernel command drvargs line.
  • Page 114 1. Connect to U-boot. For more information, see Accessing U-Boot on page 101. 2. Specify the IP address of the ATCA-F140 and the TFTP server by entering the following commands: setenv ipaddr setenv serverip ...
  • Page 115 2 will be active. Note that depending on the blade’s IPMI firmware version, the switch between the U-boot banks may be effective immediately. 7. Copy the image from the RAM to the currently stand-by U-boot bank: cp.b $loadaddr e3f80000 80000 ATCA-F140 Installation and Use (6806800M67H)
  • Page 116 U-Boot Copy to Flash... done 8. Make stand-by U-boot active and vice versa, by entering the following command: bootsel switch 9. In order to boot the new U-Boot, reset the blade. ATCA-F140 Installation and Use (6806800M67H)
  • Page 117 Replacing the Battery The battery provides data retention of seven years summing up all periods of actual data use. Emerson therefore assumes that there is usually no need to replace the battery except, for example, in case of long-term spare part handling.
  • Page 118 Removing the battery with a screw driver may damage the PCB or the battery holder. To  prevent this damage, do not use a screw driver to remove the battery from its holder. Install the new battery following the "positive" and "negative" signs. ATCA-F140 Installation and Use (6806800M67H)

  • Page 119: Table B-1 Emerson Network Power - Embedded Computing Publications

    The publications listed below are referenced in this manual. You can obtain electronic copies of Emerson Network Power - Embedded Computing publications by contacting your local Emerson sales office. For released products, you can also visit our Web site for the latest copies of our product documentation.

  • Page 120: Table B-2 Specifications

    Refer to the table below for related specifications. Note that the information in these documents are subject to change without notice. Table B-2 Specifications Organization Document PICMG ATCA Base Specification Revision 3.0 Ethernet/Fiber Channel Specification Revision 1.0 Advanced Mezzanine Card Base Specification Revision 2.0 ATCA-F140 Installation and Use (6806800M67H)
  • Page 121 Emerson and our suppliers take significant steps to make sure that there are no bent pins on the backplane or connector damage to the boards prior to leaving the factory. Bent pins caused by improper installation or by inserting boards with damaged connectors could void the Emerson warranty for the backplane or boards.
  • Page 122 (EMI) shielding to maintain EMC compliance. Board products are tested in a representative system to show compliance with the above mentioned requirements. A proper installation in a compliant system maintains the required performance. ATCA-F140 Installation and Use (6806800M67H)
  • Page 123 Before installing or removing additional devices or modules, read the respective documentation and use appropriate tools. Blade Damage Incorrect installation of the blade can cause damage of the blade, Only use handles when installing/removing the blade to avoid damage/deformation to the face plate and/or PCB. ATCA-F140 Installation and Use (6806800M67H)
  • Page 124 Overheating and Blade Damage Operating the blade without forced air cooling may lead to overheating and thus damage of the blade. When operating the blade, make sure that forced air cooling is available in the shelf. ATCA-F140 Installation and Use (6806800M67H)
  • Page 125 Setting/resetting the switches during operation can cause damage to the product. Check and change switch settings before you install the product. Product Damage Too much force may damage the reset switch. Use minimal force when pressing the reset switch. ATCA-F140 Installation and Use (6806800M67H)
  • Page 126 Installing AMC modules with small operating temperature ranges into the ATCA-F140 may further restrict the operating temperature range of the ATCA-F140. Make sure that the operating temperature of any installed AMC modules and the ATCA-F140 as a bundle are within allowed limits...
  • Page 127 SFP/SFP+/QSFP+ module inoperable. Only remove the optical plug when you are ready to connect a cable to the SFP/SFP+/QSFP+ module. When no cable is connected, cover the port with an optical port plug. ATCA-F140 Installation and Use (6806800M67H)
  • Page 128 Do not use a screw driver to remove the battery from its holder. Environment Environmental Damage Improperly disposing of used products may harm the environment. Always dispose of used products according to your country’s legislation and manufacturer’s instructions. ATCA-F140 Installation and Use (6806800M67H)
  • Page 129 Anwendungen, lebenserhaltenden Geräten oder in Flugzeugen verwendet werden. Einbau, Wartung und Betrieb dürfen nur von durch Emerson ausgebildetem oder im Bereich Elektronik oder Elektrotechnik qualifiziertem Personal durchgeführt werden. Die in diesem Handbuch enthaltenen Informationen dienen ausschließlich dazu, das Wissen von Fachpersonal zu ergänzen, können dieses jedoch nicht ersetzen.
  • Page 130 Sie sicher, dass ausreichend Schutz vor Störstrahlung vorhanden ist. Die Blades müssen mit der Frontblende installiert und alle freien Steckplätze müssen mit Blindblenden abgedeckt sein. Änderungen, die nicht ausdrücklich von Emerson erlaubt sind, können Ihr Recht das System zu betreiben zunichte machen. ATCA-F140 Installation and Use (6806800M67H)
  • Page 131 Beschädigung des Produktes und der Zusatzmodule Fehlerhafter Ein- oder Ausbau von Zusatzmodulen führt zu Beschädigung des Produktes oder der Zusatzmodule. Lesen Sie deshalb vor dem Ein- oder Ausbau von Zusatzmodulen die Dokumentation und benutzen Sie angemessenes Werkzeug. ATCA-F140 Installation and Use (6806800M67H)
  • Page 132 Betreiben Sie das Blade nur innerhalb der angegebenen Grenzwerte für die relative Luftfeuchtigkeit und Temperatur. Stellen Sie vor dem Einschalten des Stroms sicher, dass sich auf dem Blade kein Kondensat befindet und betreiben Sie das Blade nicht unter -5°C. ATCA-F140 Installation and Use (6806800M67H)
  • Page 133 Das Verstellen von Schaltern während des laufenden Betriebes kann zur Beschädigung des Produktes führen. Prüfen und ändern Sie die Schaltereinstellungen, bevor Sie das Produkt installieren. Beschädigung des Produktes Zu viel Druck kann den Reset Schalter beschädigen. Drücken Sie den Reset Schalter nur leicht. ATCA-F140 Installation and Use (6806800M67H)
  • Page 134 Ein leerer AMC-Steckplatz kann zu verminderter Kühlung des Shelfs sowie starker elektromagnetischer Strahlung führen und somit eine Überschreitung von EMV-Grenzwerten zur Folge haben. Installieren Sie daher immer ein Filler-Panel in einen anderweitig nicht verwendeten AMCSteckplatz. ATCA-F140 Installation and Use (6806800M67H)
  • Page 135 Bestimmungen für Laserprodukte eingehalten werden. Verletzungsgefahr der Augen Optische SFP/SFP+-Module können Laserstrahlen aussenden, wenn kein Kabel angeschlossen ist. Blicken Sie daher nicht direkt in die Öffnung eines SFP/SFP+-Moduls, um Verletzungen der Augen zu vermeiden. ATCA-F140 Installation and Use (6806800M67H)
  • Page 136 Benutzen Sie keinesfalls einen Schraubendreher, um die Batterie aus der Halterung zu nehmen. Umweltschutz Umweltverschmutzung Falsche Entsorgung der Produkte schadet der Umwelt. Entsorgen Sie alte Produkte gemäß der in Ihrem Land gültigen Gesetzgebung und den Empfehlungen des Herstellers. ATCA-F140 Installation and Use (6806800M67H)
  • Page 137 Index abbreviations amc module control, leds, connectors conventions environmental requirements features fpga functional description installation installation requirements ipmi mechanical data memory ordering information power requirements requirements environmental sata drive installation thermal requirements u-boot ATCA-F140 Installation and Use (6806800M67H)
  • Page 138 Index ATCA-F140 Installation and Use (6806800M67H)
  • Page 140 Precision Cooling Surge & Signal Protection Emerson, Business-Critical Continuity, Emerson Network Power and the Emerson Network Power logo are trademarks and service marks of Emerson Electric Co. All other product or service names are the property of their respective owners.

This manual is also suitable for:

6806800m67h

Table of Contents