Emerson MVME6100 Series Installation And Use Manual
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Emerson MVME6100 Series Installation And Use Manual

Emerson MVME6100 Series Installation And Use Manual

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MVME6100 Single Board Computer
Installation and Use
P/N: 6806800D58E
March 2009
Embedded Computing for
Business-Critical Continuity
TM

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Summary of Contents for Emerson MVME6100 Series

  • Page 1 Embedded Computing for Business-Critical Continuity MVME6100 Single Board Computer Installation and Use P/N: 6806800D58E March 2009...
  • 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: Table Of Contents

    3.4.2 Command Line Help............40 MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 4 4.6.8 Watchdog Timer ............. 66 MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 5 5.3.6 Processor JTAG/COP Header (J42) ..........100 MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 6 Related Documentation ............. . 103 Emerson Network Power - Embedded Computing Documents ......103 Manufacturers’...
  • Page 7 MVME6100 Features Summary ........

  • Page 8: List Of Tables

    Thermally Significant Components ......... . . 108 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 9: List Of Figures

    MVME6100 Block Diagram ........

  • Page 10: List Of Figures

    List of Figures MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 11: About This Manual

    The MVME61006E Series Single-Board Computer Installation and Use manual provides the information you will need to install and configure your MVME61006E single-board computer (hereinafter referred to as MVME6100). It provides specific preparation and installation information, and data applicable to the board.
  • Page 12 Used to characterize user input and to separate it Courier + Bold from system output Reference Used for references and for table and figure descriptions File > Exit Notation for selecting a submenu <text> Notation for variables and keys MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 13 Indicates a hazardous situation which, if not avoided, may result in minor or moderate injury Indicates a property damage message No danger encountered. Pay attention to important information MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 14 > Contact Us > Online Form In "Area of Interest" select "Technical Documentation". Be sure to include the title, part number, and revision of the manual and tell us how you used it. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 15: Hardware Preparation And Installation

    2 are routed to row D and row Z of P2. The MVME6100 has two planar PCI buses (PCI0 and PCI1). In order to support a more generic PCI bus hierarchy nomenclature, the MV64360 PCI buses will be referred to in this document as PCI bus 0 (root bridge instance 0, bus 0) and PCI bus 1 (root bridge instance 1, bus 0).

  • Page 16: Getting Started

    Hardware Preparation and Installation The MVME6100 board interfaces to the VMEbus via the P1 and P2 connectors, which use 5-row 160-pin connectors as specified in the VME64 Extension Standard. It also draws +12V and +5V power from the VMEbus backplane through these two connectors. The +3.3V, +2.5V, +1.8V, and processor core supplies are regulated on-board from the +5V power.

  • Page 17: Overview Of Startup Procedures

    1.3.2 Unpacking Guidelines Unpack the equipment from the shipping carton. Refer to the packing list and verify that all items are present. Save the packing material for storing and reshipping of equipment. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 18: Configuring The Hardware

    This section discusses certain hardware and software tasks that may need to be performed prior to installing the board in a chassis. To produce the desired configuration and ensure proper operation of the MVME6100, you may need to carry out certain hardware modifications before installing the module.

  • Page 19: Table 1-2 Jumper And Switch Settings

    Figure 1-1 illustrates the placement of the jumpers, headers, connectors, switches, and various other components on the MVME6100. There are several manually configurable headers on the MVME6100 and their settings are shown in Table 1-2.

  • Page 20: Figure 1-1 Component Layout

    Hardware Preparation and Installation The MVME6100 is factory tested and shipped with the configuration described in the following sections. Figure 1-1 Component Layout IPMC ABT/RST 4296 0604 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 21: Scon Header (J7)

    Nine 3-pin planar headers are for PMC/IPMC mode I/O selection for PMC slot 1. These nine headers can also be combined into one single header block where a block shunt can be used as a jumper. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 22: Pmc I/O Voltage Configuration

    The onboard PMC sites may be configured to support 3.3V or 5.0V I/O PMC modules. To support 3.3V or 5.0V I/O PMC modules, both PMC sites on the MVME6100 have I/O keying pins. One pin must be installed in each PMC site and both PMC sites must have their keying pins configured he same way.

  • Page 23: Front/Rear Ethernet And Transition Module Options Header (J30)

    Similarly, a PMC card that requires 3.3V VIO-only signaling has its keying hole located just to the front of its four PMC connectors, and will only fit to the MVME6100 when the keying pin is located there. However, most modern PMC cards are universal with respect to the VIO signaling voltage they support, and have keying holes in both locations;...

  • Page 24: Srom Configuration Switch (S3)

    A part of the 8-position SMT switch, S3 enables/disables the MV64360 SROM initialization and all I C EEPROM write protection. The SROM Init switch is OFF to disable the MV64360 device initialization via the I C SROM. The switch is ON to enable this sequence. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 25: Table 1-3 Srom Configuration Switch (S3)

    Table 1-3 SROM Configuration Switch (S3) Position FUNCTION SROM WP SROM_INIT DEFAULT (OFF) No SROM_INIT S3 position 3-8 defines the VME Geographical Address if the MVME6100 is installed in a 3-row backplane. The following is the pinout: Position Function VMEGAP_L VMEGA4_L VMEGA3_L...

  • Page 26: Flash Boot Bank Select Configuration Switch (S4)

    When the Safe Start switch is set OFF, normal boot sequence should be followed by MOTLoad. When ON, MOTLoad executes Safe Start, during which the user can select the Alternate Boot Image. Table 1-4 Configuration Switch (S4) Position FUNCTION FACTORY DEFAULT No WP Bank B Norm ENV MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 27: Installing The Blade

    2. Remove any filler panel that might fill that slot. 3. Install the top and bottom edge of the MVME6100 into the guides of the chassis. Only use injector handles for board insertion to avoid damage/deformation to the front panel and/or PCB.

  • Page 28: Completing The Installation

    Verify that hardware is installed and the power/peripheral cables connected are appropriate for your system configuration. Replace the chassis or system cover, reconnect the system to the AC or DC power source, and turn the equipment power on. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 29: Startup And Operation

    VME Bridge ASIC, PCI6520, PMC1/2 slots, both Ethernet PHYs, serial ports, PMCspan slot, both flash banks, and the device bus control PLD. If the MVME6100 is enabled for VME system controller, the VME bus will be reset and local reset input is sent to the Tsi148 VME controller.

  • Page 30: Table 2-1 Front-Panel Led Status Indicators

    The following table describes these indicators: Table 2-1 Front-Panel LED Status Indicators Function Label Color Description CPU Bus Activity Green CPU bus is busy Board Fail BDFAIL Yellow Board has a failure MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 31: Motload Firmware

    DRAM, external cache, flash). Typically, the smallest amount of on-board DRAM that an Emerson SBC has is 32 MB. Each supported product line has its own unique MOTLoad binary image(s). Currently the largest MOTLoad compressed image is less than 1 MB in size.

  • Page 32: Tests

    RAM, which is not considered a true device and can be directly tested without a device path string. Refer to the devShow command description page in the MOTLoad Firmware Package User’s Manual. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 33: Command List

    Table 3-1 MOTLoad Commands Command Description One-Line Instruction Assembler Block Compare Byte/Halfword/Word bdTempShow Display Current Board Temperature Block Fill Byte/Halfword/Word blkCp Block Copy blkFmt Block Format blkRd Block Read blkShow Block Show Device Configuration Data MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 34 Down Load S-Record from Host One-Line Instruction Disassembler echo Echo a Line of Text elfLoader ELF Object File Loader errorDisplay Display the Contents of the Test Error Status Table eval Evaluate Expression MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 35 Display Command/Test Help Strings l2CacheShow Display state of L2 Cache and L2CR register contents l3CacheShow Display state of L3 Cache and L3CR register contents Memory Display Bytes/Halfwords/Words memShow Display Memory Allocation MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 36 Display Port Device Configuration Data User Program Register Display reset Reset System User Program Register Set Set Date and Time sromRead SROM Read sromWrite SROM Write Symbol Table Attach Symbol Table Lookup MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 37 RAM Random Data Patterns testRtcAlarm RTC Alarm testRtcReset RTC Reset testRtcRollOver RTC Rollover testRtcTick RTC Tick testSerialExtLoop Serial External Loopback testSeriallntLoop Serial Internal Loopback testStatus Display the Contents of the Test Status Table MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 38: Using The Command Line Interface

    MOTLoad then performs the specified action. An example of a MOTLoad command line prompt is shown below. The MOTLoad prompt changes according to what product it is used on (for example, MVME5500, MVME6100). Example: MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 39 PAL Version 0.1 (Motorola MVME6100) If the partial command string cannot be resolved to a single unique command, MOTLoad will inform the user that the command was ambiguous. Example: MVME6100> te "te" ambiguous MVME6100> MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 40: Command Line Rules

    For help with a specific test or utility the user can enter the following at the MOTLoad prompt: help <command_name> The help command also supports a limited form of pattern matching. Refer to the help command page. Example MVME6100> help testRam MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 41: Firmware Settings

    Firmware Settings The following sections provide additional information pertaining to the VME firmware settings of the MVME6100. A few VME settings are controlled by hardware jumpers while the majority of the VME settings are managed by the firmware command utility vmeCfg.
  • Page 42 Inbound Image 0 Ending Address Upper Register = 00000000 Inbound Image 0 Ending Address Lower Register = 1FFF0000 Inbound Image 0 Translation Offset Upper Register = 00000000 Inbound Image 0 Translation Offset Lower Register = 00000000 MVME6100> MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 43 Outbound Image 2 Starting Address Upper Register = 00000000 Outbound Image 2 Starting Address Lower Register = B0000000 Outbound Image 2 Ending Address Upper Register = 00000000 Outbound Image 2 Ending Address Lower Register = B0FF0000 MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 44 Outbound Image 7 Starting Address Upper Register = 00000000 Outbound Image 7 Starting Address Lower Register = B1000000 Outbound Image 7 Ending Address Upper Register = 00000000 Outbound Image 7 Ending Address Lower Register = B1FF0000 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 45: Control Register/Control Status Register Settings

    –s –r184 Displays PCI Miscellaneous Register state vmeCfg –s –r188 Displays Special PCI Target Image Register state vmeCfg –s –r400 Displays Master Control Register state vmeCfg –s –r404 Displays Miscellaneous Control Register state MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 46: Editing Vme Settings

    Edits Master Control Register state vmeCfg –e –r404 Edits Miscellaneous Control Register state vmeCfg –e –r40C Edits User AM Codes Register state vmeCfg –e –rF70 Edits VMEbus Register Access Image Control Register state MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 47: Deleting Vme Settings

    Deletes VMEbus Register Access Image Control Register state 3.5.6 Restoring Default VME Settings To restore all of the changeable VME setting back to their default settings, type the following at the firmware prompt: vmeCfg –z MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 48: Remote Start

    Appendix C, Related Documentation. The MVME6100 uses a Discovery II for its VME bridge. The offsets of the mailboxes in the Discovery II are defined in the Discovery II User Manual, listed in Appendix C, Related Documentation, but are noted here for reference:...

  • Page 49: Alternate Boot Images And Safe Start

    The MVME6100’s IBCA needs to be mapped appropriately through the master’s VMEbus bridge. For example, to use remote start using mailbox 0 on an MVME6100 installed in slot 5, the master would need a mapping to support reads and writes of address 0x002ff348 in VME CR/CSR space (0x280000 + 0x7f348).

  • Page 50: Firmware Scan For Boot Image

    Second possible alternate image (Bank B / Bank A actual) (FBC00000 or F7C00000) ..Alternate boot images 0xFF899999 to 0xFF8FFFFF Last possible alternate image (Bank B / Bank A actual) (Fb800000 or F3800000) MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 51 Addr FFE00000 Size 00100000 Flags 00000003 Name: MOTLoad Addr FFD00000 Size 00100000 Flags 00000003 Name: MOTLoad boot> c NOPQRSTUVabcdefghijk#lmn3opqrsstuvxyzaWXZ Copyright Motorola Inc. 1999-2004, All Rights Reserved MOTLoad RTOS Version 2.0, PAL Version 0.b EA02 MVME6100> MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 52: Boot Images

    The algorithm is implemented using the following code: Unsigned int checksum( Unsigned int *startPtr,/* starting address */ Unsigned int endPtr/* ending address */ unsigned int checksum=0; while (startPtr < endPtr) { checksum += *startPtr; MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 53: Image Flags

    USER or MCG boot images. POST images are expected, but not required, to return to the boot block code upon completion. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 54: User Images

    RAM size in MB */ void flashPtr;/* ptr to this image in flash */ char boardType[16];/* name string, eg MVME6100 */ void globalData;/* 16K, zeroed, user defined */ unsigned int reserved[12]; } altBootData_t; MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 55: Alternate Boot Data Structure

    Some later versions of MOTLoad support alternate boot images and a safe start recovery procedure. If safe start is available on the MVME6100, alternate boot images are supported. With alternate boot image support, the boot loader code in the boot block examines the upper 8 MB of the flash bank for alternate boot images.

  • Page 56: Boot Image Firmware Scan

    'd':show directory of alternate boot images 'c':continue with normal startup 'q':quit without executing any alternate boot image 'r [address]':execute specified (or default) alternate image 'p [address]':execute specified (or default) POST image '?':this help screen MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 57: Startup Sequence

    During interactive mode, the user has the option to display locations at which valid boot images were discovered, specify which discovered image is to be executed, or specify that the recovery image in the boot block of the active flash bank is to be executed. MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 58 MOTLoad Firmware MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 59: Functional Description

    Chapter 4 Functional Description Overview This chapter describes the MVME6100 on a block diagram level. Features The following table lists the features of the MVME6100. Table 4-1 MVME6100 Features Summary Feature Description Processor — Single 1.267 GHz MPC7457 processor — Bus clock frequency at 133 MHz —...
  • Page 60 Miscellaneous — Combined reset and abort switch — Status LEDs — 8-bit software-readable switch (S1) — VME geographical address switch (S3) — Boundary Scan header (J8) — CPU RISCWatch COP header (J42) MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 61: Block Diagram

    4250 0604 Processor The MVME6100 supports the MPC7457 with adjustable core voltage supply. The maximum external processor bus speed is 133 MHz. The processor core frequency runs at 1.267 GHz or the highest speed MPC7457 can support, which is determined by the processor core voltage, the external speed, and the internal VCO frequency.

  • Page 62: L3 Cache

    Functional Description L3 Cache The MVME6100 external L3 cache is implemented using two 8Mb DDR SRAM devices. The L3 cache bus is 72-bits wide (64 bits of data and 8 bits of parity) and operates at 211 MHz. The L3 cache interface is implemented with an on-chip, 8-way, set-associative tag memory.

  • Page 63: Cpu Bus Interface

    4.6.2 Memory Controller Interface The MVME6100 supports two banks of DDR SDRAM using 256Mb/ 512Mb DDR SDRAM devices on-board. 1Gb DDR non-stacked SDRAM devices may be used when available. 133 MHz operation should be used for all memory options. The SDRAM supports ECC and the MV64360 supports single-bit and double-bit error detection and single-bit error correction of all SDRAM reads and writes.

  • Page 64: Device Controller Interface

    Banks A and B, NVRAM/RTC. Each bank supports up to 512MB of address space, resulting in total device space of 1.5GB. Serial ports are the fourth and fifth devices on the MVME6100. Each bank has its own parameters register as shown in the following table.

  • Page 65: Gigabit Ethernet Macs

    4.6.5 Gigabit Ethernet MACs The MVME6100 supports two 10/100/1000Mb/s full duplex Ethernet ports connected to the front panel via the MV64360 system controller. Ethernet access is provided by front panel RJ- 45 connectors with integrated magnetics and LEDs. Port 1 is a dedicated Gigabit Ethernet port...

  • Page 66: Watchdog Timer

    4.6.11 I C Serial Interface and Devices A two-wire serial interface for the MVME6100 board is provided by a master/slave capable I serial controller integrated into the MV64360 device. The I C serial controller provides two basic functions. The first function is to optionally provide MV64360 register initialization following a reset.

  • Page 67: Interrupt Controller

    The MVME6100 uses the interrupt controller integrated into the MV64360 device to manage the MV64360 internal interrupts as well as the external interrupt requests. The interrupts are routed to the MV64360 MPP pins from on-board resources as shown in the MVME6100 Programmer’s Guide. The external interrupt sources include the following:...

  • Page 68: Pci Bus Arbitration

    VME64x (VITA 1.5) compatible backplanes, such as 5-row backplanes, to achieve maximum VMEbus performance. PMCspan Interface The MVME6100 provides a PCI expansion connector to add more PMC interfaces than the two on the MVME6100 board. The PMCspan interface is provided through the PCI6520 PCIx/PCIx bridge.

  • Page 69: System Memory

    The MVME6100 board supports two PMC slots. Two sets of four EIA-E700 AAAB connectors are located on the MVME6100 board to interface to the 32-bit/64-bit IEEE P1386.1 PMC to add any desirable function. The PMC slots are PCI/PCI-X 33/66/100 capable.
  • Page 70 On either PMC site, the user I/O — Jn4 signals will only support the low-current, high-speed signals and not for any current bearing power supply usage. The maximum current rating of each pin/signal is 250 mA. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 71: Real-Time Clock/Nvram/Watchdog Timer

    62.5 msec (1/16s) and maximum time-out period is 124 seconds. The interface for the Timekeeper and SRAM is connected to the MV64360 device controller bus on the MVME6100 board. Refer to the MV64360 Data Sheet, listed in Appendix C, Related Documentation, for additional information and programming details.

  • Page 72: Processor Jtag/Cop Headers

    Functional Description 4.17 Processor JTAG/COP Headers The MVME6100 provides JTAG/COP connectors for JTAG/COP emulator support (RISCWatch COP J42), as well as supporting board boundary scan capabilities (Boundary Scan header J8). MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 73: Pin Assignments

    Front/Rear Ethernet and Transition Module Options Header (J30) Processor JTAG/COP Header (J42) Connectors The following tables provide a brief description of the connector, the pin assignments, and signal descriptions for standard and nonstandard connectors on the MVME6100. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 74: Pmc Expansion Connector (J4)

    Signal Signal +3.3V +3.3V PCICLK PMCINTA# PMCINTB# PURST# PMCINTC# HRESET# PMCINTD# TRST# PCIXP# PCIXGNT# PCIXREQ# +12V -12V PERR# SERR# LOCK# SDONE DEVSEL# SBO# TRDY# IRDY# STOP# FRAME# M66EN ACK64# Reserved REQ64# Reserved MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 75 Table 5-1 PMC Expansion Connector (J4) Pin Assignments (continued) Signal Signal PCIRST# C/BE1# C/BE0# C/BE3# C/BE2# AD11 AD10 AD13 AD12 AD15 AD14 AD17 AD16 AD19 AD18 AD21 AD20 AD23 AD22 AD25 AD24 AD27 AD26 AD29 AD28 AD31 AD30 MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 76 AD42 AD45 AD44 AD47 AD46 AD49 AD48 AD51 AD50 AD53 AD52 AD55 AD54 AD57 AD56 AD59 AD58 AD61 AD60 AD63 AD62 All PMC expansion signals are dedicated PMC expansion PCI bus signals. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 77: Gigabit Ethernet Connectors (J9, J93)

    Gigabit Ethernet Connectors (J9, J93) Access to the dual Gigabit Ethernet is provided by two transpower RJ-45 connectors with integrated magnetics and LEDs located on the front panel of the MVME6100. The pin assignments for these connectors are as follows:...

  • Page 78: Table 5-3 Pmc Slot 1 Connector (J11) Pin Assignments

    PMCPRSNT1# INTD# PCI_RSVD +3.3Vaux PMCGNT1# PMCREQ1# +3.3V (VIO) AD31 AD28 AD27 AD25 C/BE3# AD22 AD21 AD19 +3.3V (VIO) AD17 FRAME# IRDY# DEVSEL# PCIXCAP LOCK# PCI_RSVD PCI_RSVD +3.3V (VIO) AD15 AD12 AD11 AD09 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 79: Table 5-4 Pmc Slot 1 Connector (J12) Pin Assignments

    Table 5-4 PMC Slot 1 Connector (J12) Pin Assignments Signal Signal +12V TRST# Not Used Not Used Not Used Pull-up +3.3V RST# Pull-down +3.3V Pull-down Not Used AD30 AD29 AD26 AD24 +3.3V IDSEL1 AD23 +3.3V AD20 AD18 AD16 C/BE2# IDSEL1B MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 80: Table 5-5 Pmc Slot 1 Connector (J13) Pin Assignments

    Not Used ACK64# +3.3V No Connect (MONARCH#) Table 5-5 PMC Slot 1 Connector (J13) Pin Assignments Signal Signal Reserved C/BE7# C/BE6# C/BE5# C/BE4# +3.3V (VIO) PAR64 AD63 AD62 AD61 AD60 AD59 AD58 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 81: Table 5-6 Pmc Slot 1 Connector (J14) Pin Assignments

    AD42 AD41 AD40 AD39 AD38 AD37 AD36 AD35 AD34 AD33 +3.3V (VIO) AD32 Reserved Reserved Reserved Reserved Table 5-6 PMC Slot 1 Connector (J14) Pin Assignments Signal Signal PMC0_1 (P2-C1) PMC0_2 (P2-A1) MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 82 PMC0_41 (P2-C21) PMC0_42 (P2-A21) PMC0_43 (P2-C22) PMC0_44 (P2-A22) PMC0_45 (P2-C23) PMC0_46 (P2-A23) PMC0_47 (P2-C24) PMC0_48 (P2-A24) PMC0_49 (P2-C25) PMC0_50 (P2-A25) PMC0_51 (P2-C26) PMC0_52 (P2-A26) PMC0_53 (P2-C27) PMC0_54 (P2-A27) PMC0_55 (P2-C28) PMC0_56 (P2-A28) MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 83: Table 5-7 Pmc Slot 2 Connector (J21) Pin Assignments

    Table 5-7 PMC Slot 2 Connector (J21) Pin Assignments Signal Signal -12V INTC# INTD# INTA# PMCPRSNT1# INTB# PCI_RSVD +3.3Vaux PMCGNT1# PMCREQ1# +3.3V (VIO) AD31 AD28 AD27 AD25 C/BE3# AD22 AD21 AD19 +3.3V (VIO) AD17 FRAME# IRDY# DEVSEL# PCIXCAP LOCK# MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 84: Table 5-8 Pmc Slot 2 Connector (J22) Pin Assignments

    Table 5-8 PMC Slot 2 Connector (J22) Pin Assignments Signal Signal +12V TRST# Not Used Not Used Not Used Pull-up +3.3V RST# Pull-down +3.3V Pull-down Not Used AD30 AD29 AD26 AD24 +3.3V MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 85: Table 5-9 Pmc Slot 2 Connector (J23) Pin Assignments

    AD07 REQ1B# +3.3V GNT1B# Not Used Not Used EREADY1 Not Used ACK64# +3.3V No Connect (MONARCH#) Table 5-9 PMC Slot 2 Connector (J23) Pin Assignments Signal Signal Reserved C/BE7# C/BE6# C/BE5# C/BE4# MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 86 AD56 AD55 AD54 AD53 AD52 AD51 AD50 AD49 AD48 AD47 AD46 AD45 +3.3V (VIO) AD44 AD43 AD42 AD41 AD40 AD39 AD38 AD37 AD36 AD35 AD34 AD33 +3.3V (VIO) AD32 Reserved Reserved Reserved MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 87: Table 5-10 Pmc Slot 2 Connector (J24) Pin Assignments

    PMC1_31 (P2-D21) PMC1_32 (P2-Z21) PMC1_33 (P2-D22 PMC1_34 (P2-D23) PMC1_35 (P2-Z23) PMC1_36 (P2-D24) PMC1_37 (P2-D25) PMC1_38 (P2-Z25 PMC1_39 (P2-D26) PMC1_40 (P2-D27) PMC1_41 (P2-Z27) PMC1_42 (P2-D28) PMC1_43 (P2-D29) PMC1_44 (P2-Z29) PMC1_45 (P2-D30) PMC1_46 (P2-Z31) MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 88: Com1 Connector (J19)

    5.2.4 COM1 Connector (J19) A standard RJ-45 connector located on the front panel of the MVME6100 provides the interface to the asynchronous serial debug port. The pin assignments for this connector are as follows: Table 5-11 COM1 Connector (J19) Pin Assignments...

  • Page 89: Vmebus P1 Connector

    SYSRESET* Reserved Reserved DS0* BR1* LWORD* Reserved (GA2) WRITE* BR2* Reserved Reserved BR3* Reserved (GA3) DTACK* Reserved Reserved Reserved (GA4) Reserved Reserved Reserved IACK* Reserved Reserved IACKIN* SERA Reserved IACKOUT* SERB Reserved MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 90: Vmebus P2 Connector (Pmc Mode)

    The VME P2 connector is an 160-pin DIN. Row B of the P2 connector provides power to the MVME6100 and to the upper eight VMEbus address lines and additional 16 VMEbus data lines. The pin assignments for the P2 connector are as follows:...
  • Page 91 PMC1_19 (J24-20) 6 (J14- (J14-25) (J24-19) PMC0_2 VD16 PMC0_27 PMC1_21 8 (J14- (J14-27) (J24-21) PMC1_23 PMC0_3 VD17 PMC0_29 PMC1_22 (J24-J23) 0 (J14- (J14-29) (J24-22) PMC0_3 VD18 PMC0_31 PMC1_24 2 (J14- (J14-31) (J24-24) MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 92 0 (J14- (J14-49) (J24-37) P2_IO_GLAN1_M DIO_2+ (J30 B7- PMC0_5 VD27 PMC0_51 PMC1_39 2 (J14- (J14-51) (J24-39) PMC1_41 (J30 D8- PMC0_5 VD28 PMC0_53 PMC1_40 C8) or 4 (J14- (J14-53)/TXB (J24-40) P2_IO_GLAN1_M DIO_2- (J30 B8-C8) MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 93: Vmebus P2 Connector (Ipmc Mode)

    The VME P2 connector is an 160-pin DIN. Row B of the P2 connector provides power to the MVME6100 and to the upper eight VMEbus address lines and additional 16 VMEbus data lines. The pin assignments for the P2 connector are as follows:...
  • Page 94 VD27 CTS1 PMC2_39 (J24-39) PMC2_41 (J24-41) RTS4 VD28 TXD2 PMC2_40 (J24-40) TRXC4 VD29 RXD2 PMC2_42 (J24-42) PMC2_44 (J24-44) CTS4 VD30 RTS2 PMC2_43 (J24-43) DTR4 VD31 CTS2 PMC2_45 (J24-45) PMC2_46 (J24-46) DCD4 DTR2 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 95: Table 5-15 Vme P2 Connector Pinouts With Ipmc761

    VD19 PRACK# PMC2_25 (J24-25) O/I# VD20 PRBSY PMC2_27 (J24-27) PMC2_29 AFD# VD21 PRPE PMC2_28 (J24-28) (J24-29) SLIN# VD22 PRSEL PMC2_30 (J24-30) PMC2_32 TXD3 VD23 INIT# PMC2_31 (J24-31) (J24-32) RXD3 PRFLT# PMC2_33 (J24-33) MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 96: Headers

    MCLK Rows A and C and Zs (Z1, 3, 5, 7, 9, 11, 13, 15, and 17) functionality is provided by the IPMC761 in slot 1 and the MVME6100 Ethernet port 2. Headers The next subsections provide a description of each header and its settings and/or pin assignments.

  • Page 97: Scon Header (J7)

    The 14-pin boundary scan header provides an interface for programming the on-board PLDs and for boundary scan testing/debug purposes. The pin assignments for this header are as follows: Table 5-17 Boundary Scan Header (J8) Pin Assignments Signal Signal TRST_L TCLK CPU_BSCAN_L AW_L MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 98: Pmc/Ipmc Selection Headers (J10, J15 - J18, J25 - J28)

    COM2 only goes to the on-board header as the default configuration. The pin assignments for this header are as follows: Table 5-19 COM2 Planar Serial Port Header (J29) Pin Assignments Signal Signal COM2_DCD COM2_DSR COM2_RX COM2_RTS COM2_TX COM2_CTS MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 99: Front/Rear Ethernet And Transition Module Options Header (J30)

    P2_Z27 magnetic T2-16 MDI_2N (J9-7) PMC1_IO(44) P2_Z29 magnetic T2-14 MDI_3P (J9-8) PMC1_IO(46) P2_Z31 magnetic T2-13 MDI_3N (J9-9) a. VME P2. b. Transformer for Ethernet port #2. c. Ethernet port #2 front connector. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 100: Processor Jtag/Cop Header (J42)

    Signal Signal CPU_TDO CPU_QACK_L CPU_TDI CPU_TRST_L CPU_QREQ_L PU CPU_VIO CPU_TCK OPT PU CPU_VIO CPU_TMS CPU_SRST_L OPTPD_GND CPU_HRST_L KEY (no pin) CPU_CKSTPO_L Some signals are actually resistor buffered versions of the named signal. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 101: Specifications

    Appendix A Specifications Power Requirements In its standard configuration, the MVME6100 requires +5 V, +12 V, and —12 V for operation. On-board converters supply the processor core voltage, +3.3 V, +1.8 V, and +2.5 V. A.1.1 Supply Current Requirements Table A-1 provides an estimate of the typical and maximum current required from each of the input supply voltages.
  • Page 102 6U, 4HP wide (233 mm x 160 mm x 20 mm) (9.2 in. x 6.3 in. x 0.8 in) MTBF 328,698 hours, calculated based on BellCore Issue 6, Method 1, case 3 for the central office or environmentally controlled remote shelters or customer premise areas. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 103: Related Documentation

    Computing Documents The Emerson Network Power - Embedded Computing 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 documentation of final released (GA) products, you can also visit the following website: http://www.emersonnetworkpowerembeddedcomputing.com...
  • Page 104 ST16C554/554D Rev. 3.10 EXAR Corporation 48720 Kato Road Fremont, CA 94538 Web Site: http://www.exar.com 3.3V-5V 256Kbit (32Kx8) Timekeeper SRAM M48T37V ST Microelectronics 1000 East Bell Road Phoenix, AZ 85022 Web Site: http://www.st.com/stonline/books/toc/index.htm MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 105: Related Specifications

    Revision 2.0, 2.1, 2.2 PCI-X Addendum to the PCI Local Bus Specification Rev 1.0b IEEE http://standards.ieee.org IEEE - Common Mezzanine Card Specification (CMC) Institute of P1386 Draft 2.0 Electrical and Electronics Engineers, Inc. MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 106 Related Documentation Table C-3 Related Specifications (continued) Document Title and Source Publication Number IEEE - PCI Mezzanine Card Specification (PMC) P1386.1 Draft 2.0 Institute of Electrical and Electronics Engineers, Inc. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 107: Thermal Validation

    You can find components on the board by their reference designators as shown in Figure B-1 Figure B-2. Versions of the board that are not fully populated may not contain some of these components. MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 108 Gigabit Ethernet Transceiver Case U82, U83 Cache Case U45, U46 Programmable Logic Device PCI Bridge Discovery II Case Clock Generator U14, U22 Clock Buffer MC7457RX, 1.267 GHz Processor Case Tsi148 VME Bridge ASIC MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 109: Figure B-1 Thermally Significant Components-Primary Side

    Thermal Validation Figure B-1 Thermally Significant Components–Primary Side IPMC ABT/RST 4248 0504 MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 110: Component Temperature Measurement

    B-1. B.3.1 Preparation We recommend 40 AWG (American wire gauge) thermocouples for all thermal measurements. Larger gauge thermocouples can wick heat away from the components and disturb air flowing past the board. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 111: Measuring Junction Temperature

    Also make sure that heatsinks lay flat on electrical components. The following figure shows one method of machining a heatsink base to provide a thermocouple routing path. MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 112: Figure B-3 Mounting A Thermocouple Under A Heatsink

    Machined groove for Through hole for thermocouple thermocouple wire junction clearance (may require routing removal of fin material) Also use for alignment guidance during heatsink installation Thermal pad Heatsink base HEATSINK BOTTOM VIEW MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 113: Measuring Local Air Temperature

    This method is conservative since it includes heating of the air by the component. The following figure illustrates one method of mounting the thermocouple. Figure B-4 Measuring Local Air Temperature Tape thermocouple wire to top of component Thermocouple junction Air flow MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 114 Thermal Validation MVME6100 Single Board Computer Installation and Use (6806800D58E)

  • Page 115: Index

    L3 cache delete VME settings LEDs dimensions board fail display VME settings CPU bus activity list of commands edit VME settings MOTLoad environmental specifications ESD precautions evaluating thermal performance memory MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 116 MPC7457 processor unpacking guidelines operating temperatures, maximum user images physical dimensions vibration power requirements VME settings power, apply delete processor display edit restore relative humidity vmeCfg remote start restore VME settings MVME6100 Single Board Computer Installation and Use (6806800D58E)
  • Page 118 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.

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