Embedded Computing for Business-Critical ContinuityTM MVME4100 Single Board Computer Installation and Use P/N: 6806800H18D June 2010
© 2009 Emerson All rights reserved. Trademarks Emerson, Business-Critical Continuity, Emerson Network Power and the Emerson Network Power logo are trademarks and service marks of Emerson Electric Co. © 2008 Emerson Electric Co. All other product or service names are the property of their respective owners. Intel® is a trademark or registered trademark of Intel Corporation or its subsidiaries in the United States and other countries.
Contents About this Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Safety Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Sicherheitshinweise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents Contents 3 Controls, LEDs, and Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 3.1 3.2 3.3 3.4 4 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents 4.11 XMC Expansion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 4.12 Power Supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 4.12.1 Power Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 4.12.2 Power Supply Monitor . . . .
Contents Contents 6.5 6.6 6.7 6.8 A Battery Exchange. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 A.1 B Firmware Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 6.5.1 Default VME Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 6.5.
List of Tables Table 1-1 Table 1-2 Table 1-3 Table 1-4 Table 2-1 Table 2-2 Table 2-3 Table 2-4 Table 2-5 Table 2-6 Table 3-1 Table 3-2 Table 3-3 Table 3-4 Table 3-5 Table 3-6 Table 3-7 Table 3-8 Table 3-9 Table 3-10 Table 3-11 Table 3-12 Table 3-13 Table 3-14 Table 3-15 Table 3-16 Table 3-17 Table 4-1 Table 5-1 Table 5-2 Table 5-3 Table 5-4 Table 5-5 Table 5-6 Table 5-7 Table 5-8 Features List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables Table 6-1 Table 6-2 Table B-1 Table B-2 Table B-3 8 MOTLoad Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 MOTLoad Image Flags . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122 Emerson Network Power - Embedded Computing Publications . . . . . . . . . . . . . . . . . . 129 Manufacturer’s Publications . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Figures Figure 1-1 Figure 1-2 Figure 2-1 Figure 2-2 Figure 2-3 Figure 2-4 Figure 2-5 Figure 2-6 Figure 3-1 Figure 3-2 Figure 4-1 Figure 5-1 Figure 5-2 Figure 5-3 Figure 5-4 Figure 5-5 Figure A-1 Declaration of Conformity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Serial Number Label Location . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Primary Side Thermally Significant Components . . . . . . .
List of Figures 10 MVME4100 Single Board Computer Installation and Use (6806800H18D)
About this Manual Overview of Contents This manual provides the information required to install and configure an MVME4100 Single Board Computer. Additionally, this manual provides specific preparation and installation information and data applicable to the board. The MVME4100 single-board computer, with the Freescale MPC8548E system-on-chip (SoC) processor, provides a high-performance, cost-effective continuation for currently deployed VME infrastructure.
About this Manual About this Manual Appendix B, Related Documentation, provides listings for publications, manufacturer’s documents and related industry specification for this product.
About this Manual Term Meaning ECC Error Correction Code EEPROM Electrically Erasable Programmable Read-Only Memory EPROM Erasable Programmable Read-Only Memory FCC Federal Communications Commission FEC Fast Ethernet Controller FIFO First In First Out F/W Firmware fpBGA Flip chip Plastic Ball Grid Array GB Gigabytes Gbit Gigabit Gbps Gigabits Per Second GMII Gigabit Media Independent Interface GPCM General Purpose Chip select Machine GPR General Purpose Register H/W Hardware
About this Manual About this Manual 14 Term Meaning Mbit Megabit MBLT Multiplexed Block Transfer Mbps Megabits Per Second MHz Megahertz MII Media Independent Interface MSB Most Significant Byte Msb Most Significant Bit MTBF Mean Time Between Failure NAND (Not and) Flash that is used for storage NOR (Not or) Flash that is used for executing code OS Operating System PBGA Plastic Ball Grid Array PCI Peripheral Component Interconnect PCI-X Peripheral Component Interconnect -X PIC
About this Manual Term Meaning ROM Read-Only Memory RTBI Reduced Ten Bit Interface RTC Real-Time Clock RTM Rear Transition Module sATA Serial AT Attachment SBC Single Board Computer SDRAM Synchronous Dynamic Random Access Memory SMT Surface Mount Technology SODIMM Small-Outline Dual In-line Memory Module SPD Serial Presence Detect SoC System-on-Chip SRAM Static Random Access Memory S/W Software TBI Ten Bit Interface TSEC Three-Speed Ethernet Controller 2eSST Two edge Source
About this Manual About this Manual Conventions The following table describes the conventions used throughout this manual.
About this Manual Notation Description Indicates a hazardous situation which, if not avoided, could result in death or serious injury Indicates a hazardous situation which, if not avoided, may result in minor or moderate injury Indicates a property damage message No danger encountered.
About this Manual About this Manual Summary of Changes Part Number Publication Date Description 6806800H18A January 2009 Early access version 6806800H18B April 2009 Update for final release, updated table "Feature List", added "Declaration of Conformity", added section "Serial Number Label", added weight of the board to section "Mechanical Data", updated power requirements, added location of thermally significant components, updated graphic of switch location, updated connector pinouts, updated blo
Safety Notes This section provides warnings that precede potentially dangerous procedures throughout this manual. Instructions contained in the warnings must be followed during all phases of operation, service, and repair of this equipment. You should also employ all other safety precautions necessary for the operation of the equipment in your operating environment.
Safety Notes Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. Changes or modifications not expressly approved by Emerson Network Power could void the user's authority to operate the equipment. Board products are tested in a representative system to show compliance with the above mentioned requirements.
Safety Notes Damage of Circuits Electrostatic discharge and incorrect installation and removal can damage circuits or shorten their life. Before touching the board or electronic components, make sure that you are working in an ESD-safe environment. Board Malfunction Switches marked as "reserved" might carry production-related functions and can cause the board to malfunction if their setting is changed. Do not change settings of switches marked as "reserved".
Safety Notes Data Loss Exchanging the battery can result in loss of time settings. Backup power prevents the loss of data during exchange. Quickly replacing the battery may save time settings. Data Loss If the battery has low or insufficient power the RTC is initialized. Exchange the battery before seven years of actual battery use have elapsed. PCB and Battery Holder Damage Removing the battery with a screw driver may damage the PCB or the battery holder.
Sicherheitshinweise Dieses Kapitel enthält Hinweise, die potentiell gefährlichen Prozeduren innerhalb dieses Handbuchs vorrangestellt sind. Beachten Sie unbedingt in allen Phasen des Betriebs, der Wartung und der Reparatur des Systems die Anweisungen, die diesen Hinweisen enthalten sind. Sie sollten außerdem alle anderen Vorsichtsmaßnahmen treffen, die für den Betrieb des Produktes innerhalb Ihrer Betriebsumgebung notwendig sind.
Sicherheitshinweise EMV Das Produkt wurde in einem Emerson Standardsystem getestet. Es erfüllt die für digitale Geräte der Klasse A gültigen Grenzwerte in einem solchen System gemäß den FCC-Richtlinien Abschnitt 15 bzw. EN 55022 Klasse A. Diese Grenzwerte sollen einen angemessenen Schutz vor Störstrahlung beim Betrieb des Produktes in Gewerbe- sowie Industriegebieten gewährleisten. Das Produkt arbeitet im Hochfrequenzbereich und erzeugt Störstrahlung.
Sicherheitshinweise Beschädigung des Produktes Fehlerhafte Installation des Produktes kann zu einer Beschädigung des Produktes führen. Verwenden Sie die Handles, um das Produkt zu installieren/deinstallieren. Auf diese Weise vermeiden Sie, dass das Front Panel oder die Platine deformiert oder zerstört wird. Beschädigung des Produktes und von Zusatzmodulen Fehlerhafte Installation von Zusatzmodulen, kann zur Beschädigung des Produktes und der Zusatzmodule führen.
Sicherheitshinweise Kabel und Stecker Beschädigung des Produktes Bei den RJ-45-Steckern, die sich an dem Produkt befinden, handelt es sich entweder um Twisted-Pair-Ethernet (TPE) oder um E1/T1/J1-Stecker. Beachten Sie, dass ein versehentliches Anschließen einer E1/T1/J1-Leitung an einen TPE-Stecker das Produkt zerstören kann. z Kennzeichnen Sie deshalb TPE-Anschlüsse in der Nähe Ihres Arbeitsplatzes deutlich als Netzwerkanschlüsse.
Sicherheitshinweise Schäden an der Platine oder dem Batteriehalter Wenn Sie die Batterie mit einem Schraubendreher entfernen, können die Platine oder der Batteriehalter beschädigt werden. Um Schäden zu vermeiden, sollten Sie keinen Schraubendreher zum Ausbau der Batterie verwenden. Umweltschutz Entsorgen Sie alte Batterien und/oder Boards/RTMs stets gemäß der in Ihrem Land gültigen Gesetzgebung und den Empfehlungen des Herstellers.
Sicherheitshinweise 28 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Chapter 1 Introduction 1.1 Features The MVME4100 Single Board Computer is a VMEbus board based on the MPC8548E Integrated Processor. It is a full 6U board and occupies a single VME card slot with PMC cards installed. The MVME4100 is compliant with the VITA standards VMEbus, 2eSST, and PCI-X as listed in Appendix B, Related Documentation. Target applications for this board are medical imaging, industrial control, radar/sonar, and test and measure.
Introduction Table 1-1 Features List (continued) Function Features Flash 128 MB soldered NOR flash with two alternate 1 MB boot sectors selectable via hardware switch H/W switch or S/W bit write protection for entire logical bank 4 GB NAND flash NVRAM One 512 KB MRAM PCI_E 8X Port to XMC Expansion I/O One front panel mini DB-9 connector for front I/O: one serial channel Two front panel RJ-45 connectors with integrated LEDs for front I/O: two 10/100/1000 Ethernet channels One front panel USB Type A
Introduction Table 1-1 Features List (continued) Function Features VME Interface VME64 (ANSI/VITA 1-1994) compliant (3 row backplane 96-pin VME connector) VME64 Extensions (ANSI/VITA 1.1-1997) compliant (5 row backplane 160-pin VME connector) 2eSST (ANSI/VITA 1.5-2003) compliant ANSI/VITA 1.7-2003 compliant (Increased Current Level for 96 pin & 160 pin DIN/IEC Connector Standard) VITA 41.0, version 0.
Introduction 1.2 Standard Compliances The MVME4100 is designed to be CE compliant and to meet the following standard requirements. Table 1-2 Board Standard Compliances Standard Description UL 60950-1 Safety Requirements (legal) EN 60950-1 IEC 60950-1 CAN/CSA C22.
Introduction Figure 1-1 Declaration of Conformity MVME4100 Single Board Computer Installation and Use (6806800H18D) 33
Introduction 1.3 Mechanical Data This section provides details on the board’s mechanical data. Table 1-3 Mechanical Data 1.4 Characteristic Value Dimensions (D x W x H) 6U, 4HP wide, (233.4 mm x 160 mm x 19.8 mm) Weight 0.453 kg Ordering Information When ordering board variants or board accessories, use the order numbers given in the following tables. 1.4.
Introduction The IPMC712 and IPMC761 I/O modules are not supported on the MVME4100. 1.4.3 Serial Number Label You can find the serial number of your product on a label that is located on the PCB close to the front panel. The following figure shows a sample label and its location. The actual label on your product may vary in content and location.
Introduction 36 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Chapter 2 Hardware Preparation and Installation 2.1 Overview This chapter provides startup and safety instructions related to this product, hardware preparation instruction that includes default switch settings. System considerations and installation instructions for the base board, PMC, and transition module are also described in this chapter. A fully implemented MVME4100 consists of the base board plus: z Two single-wide or one double-wide PCI Mezzanine Card (PMC) slot for added versatility.
Hardware Preparation and Installation Table 2-1 Startup Overview (continued) 2.2 Task Page Examine and/or change environmental parameters. MVME4100 Single Board Computer Programmer’s Reference Program the board as needed for your applications. MVME4100 Single Board Computer Programmer’s Reference Unpacking and Inspecting the Board Read all notices and cautions prior to unpacking the product.
Hardware Preparation and Installation 2.3 Requirements Make sure that the board, when operated in your particular system configuration, meets the requirements specified in the next sections. 2.3.1 Environmental Requirements The following table lists the currently available specifications for the environmental characteristics of the MVME4100. A complete functional description of the MVME4100 base board appears in Chapter 4, Functional Description.
Hardware Preparation and Installation Product Damage High humidity and condensation on the board surface causes short circuits. Do not operate the board outside the specified environmental limits. Make sure the board is completely dry and there is no moisture on any surface before applying power. 2.3.2 Power Requirements Up to 90 W (18 A at 5 V) of power can be supplied to the board in a 5-row backplane. 70 W (14 A at 5 V) can be supplied in a 3-row backplane. The board requires 18 W to 22 W (3.6 A to 4.
Hardware Preparation and Installation 2.3.3 Thermal Requirements The MVME4100 module requires a minimum air flow of 10 CFM uniformly distributed across the board, with the airflow traveling from the heat sink to the PMC2 site, when operating at a 55 °C (131 °F) ambient temperature. 2.3.4 Thermally Significant Components The following table summarizes components that exhibit significant temperature rises. These are the components that should be monitored in order to assess thermal performance.
Hardware Preparation and Installation Figure 2-1 Primary Side Thermally Significant Components U2 U4 XJ1 U12 U22 U25 U21 U24 U27 U34 U35 U36 42 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Hardware Preparation and Installation Figure 2-2 Secondary Side Thermally Significant Components U66 U67 2.3.
Hardware Preparation and Installation 2.4 Configuring the Board To produce the desired configuration and ensure proper operation of the MVME4100, you may need to carry out certain hardware modifications before installing the module. The MVME4100 provides software control over most options: by setting bits in control registers after installing the module in a system, you can modify its configuration. The MVME4100 control registers are described in the MVME4100 Programmer’s Reference.
Hardware Preparation and Installation The following sections describe the on-board switches and their configurations for the MVME4100. Board Malfunction Switches marked as "reserved" might carry production-related functions and can cause the board to malfunction if their setting is changed. Do not change settings of switches marked as "reserved". The setting of switches which are not marked as "reserved" has to be checked and changed before board installation. 2.4.
Hardware Preparation and Installation Table 2-5 Configuration Switch Settings (S1) Switch Description Setting Function S1-1 Safe Start1 [OFF] Use normal ENV ON Use safe ENV [OFF] Flash memory map normal and boot block A selected ON Boot block B selected, mapped to highest address [OFF] Entire NOR flash not write-protected ON Flash is write-protected S1-2 S1-3 Boot Block B Select Flash Bank WP When this switch is on, writes to the NOR flash devices are blocked by hardware.
Hardware Preparation and Installation position when installed in a 5-row chassis in order to get the correct address from the P1 connector. This switch also includes the SCON control switches. More information regarding GA address switch assignments can be found in the MVME4100 Single Board Computer Programmer’s Reference.
Hardware Preparation and Installation 2. The VME SCON SEL switch is OFF to select non-SCON mode. The switch is ON to select always SCON mode. This switch is only effective when the VME SCON MAN switch is ON. If you are installing the optional MVME7216E transition module, refer to Transition Module on page 48 for configuration switch settings. 2.5 Installing Accessories This section describes the procedures for installing the MVME7216E transition module, PMCs, and the XMCspan on the base board. 2.5.
Hardware Preparation and Installation Installation and Removal Procedure To begin the installation of the transition module in a chassis, proceed as follows: 1. Turn all equipment power OFF and disconnect the power cable from the AC power source. 2. Remove the chassis cover as instructed in the equipment user's manual. 3. Remove the filler panel(s) from the appropriate card slot(s) at the rear of the chassis (if the chassis has a rear card cage). 4.
Hardware Preparation and Installation The user-configured switches S1 and S2 are not accessible with a PMC installed in PMC site 2. The onboard PMC sites are configured to support +3.3 V I/O PMC modules. 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 I/O keying pins must be installed in the holes. If both keying pins are not in the same location or if the keying pins are not installed, the PMC sites will not function.
Hardware Preparation and Installation 4. Slide the edge connector of the PMC module into the front panel opening from behind and place the PMC module on top of the base board. The four connectors on the underside of the PMC module should then connect smoothly with the corresponding connectors on the MVME4100. 5. Insert the four short phillips-head screws (provided with the PMC) through the holes on the bottom side of the MVME4100 and the PMC front bezel and into rear standoffs. 6. Tighten the screws.
Hardware Preparation and Installation 7. Reinstall the MVME4100 assembly in its proper card slot. Be sure the module is well seated in the backplane connectors. Do not damage or bend connector pins. 8. If the PMC module was installed in a non-hot swap chassis, replace the chassis or system cover(s), reconnect the system to the AC or DC power source and turn the equipment power on. Figure 2-6 2.5.
Hardware Preparation and Installation 2.6 Installing and Removing the Board This section describes a recommended procedure for installing a board module in a chassis. The MVME4100 does not support hot swap. You should remove power to the slot or system before installing the module. Before installing the MVME4100, ensure that the serial ports and switches are properly configured.
Hardware Preparation and Installation 7. Simultaneously move the injector/ejector levers in an inward direction. 8. Verify that the MVME4100 is properly seated. 9. Secure it to the chassis using the two screws located adjacent to the injector/ejector levers. 10.Connect the appropriate cables to the MVME4100. To remove the board from the chassis, reverse the procedure and press the red locking tabs (IEEE handles only) to extract the board. 2.
Hardware Preparation and Installation The console settings for the MVME4100 are: z Eight bits per character z One stop bit per character z Parity disabled (no parity) z Baud rate of 9600 baud 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 chassis to the AC or DC power source, and turn the equipment power on. 2.
Hardware Preparation and Installation 56 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Chapter 3 Controls, LEDs, and Connectors 3.1 Overview This chapter summarizes the controls, LEDs, connectors, and headers for the MVME4100 base board. Connectors for the MVME7216E transition module can be found in Rear Panel Connectors on page 95.
Controls, LEDs, and Connectors 3.2 Board Layout The following figure shows the components, LEDs, connectors, and the reset switch on the MVME4100.
Controls, LEDs, and Connectors 3.3 Front Panel The following switch, LEDs, and connectors are available on the MVME4100 front panel. Figure 3-2 Front Panel LEDs, Connectors, Switch PMC 2 PMC 1 COMM 1 USB GENET 1 GENET 2 3.3.1 USER 1 ABT/RST FAIL SPEED ACT SPEED ACT Reset/Abort Switch The MVME4100 has a single push button switch to provide both the abort and reset functions. When the switch is depressed for less than 3 seconds, an abort interrupt is generated to the MPC8548E PIC.
Controls, LEDs, and Connectors 3.3.2 LEDs The next table describes the LEDs on the front panel of the MVME4100. Refer to Figure 3-2 on page 59 for LED locations. Table 3-1 Front Panel LEDs Label Function Color Description BFL Board Fail Red This indicator is illuminated during a hard reset and remains illuminated until software turns it off. The LED is controlled by bit 14 (BDFAIL) of the VSTAT register in the Tsi148.
Controls, LEDs, and Connectors 3.3.3 Connectors This section describes the pin assignments and signals for the connectors on the MVME4100. The next table lists the standard connectors on the MVME4100 base board. Refer to Figure 3-1 on page 58 for connector locations. Pin assignments for the connectors are in the following sections. Some connectors use standard pin assignments in compliance with the VMEbus, IEEE, PCI, and ANSI/VITA specifications.
Controls, LEDs, and Connectors 3.3.3.1 XMC Expansion Connector (J6) One 76-pin Mictor connector with a center row of ground pins is used to provide XMC expansion capability.
Controls, LEDs, and Connectors Table 3-3 XMC Expansion Connector (J6) Pin Assignments (continued) Pin Signal Signal Pin 39 GND GND 40 41 TX4_P RX4_P 42 43 TX4_N RX4_N 44 45 GND GND 46 47 TX5_P RX5_P 48 49 TX5_N RX5_N 50 51 GND GND 52 53 TX6_P RX6_P 54 55 TX6_N RX6_N 56 57 GND GND 58 59 TX7_P RX7_P 60 61 TX7_N RX7_N 62 63 GND GND 64 65 No Connect No Connect 66 67 No Connect No Connect 68 69 TDI TDO 70 71 TRST_N I2C_CLK 72 73 TMS I2C_D
Controls, LEDs, and Connectors 3.3.3.2 Ethernet Connectors (J4A/J4B) There are four 10/100/1000 Mb/s full duplex Ethernet interfaces using the MPC8548E Triple Speed Ethernet Controllers (TSECs). Two Gigabit Ethernet interfaces are routed to the two front-panel RJ-45 connectors with integrated LEDs for speed and activity indication. The other Gigabit Ethernet interfaces are routed to P2 for rear I/O.
Controls, LEDs, and Connectors Table 3-5 PMC Slot 1 Connector (J11) Pin Assignments (continued) Pin Signal Signal Pin 9 INTD# PCI_RSVD (No Connect) 10 11 GND +3.3Vaux (No Connect) 12 13 CLK GND 14 15 GND PMCGNT1# 16 17 PMCREQ1# +5V 18 19 +3.3V (VIO) AD31 20 21 AD28 AD27 22 23 AD25 GND 24 25 GND C/BE3# 26 27 AD22 AD21 28 29 AD19 +5V 30 31 +3.
Controls, LEDs, and Connectors Table 3-5 PMC Slot 1 Connector (J11) Pin Assignments (continued) Pin Signal Signal Pin 63 GND REQ64# 64 Table 3-6 PMC Slot 1 Connector (J12) Pin Assignments 66 Pin Signal Signal Pin 1 +12V TRST# 2 3 TMS TDO 4 5 TDI GND 6 7 GND Not Used 8 9 Not Used Not Used 10 11 Pull-up to +3.3V +3.3V 12 13 RST# Pull-down 14 15 +3.3V Pull-down 16 17 Not Used GND 18 19 AD30 AD29 20 21 GND AD26 22 23 AD24 +3.
Controls, LEDs, and Connectors Table 3-6 PMC Slot 1 Connector (J12) Pin Assignments (continued) Pin Signal Signal Pin 47 M66EN AD10 48 49 AD08 +3.3V 50 51 AD07 REQ1B# 52 53 +3.3V GNT1B# 54 55 Not Used GND 56 57 Not Used EREADY0 58 59 GND Not Used 60 61 ACK64# +3.
Controls, LEDs, and Connectors Table 3-7 PMC Slot 1 Connector (J13) Pin Assignments (continued) Pin Signal Signal Pin 31 AD49 GND 32 33 GND AD48 34 35 AD47 AD46 36 37 AD45 GND 38 39 +3.3V (VIO) AD44 40 41 AD43 AD42 42 43 AD41 GND 44 45 GND AD40 46 47 AD39 AD38 48 49 AD37 GND 50 51 GND AD36 52 53 AD35 AD34 54 55 AD33 GND 56 57 +3.
Controls, LEDs, and Connectors Table 3-8 PMC Slot 1 Connector (J14) Pin Assignments (continued) Pin Signal Signal Pin 15 PMC1_15 (P2-C8) PMC1_16 (P2-A8) 16 17 PMC1_17 (P2-C9) PMC1_18 (P2-A9) 18 19 PMC1_19 (P2-C10) PMC1_20 (P2-A10) 20 21 PMC1PMC1_21 (P2-C11) PMC1_22 (P2-A11) 22 23 PMC1_23 (P2-C12) PMC1_24 (P2-A12) 24 25 PMC1_25 (P2-C13) PMC1_26 (P2-A13) 26 27 PMC1_27 (P2-C14) PMC1_28 (P2-A14) 28 29 PMC1_29 (P2-C15) PMC1_30 (P2-A15) 30 31 PMC1_31 (P2-C16) PMC1_32 (P2-A16
Controls, LEDs, and Connectors Table 3-9 PMC Slot 2 Connector (J21) Pin Assignments 70 Pin Signal Signal Pin 1 TCK -12V 2 3 GND INTC# 4 5 INTD# INTA# 6 7 PMCPRSNT1# +5V 8 9 INTB# PCI_RSVD (No Connect) 10 11 GND +3.3Vaux (No Connect) 12 13 CLK GND 14 15 GND PMCGNT1# 16 17 PMCREQ1# +5V 18 19 +3.3V (VIO) AD31 20 21 AD28 AD27 22 23 AD25 GND 24 25 GND C/BE3# 26 27 AD22 AD21 28 29 AD19 +5V 30 31 +3.
Controls, LEDs, and Connectors Table 3-9 PMC Slot 2 Connector (J21) Pin Assignments (continued) Pin Signal Signal Pin 55 AD04 GND 56 57 +3.3V (VIO) AD03 58 59 AD02 AD01 60 61 AD00 +5V 62 63 GND REQ64# 64 Table 3-10 PMC Slot 2 Connector (J22) Pin Assignments Pin Signal Signal Pin 1 +12V TRST# 2 3 TMS TDO 4 5 TDI GND 6 7 GND Not Used 8 9 Not Used Not Used 10 11 Pull-up to +3.3V +3.3V 12 13 RST# Pull-down 14 15 +3.
Controls, LEDs, and Connectors Table 3-10 PMC Slot 2 Connector (J22) Pin Assignments (continued) Pin Signal Signal Pin 39 PERR# GND 40 41 +3.3V SERR# 42 43 C/BE1# GND 44 45 AD14 AD13 46 47 M66EN AD10 48 49 AD08 +3.3V 50 51 AD07 REQ1B# 52 53 +3.3V GNT1B# 54 55 Not Used GND 56 57 Not Used EREADY1 58 59 GND RSTOUT# 60 61 ACK64# +3.
Controls, LEDs, and Connectors Table 3-11 PMC Slot 2 Connector (J23) Pin Assignments (continued) Pin Signal Signal Pin 23 AD55 AD54 24 25 AD53 GND 26 27 GND AD52 28 29 AD51 AD50 30 31 AD49 GND 32 33 GND AD48 34 35 AD47 AD46 36 37 AD45 GND 38 39 +3.3V (VIO) AD44 40 41 AD43 AD42 42 43 AD41 GND 44 45 GND AD40 46 47 AD39 AD38 48 49 AD37 GND 50 51 GND AD36 52 53 AD35 AD34 54 55 AD33 GND 56 57 +3.
Controls, LEDs, and Connectors 3.3.3.4 Serial Port Connector (COM1/J1) There is one front access asynchronous serial port interface (SP0) that is routed to the micro DB-9 front-panel connector. You can use the Emerson part SERIAL-MINI-D2 to convert to a DB9 male connector. The pin assignments for this connector are as follows: Table 3-12 COM1 Port Connector Pin Assignments 3.3.3.
Controls, LEDs, and Connectors 3.3.3.6 VMEbus P1 Connector The VME P1 connector is a 160-pin DIN. The P1 connector provides power and VME signals for 24-bit address and 16-bit data.
Controls, LEDs, and Connectors Table 3-14 VMEbus P1 Connector Pin Assignments (continued) 3.3.3.7 Pin ROW Z ROW A ROW B ROW C ROW D Pin 24 GND A07 IRQ7* A14 +3.3V (Not Used) 24 25 Reserved (N/C) A06 IRQ6* A13 Reserved (N/C) 25 26 GND A05 IRQ5* A12 +3.3V (Not Used) 26 27 Reserved (N/C) A04 IRQ4* A11 Reserved (N/C) 27 28 GND A03 IRQ3* A10 +3.3V (Not Used) 28 29 Reserved (N/C) A02 IRQ2* A09 Reserved (N/C) 29 30 GND A01 IRQ1* A08 +3.
Controls, LEDs, and Connectors Table 3-15 VME P2 Connector Pinouts (continued) 3.
Controls, LEDs, and Connectors 3.4.1 Processor COP Header (P4) There is one standard 16-pin header that provides access to the COP function. The pin assignments for this header are as follows: Table 3-16 Processor COP Header (P4) Pin Assignments Pin Signal Signal Pin 1 CPU_TDO No Connect 2 3 CPU_TDI CPU_TRST_L 4 5 Pull-up to +3.3V Pull-up to CPU_VIO (+3.
Controls, LEDs, and Connectors Table 3-17 Boundary Scan Header (P5) Pin Assignments (continued) Pin Signal Signal Pin 11 KEY No Connect 12 13 GND AUTOWR_N 14 15 GND No Connect 16 17 GND No Connect 18 19 GND No Connect 20 Pin 10 must be grounded in the cable in order to enable boundary scan.
Controls, LEDs, and Connectors 80 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Chapter 4 Functional Description 4.1 Overview The MVME4100 VMEbus board is based on the MPC8548E system-on-chip (SoC) processors. The MVME4100 provides front panel access to one serial port with a mini DB-9 connector, two 10/100/1000 Ethernet ports with two RJ-45 connectors, and one USB port with one type A connector. The front panel includes a fail indicator LED, user-defined indicator LED, and a reset/abort switch.
Functional Description 4.2 Block Diagram The following figure is a block diagram of the MVME4100 architecture.
Functional Description 4.3 Processor The MVME4100 is designed to support the MPC8548E processor. The processor is configured to operate at 1.3 GHz core frequency with a corresponding 533 Mb DDR2 memory bus. The MVME4100 supports the power-on reset (POR) pin sampling method for processor reset configuration. The states of the various configuration pins on the processor are sampled when reset is de-asserted to determine the desired operating modes.
Functional Description For programming information, see the MVME4100 Single Board Computer Programmer’s Reference. 4.5 System Memory The MVME4100 includes one SO-CDIMM socket. The SO-CDIMM socket supports 1 GByte and 2 GByte DDR2 SDRAM modules. The MVME4100 supports memory speeds up to DDR533. 4.6 Timers Timing functions for the MVME4100 are provided by four global high-resolution timers integrated into the MPC8548E plus four additional independent 32-bit timers in a PLD.
Functional Description 4.8 Local Bus Interface The MVME4100 uses the MPC8548E Local Bus Controller (LBC) for access to on-board flash and I/O registers. The LBC has programmable timing modes to support devices of different access times, as well as device widths of 8, 16, and 32 bits. The MVME4100 uses the LBC in GPCM mode to interface to two physical banks of on-board flash, an on-board Quad UART (QUART), an MRAM, and on-board 32-bit timers along with control/status registers.
Functional Description 4.8.2 NVRAM The MVME4100 includes one Freescale 512 MB MRAM device connected to the MPC8548E device control bus to provide a non-volatile memory that has unlimited writes, fast access and long term data retention without power. The MRAM device selected is also an extended temperature device with an operating range from -40 °C to 105 °C/-40 °F to +221 °F. The MRAM is organized as 256 K by 16. Refer to the data sheet for additional information. 4.8.
Functional Description 4.9 DUART Interface The MVME4100 provides a front access asynchronous serial port interface using Serial Port 0 from the MPC8548E DUART. The TTL-level signals SIN, SOUT, RTS and CTS from Serial Port 0 are routed through on-board RS-232 drivers and receivers to the mini DB-9 front panel connector. 4.10 PCI-X Port The PCI-X port on the MPC8548E connects to the TSi148 VMEbus interface and two PCI-X to PCI-X bridges, PLX PCI6520.
Functional Description 4.11 XMC Expansion The MVME4100 provides an additional XMC/PMC module capability through the use of a 78-pin stacking connector. This connector is connected to the PCI Express port on the processor. Up to four additional XMC/PMC modules may be added by using two expansion boards. Refer to the XMCspan manual for additional details and/or programming information. 4.
Functional Description 4.13 Clock Distribution The clock function generates and distributes all of the clocks required for system operation. The PCI-E clocks are generated using an eight output differential clock driver. The PCI/PCI-X bus clocks are generated by the bridge chips from the PCI-E clock. Additional clocks required by individual devices are generated near the devices using individual oscillators. For clock assignments, refer to the MVME4100 Single Board Computer Programmer’s Reference manual.
Functional Description z Watchdog timer z System control register (BRD_RST) z VMEbus reset A board level hard reset generates a reset for the entire SBC including the processor, local PCI/PCI-X buses, Ethernet PHYs, serial ports, flash devices, and PLD(s). If the MVME4100 is configured as the VME system controller, the VMEbus and local Tsi148 reset input are also reset. 4.15 Real Time Clock Battery There is an on-board battery holder that provides easy replacement of a +3.
Chapter 5 Transition Module 5.1 Overview This chapter provides information on the MVME7216E transition module’s features. It also includes a drawing of the module showing the components and rear panel connectors.
Transition Module 5.2 Transition Module Layout The following illustration shows the component layout and connectors on the MVME7216E transition module.
Transition Module 5.3 Features The MVME7216E transition module is for I/O routing through the rear of a compact VMEbus chassis. It connects directly to the VME backplane in chassis’ with an 80 mm deep rear transition area. The MVME7216E is designed for use with the host MVME4100 board.
Transition Module 5.4 SEEPROM Address Switch, S1 A 4-position SMT configuration switch is located on the MVME7216E transition module to set the device address of the RTM serial EEPROM device and to control its write protection (if SW4 is OFF, write is enabled). The switch settings are defined in the next table. To see the switch location, refer to Figure 5-1 on page 92.
Transition Module 5.5 Rear Panel Connectors The MVME7216E transition module provides the following connectors. All connectors use standard pin assignments in compliance with the VMEbus specifications.
Transition Module PMC I/O (PIM) connector J10 routes only power and ground from VME P2 connector. There are no host I/O signals on this connector. The MVME4100 routes PMC I/O from J14 of PMC Slot 1 to VME P2 rows A and C. The MVME7216E routes these signals (pin-for-pin) from VME P2 to PMC I/O module connector J14.
Transition Module There are two sets of ACT and SPEED LEDs, one set for each Ethernet connector. They are described in the next table. Table 5-5 Transition Module LEDs 5.5.1 LED Function ACT Activity for Ethernet or Gigabit E Ethernet connector SPEED 10/100/1000Mb/s of Ethernet connectors MVME7216E PMC I/O Module (PIM) Connectors (J10, J14) PMC Host I/O connector J10 routes only power and ground from VME P2. There are no Host I/O signals on this connector.
Transition Module Table 5-6 MVME721 Host I/O Connector (J10) Pin Assignments (continued) 98 Pin Signal Signal Pin 29 GND No Connect 30 31 No Connect No Connect 32 33 No Connect GND 34 35 No Connect No Connect 36 37 +5V No Connect 38 39 No Connect No Connect 40 41 No Connect +3.
Transition Module 5.5.2 Ethernet Connectors (GIGE/J41B, GIGE/J2B,GIGE/J2A) The MVME4100 routes two 10/100/1000Mb/s full duplex Ethernet interfaces to the VMEbus P2 connector. The MVME7216E routes these from the P2 connector to the RJ-45 connectors on RTM panel. These connectors include integrated LEDs for speed and activity indication. The pin assignments for these connectors are as follows: Table 5-7 Ethernet Connectors Pin Assignment 5.5.
Transition Module Table 5-8 COM Port Connector Pin Assignments 5.6 Pin Signal 7 CTS 8 No connect PMC Input/Output Module If a PMC Input/output Module (PIM) has already been installed on the MVME7216E, or you are installing a transition module as it has been shipped from the factory, disregard this procedure and refer to Transition Module on page 48. Procedure For PIM installation, perform the following steps: 1. Attach an ESD strap to your wrist. 2.
Transition Module Refer to the following figure for proper screw/board alignment. The example below may not accurately represent your MVME7216E.
Transition Module 102 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Chapter 6 MOTLoad Firmware 6.1 Overview The MOTLoad firmware package serves as a board power-up and initialization package, as well as a vehicle from which user applications can be booted. A secondary function of the MOTLoad firmware is to serve in some respects as a test suite providing individual tests for certain devices. This chapter includes a list of standard MOTLoad commands, the default VME and firmware settings that are changeable by the user, remote start, and the alternate boot procedure.
MOTLoad Firmware Operationally, MOTLoad utility applications differ from MOTLoad test applications in several ways: 6.3.2 z Only one utility application operates at any given time (that is, multiple utility applications cannot be executing concurrently). z Utility applications may interact with the user. Most test applications do not. Tests A MOTLoad test application determines whether or not the hardware meets a given standard. Test applications are validation tests.
MOTLoad Firmware Most MOTLoad tests can be organized to execute as a group of related tests (a testSuite) through the use of the testSuite command. The expert operator can customize their testing by defining and creating a custom testSuite(s). The list of built-in and user-defined MOTLoad testSuites, and their test contents can be obtained by entering testSuite -d at the MOTLoad prompt. All testSuites that are included as part of a product specific MOTLoad firmware package are product specific.
MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) Command Description bmb Block Move Byte/Halfword/Word bmh bmw br Assign/Delete/Display User-Program Break-Points bsb Block Search Byte/Halfword/Word bsh bsw bvb Block Verify Byte/Halfword/Word bvh bvw cdDir ISO9660 File System Directory Listing cdGet ISO9660 File System File Load clear Clear the Specified Status/History Table(s) cm Turns on Concurrent Mode csb Calculates a Checksum Specified by Command-line Options csh csw 106 de
MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) Command Description fdShow Display (Show) File Discriptor flashLock Flash Memory Sector Lock flashProgram Flash Memory Program flashShow Display Flash Memory Device Configuration Data flashUnlock Flash Memory Sector Unlock gd Go Execute User-Program Direct (Ignore Break-Points) gevDelete Global Environment Variable Delete gevDump Global Environment Variable(s) Dump (NVRAM Header + Data) gevEdit Global Environment Variable Edit gevI
MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) 108 Command Description mpuShow Display multi-processor control structure mpuStart Start the other MPU netBoot Network Boot (BOOT/TFTP) netShow Display Network Interface Configuration Data netShut Disable (Shutdown) Network Interface netStats Display Network Interface Statistics Data noCm Turns off Concurrent Mode pciDataRd Read PCI Device Configuration Header Register pciDataWr Write PCI Device Configuration Header Register pciD
MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) Command Description testDisk Test Disk testEnetPtP Ethernet Point-to-Point testNvramRd NVRAM Read testNvramRdWr NVRAM Read/Write (Destructive) testRam RAM Test (Directory) testRamAddr RAM Addressing testRamAlt RAM Alternating testRamBitToggle RAM Bit Toggle testRamBounce RAM Bounce testRamCodeCopy RAM Code Copy and Execute testRamEccMonitor Monitor for ECC Errors testRamMarch RAM March testRamPatterns RAM Patterns testRamPe
MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) 6.
MOTLoad Firmware Example: MVME4100> mytest "mytest" not found MVME4100> If the user enters a partial MOTLoad command string that can be resolved to a unique valid MOTLoad command and presses the carriage-return key, the command is executed as if the entire command string had been entered. This feature is a user-input shortcut that minimizes the required amount of command line input. MOTLoad is an ever changing firmware package, so user-input shortcuts may change as command additions are made.
MOTLoad Firmware 6.4.1 Rules There are a few things to remember when entering a MOTLoad command: z Multiple commands are permitted on a single command line, provided they are separated by a single semicolon (;). z Spaces separate the various fields on the command line (command/arguments/options). z The argument/option identifier character is always preceded by a hyphen (-) character. z Options are identified by a single character. z Option arguments immediately follow (no spaces) the option.
MOTLoad Firmware Usage: testRam [-aPh] [-bPh] [-iPd] [-nPh] [-tPd] [-v] Description: RAM Test [Directory] Argument/Option Description -a Ph: Address to Start (Default = Dynamic Allocation) -b Ph: Block Size (Default = 16KB) -i Pd: Iterations (Default = 1) -n Ph: Number of Bytes (Default = 1MB) -t Ph: Time Delay Between Blocks in OS Ticks (Default = 1) -v O : Verbose Output MVME4100> 6.
MOTLoad Firmware The PCI Master is enabled. z MVME4100> vmeCfg -s -r234 Displaying the selected Default VME Setting - interpreted as follows: VMEbus Master Control Register = 00000003 MVME4100> The VMEbus Master Control Register is set to the default (RESET) condition. z MVME4100> vmeCfg -s -r238 Displaying the selected Default VME Setting - interpreted as follows: VMEbus Control Register = 00000008 MVME4100> The VMEbus Control Register is set to a Global Timeout of 2048 μseconds.
MOTLoad Firmware Inbound window 0 (ITAT0) is not enabled; Virtual FIFO at 256 bytes, 2eSST timing at SST320, respond to 2eSST, 2eVME, MBLT, and BLT cycles, A32 address space, respond to Supervisor, User, Program, and Data cycles. Image maps from 0x00000000 to 0x1FFF0000 on the VMEbus, translates 1x1 to the PCI-X bus (thus 1x1 to local memory). To enable this window, set bit 31 of ITAT0 to 1.
MOTLoad Firmware Outbound window 2 (OTAT2) is enabled, 2eSST timing at SST320, transfer mode of SCT, A24/D32 Supervisory access. The window accepts transfers on the PCI-X Local Bus from 0xB0000000-0xB0FF0000 and translates them onto the VMEbus using an offset of 0x40000000, thus an access to 0xB0000000 on the PCI-X Local Bus becomes an access to 0xF0000000 on the VMEbus.
MOTLoad Firmware Outbound Image 7 Translation Offset Upper Register = 00000000 Outbound Image 7 Translation Offset Lower Register = 4F000000 Outbound Image 7 2eSST Broadcast Select Register = 00000000 MVME4100> Outbound window 7 (OTAT7) is enabled, 2eSST timing at SST320, transfer mode of SCT, CR/CSR Supervisory access.
MOTLoad Firmware 6.5.4 Editing VME Settings To edit the changeable VME setting, type the following at the firmware prompt: 6.5.
MOTLoad Firmware 6.5.6 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 6.6 Remote Start As described in the MOTLoad Firmware Package User's Manual, listed in Appendix B, Related Documentation, remote start allows the user to obtain information about the target board, download code and/or data, modify memory on the target, and execute a downloaded program.
MOTLoad Firmware For further details on CR/CSR space, please refer to the VME64 Specification, listed in Appendix B, Related Documentation. The MVME4100 uses a TSi148 for its PCI/X-to-VME bus bridge.
MOTLoad Firmware 6.7.1 Name Type Size Notes ImageRamAddress unsigned integer 1 RAM address ImageOffset unsigned integer 1 Offset from header start to entry ImageFlags unsigned integer 1 Refer to Image Flags on page 122 ImageVersion unsigned integer 1 User defined Reserved unsigned integer 8 Reserved for expansion Checksum Algorithm The checksum algorithm is a simple unsigned word add of each word (4 byte) location in the image.
MOTLoad Firmware 6.7.2 Image Flags The image flags of the header define various bit options that control how the image will be executed.
MOTLoad Firmware 6.7.3 User Images These images are user-developer boot code; for example, a VxWorks bootrom image. Such images may expect the system software state to be as follows upon entry: z The MMU is disabled. z L1 instruction cache has been initialized and is enabled. z L1 data cache has been initialized (invalidated) and is disabled. z L2 cache is disabled. z L3 cache is disabled. z RAM has been initialized and is mapped starting at CPU address 0.
MOTLoad Firmware POST images are expected, but not required, to return to the boot loader. Upon return, the boot loader proceeds with the scan for an executable alternate boot image. POST images that return control to the boot loader must ensure that upon return, the state of the board is consistent with the state that the board was in at POST entry. USER images should not return control to the boot loader. 6.7.
MOTLoad Firmware The scan is performed downwards beginning at the location of the first possible alternate image and searches first for POST, then USER, and finally Alternate MOTLoad images. In the case of multiple images of the same type, control is passed to the first image encountered in the scan. Safe Start, whether invoked by hitting ESC on the console within the first five seconds following power-on reset or by setting the Safe Start jumper, interrupts the scan process.
MOTLoad Firmware z Search the active flash bank, possibly interactively, for a valid Power On Self Test (POST) image. If found, the POST images executes. Once completed, the POST image returns and startup continues. z Search the active flash bank, possibly interactively, for a valid USER boot image. If found, the USER boot image executes. A return to the boot block code is not anticipated.
Appendix A A Battery Exchange A.1 Battery Exchange Some blade variants contain an on-board battery. The battery location is shown in the following figure.
Battery Exchange The battery provides data retention of seven years summing up all periods of actual data use. Emerson therefore assumes that there usually is no need to exchange the battery except, for example, in case of long-term spare part handling. Board/System Damage Incorrect exchange of lithium batteries can result in a hazardous explosion. When exchanging the on-board lithium battery, make sure that the new and the old battery are exactly the same battery models.
Appendix B B Related Documentation B.1 Emerson Network Power - Embedded 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: www.emersonnetworkpower.
Related Documentation Table B-2 Manufacturer’s Publications (continued) Document Title and Source Publication Number Atmel Corporation 2-Wire Serial EEPROM 5174B-SEEPR-12/06 32K (4096 x 8), 64K (8192 x 8) AT24C32C, AT24C64C 2-Wire Serial EEPROM Rev. 1116K-SEEPR-1/04 512K (65,536 x 8) AT24C512 NEC Corporation Data Sheet S16265EJ3V0DS00 μPD720101 April 2003 USB2.0 Host Controller Freescale Corporation MPC8548E Integrated Host Processor Reference Manual MPC8548ERM Rev.
Related Documentation Table B-2 Manufacturer’s Publications (continued) Document Title and Source Publication Number Maxim Integrated Products DS1375 Serial Real-Time Clock REV: 121203 MAX3221E/MAX3223E/MAX3243E ±15kV ESD-Protected, 1μA, 3.0V to 5.
Related Documentation Table B-2 Manufacturer’s Publications (continued) Document Title and Source Publication Number Broadcom Corporation BCM5482S 5482S-DS06-R 10/100/1000BASE-T Gigabit Ethernet Transceiver 2/15/07 PLX Technology PCI6520 Version 2.0 PCI-X to PCI-X Bridge Databook B.3 Related Specifications For additional information, refer to the following table for related specifications. As an additional help, a source for the listed document is provided.
Related Documentation Table B-3 Related Specifications (continued) Organization and Standard Document Title PCI Special Interest Group PCI Local Bus Specification, Revision 2.2 PCI Rev 2.2 December 18, 1998 PCI-X Electrical and Mechanical Addendum to the PCI Local Bus Specification, Revision 2.0a PCI-X EM 2.0a PCI-X Protocol Addendum to the PCI Local Bus Specification, Revision 2.0a PCI-X PT 2.0a August 22, 2003 July 22, 2003 Institute for Electrical and Electronics Engineers, Inc.
Related Documentation 134 MVME4100 Single Board Computer Installation and Use (6806800H18D)
Index A alternate boot images 124 B battery exchange 128 board initialization 123 boot code 123 boot images, types 120 bootloader 123 C checksum 121 command line rules MOTLoad 112 command line rules and help 110 comments and suggestions 18 completing the installation 54 compliances 32 contact address 18 control register 119 control status register 119 conventions 16 D damage reporting 38 default VME settings 113 delete 118 display 117 edit 118 restore 119 delete VME settings 118 display VME settings 117
Index O startup overview 37 on-board battery 128 ordering product 34 T P PIM installation 100 PMC 37, 49 power requirements 38 product, how to order 34 R remote start 119 replacing the battery 128 restoring VME settings 119 S serial number label 35 settings, VME 113 specifications board 39 standard compliancy 32 136 thermal requirements 38 transition module PIM installation 100 U user images 124 V VME configuration 113 VME settings 113, 119 delete 118 display 117 edit 118 restore 119 vmeCfg 113
HOW TO REACH LITERATURE AND TECHNICAL SUPPORT: Tempe, Arizona, USA 1 800 759 1107 1 602 438 5720 Munich, Germany +49 89 9608 0 For literature, training, and technical assistance and support programs, visit www.emersonnetworkpowerembeddedcomputing.com Emerson Network Power. The global leader in enabling Business-Critical Continuity™ AC Power Systems Connectivity DC Power Systems Embedded Computing Embedded Power Integrated Cabinet Solutions www.emersonnetworkpowerembeddedcomputing.
