MVME7100 Single Board Computer Installation and Use 6806800E08A November 2008
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Contents About this Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Safety Notes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Sicherheitshinweise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 1 Introduction . . . . . . . . . . . . .
Contents 2.6 2.7 2.8 3 Controls, LEDs, and Connectors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 3.1 3.2 3.3 3.4 4 Installing and Removing the Board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 Completing the Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 Factory Installed Linux . . . . . . . . . . . . . . . . . . . . . .
Contents 4.13 Clock Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.13.1 System Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.13.2 Real Time Clock Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.13.3 Local Bus Controller Clock Divisor . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents B Related Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 B.1 B.2 B.3 Emerson Network Power - Embedded Computing Documents . . . . . . . . . . . . . . . . . . . . . . . 101 Manufacturers’ Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 Related Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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 3-18 Table 4-1 Table 5-1 Table 5-2 Table 5-3 Table 5-4 Table 5-5 Table 6-1 Table 6-2 Table B-1 Table B-2 Table B-3 Features List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables 8 MVME7100 Single Board Computer Installation and Use (6806800E08A)
List of Figures 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 Primary Side Thermally Significant Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Secondary Side Thermally Significant Components . . . . . . . . . . . . . . . . . . . . . . . . . . Switch Locations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Figures 10 MVME7100 Single Board Computer Installation and Use (6806800E08A)
About this Manual Overview of Contents This manual provides the information required to install and configure an MVME7100 Single Board Computer. Additionally, this manual provides specific preparation and installation information and data applicable to the board. The MVME7100 is a high-performance, dual core processor board featuring the Freescale 8641D with a dedicated bridge to each processor.
About this Manual Abbreviations This document uses the following abbreviations: 12 TERM MEANING A Amps A/D Analog/Digital ANSI American National Standard Institute ASIC Application Specific Integrated Circuit BGA Ball Grid Array BLT Block Transfer CCB Core Complex Bus CE Chip Enable CFM Cubic Feet per Minute CHRP (PowerPC) Common Hardware Reference Platform CMC Common Mezzanine Card COM Communications COP Common On-chip Processor COTS Commercial-Off-the-Shelf CPU Central Pr
About this Manual TERM MEANING GPCM General Purpose Chip select Machine GPR General Purpose Register H/W Hardware ID Identification IDMA Independent Direct Memory Access I/O Input/Output IEEE Institute of Electrical and Electronics Engineers I2C Inter IC JTAG Joint Test Access Group KB Kilobytes KBAUD Kilo Baud LBC Local Bus Controller LCD Liquid Crystal Display LED Light Emitting Diode LSB Least Significant Byte MB Megabytes Mbit Megabit MBLT Multiplexed Block Transfer
About this Manual 14 TERM MEANING PRD Product Requirements Document PReP PowerPC Reference Platform PrPMC Processor PCI Mezzanine Card QUART Quad Universal Asynchronous Receiver/Transmitter RAM Random Access Memory Rcv Receive RGMII Reduced Gigabit Media Independent Interface 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
About this Manual Conventions The following table describes the conventions used throughout this manual.
About this Manual Summary of Changes This is the first edition of the MVME7100 Single Board Computer Installation and Use. Part Number Publication Date Description 6806800E08A November 2008 First edition Comments and Suggestions We welcome and appreciate your comments on our documentation. We want to know what you think about our manuals and how we can make them better. Mail comments to us by filling out the following online form: http://www.emersonnetworkpowerembeddedcomputing.
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 representative system to show compliance with the above mentioned requirements. A proper installation in a compliant system will maintain the required performance. Use only shielded cables when connecting peripherals to assure that appropriate radio frequency emissions compliance is maintained.
Safety Notes Operation 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. Damage of Circuits Electrostatic discharge and incorrect installation and removal can damage circuits or shorten their life.
Safety Notes Cabling and Connectors Product Damage RJ-45 connectors on modules are either twisted-pair Ethernet (TPE) or E1/T1/J1 network interfaces. Connecting an E1/T1/J1 line to an Ethernet connector may damage your system. z Make sure that TPE connectors near your working area are clearly marked as network connectors. z Verify that the length of an electric cable connected to a TPE bushing does not exceed 100 meters.
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 Das Produkt arbeitet im Hochfrequenzbereich und erzeugt Störstrahlung. Bei unsachgemäßem Einbau und anderem als in diesem Handbuch beschriebenen Betrieb können Störungen im Hochfrequenzbereich auftreten. Wird das Produkt in einem Wohngebiet betrieben, so kann dies mit grosser Wahrscheinlichkeit zu starken Störungen führen, welche dann auf Kosten des Produktanwenders beseitigt werden müssen.
Sicherheitshinweise Installation Datenverlust Das Herunterfahren oder die Deinstallation eines Boards bevor das Betriebssystem oder andere auf dem Board laufende Software ordnungsmemäss beendet wurde, kann zu partiellem Datenverlust sowie zu Schäden am Filesystem führen. Stellen Sie sicher, dass sämtliche Software auf dem Board ordnungsgemäss beendet wurde, bevor Sie das Board herunterfahren oder das Board aus dem Chassis entfernen.
Sicherheitshinweise Batterie Beschädigung des Blades Ein unsachgemäßer Einbau der Batterie kann gefährliche Explosionen und Beschädigungen des Blades zur Folge haben. Verwenden Sie deshalb nur den Batterietyp, der auch bereits eingesetzt wurde und befolgen Sie die Installationsanleitung. Datenverlust Wenn Sie die Batterie austauschen, können die Zeiteinstellungen verloren gehen. Eine Backupversorgung verhindert den Datenverlust während des Austauschs.
Introduction 1.1 1 Features The MVME7100 Single Board Computer is a VMEbus board based on the MC8640D and MC8641D integrated PowerPC processors. It is a full 6U board and occupies a single VME card slot with PMC cards installed. The MVME7100 is compliant with the VITA standards VMEbus, 2eSST, and PCI-X as listed in Appendix B, Related Documentation.
Introduction Features Table 1-1 Features List (continued) Function Features PCI_E 8X Port to XMC Expansion 8X Port to 5 Port PCI Express switch 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 upright receptacle for front I/O: one USB 2.0 channel PMC site 1 front I/O and rear P2 I/O PMC site 2 front I/O USB One four-channel USB 2.
Standard Compliances 1.2 Introduction Standard Compliances The MVME7100 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 1.4 Ordering Information Ordering Information When ordering board variants or board accessories, use the order numbers given in the following tables. 1.4.1 Supported Board Models At the time of publication of this manual, the MVME7100 Single Board Computer is available in the configurations shown below. Table 1-4 Board Variants 1.4.2 Marketing # Processor MVME7100-0161 MC8640D 1.067 GHz, 1 GB DDR, 4 GB NAND Flash, Scanbe handles MVME7100-0163 MC8640D 1.
Hardware Preparation and Installation 2.1 2 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 baseboard, PMC, and transition module are also described in this chapter. A fully implemented MVME7100 consists of the baseboard plus: z Two single-wide or one double-wide PCI Mezzanine Card (PMC) slot for added versatility.
Hardware Preparation and Installation 2.2 Unpacking and Inspecting the Board Unpacking and Inspecting the Board Read all notices and cautions prior to unpacking the product. 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. Shipment Inspection To inspect the shipment, perform the following steps: 1.
Requirements 2.3 Hardware Preparation and Installation 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 MVME7100. A complete functional description of the MVME7100 baseboard appears in Chapter 4, Functional Description.
Hardware Preparation and Installation 2.3.2 Power Requirements Power Requirements The MVME7100 uses only +5.0 V from the VMEbus backplane. On board power supplies generate the required voltages for the various ICs. The MVME 7100 connects the +12 V and 12 V supplies from the backplane to the PMC sites while the +3.3 V power supplied to the PMC sites comes from the +5.0 V backplane power. A maximum of 10 A of +3.3 V power is available to the PMC sites, however the 90 W +5.
Thermal Requirements 2.3.3 Hardware Preparation and Installation Thermal Requirements The MVME7100 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.
Hardware Preparation and Installation Figure 2-1 Thermally Significant Components Primary Side Thermally Significant Components U4 U6 U7 U8 U9 U10 U11 U12 U13 U14 U20 U22 U25 U27 Figure 2-2 U26 U28 Secondary Side Thermally Significant Components U56 34 U24 U57 U58 U59 U60 U61 U62 U63 U64 MVME7100 Single Board Computer Installation and Use (6806800E08A)
Equipment Requirements 2.3.
Hardware Preparation and Installation 2.4 Configuring the Board Configuring the Board To produce the desired configuration and ensure proper operation of the MVME7100, you may need to carry out certain hardware modifications before installing the module. The MVME7100 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 MVME7100 control registers are described in the MVME7100 Programmer’s Reference.
SMT Configuration Switch, S1 Hardware Preparation and Installation The following sections describe the on-board switches and their configurations for the MVME7100. 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 SMT Configuration Switch, S1 Table 2-5 Configuration Switch Settings (S1) (continued) Switch Description Setting Function S1-5 CORE1 Low Memory Offset [OFF] Normal operation S1-6 S1-7 S1-8 PMC 133 MHz Master WP ON [OFF] PMC 100 MHz maximum ON PMC 133 MHz maximum [OFF] Master write protect disabled ON Master write protect enabled Reserved 1. Switch status is readable from System Status Register 1, bit 5. 2.4.1.
Geographical Address Switch, S2 2.4.1.7 Hardware Preparation and Installation Master WP The Master Write Protect (WP) switch is OFF for normal operation. When this switch is ON, writes to the NOR Flash, NAND Flash, MRAM and I2C EEPROMs are disabled. When the switch is OFF, writes to the non-volatile devices may be allowed depending on other switches and control bits. 2.4.2 Geographical Address Switch, S2 The Tsi148 VMEbus Status Register provides the VMEbus geographical address of the MVME7100.
Hardware Preparation and Installation Installing Accessories Table 2-6 VME System Controller and GA Switch Settings (continued) Position Function Default S2-8 GA0 1 1. The VME SCON MAN switch is OFF to select Auto-SCON mode. The switch is ON to select manual SCON mode which works in conjunction with the VME SCON SEL switch. 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.
PMC 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 PMC Installation Procedure Read all notices and follow these steps to install a PMC on the baseboard. 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. Product Damage Inserting or removing modules with power applied may result in damage to module components.
XMCspan Hardware Preparation and Installation Figure 2-6 2.5.3 Typical Placement of a PMC Module on a VME Module XMCspan The XMCspan is a carrier module that provides PCI Express expansion capability to the MVME7100. Refer to the XMCspan Installation and Use manual (part number 6806800H03) for details about the XMCspan and the installation procedure. 2.6 Installing and Removing the Board This section describes a recommended procedure for installing a board module in a chassis.
Hardware Preparation and Installation Installing and Removing the Board Installation and Removal Procedure Before you install your module, please read all cautions, warnings and instructions presented in this section. 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.
Completing the Installation 2.7 Hardware Preparation and Installation Completing the Installation The MVME7100 is designed to operate as an application-specific compute blade or an intelligent I/O board/carrier. It can be used in any slot in a VME chassis. When the MVME7100 is installed in a chassis, you are ready to connect peripherals and apply power to the board. Figure 3-1 on page 47 and Figure 5-1 on page 75 show the locations of the various connectors on the MVME7100 and MVME7216E.
Hardware Preparation and Installation Factory Installed Linux Emerson Network Power Embedded Computing Linux Kernel 2.6.25 on a 2-processor MVME7100 localhost login: Login as root. The /root/README.MVME7100_LINUX file provides a brief overview of MVME7100 Linux. Contact Emerson Network Power Embedded Computing for kernel patches and additional information on using MVME7100 Linux.
Controls, LEDs, and Connectors 3.1 3 Overview This chapter summarizes the controls, LEDs, connectors, and headers for the MVME7100 baseboard. Connectors for the MVME7216E transition module can be found in Rear Panel Connectors on page 77. 3.2 Board Layout The following figure shows the components, LEDs, connectors, and the reset switch on the MVME7100.
Controls, LEDs, and Connectors 3.3 Front Panel Front Panel The following switch, LEDs, and connectors are available on the MVME7100 front panel. Refer to Figure 3-1 for the location of each. 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 MVME7100 has a single push button switch to provide both the abort and reset functions.
LEDs 3.3.2 Controls, LEDs, and Connectors LEDs The next table describes the LEDs on the front panel of the MVME7100. Refer to Figure 3-1 on page 47 for LED locations. Table 3-1 Front Panel LEDs Label Function Location Color Description BFL Board Fail Front panel 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 Connectors This section describes the pin assignments and signals for the connectors on the MVME7100. The next table lists the standard connectors on the MVME7100 baseboard. Refer to Figure 3-1 on page 47 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.
Connectors 3.3.3.1 Controls, LEDs, and Connectors 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 Connectors Table 3-3 XMC Expansion Connector (J6) Pin Assignments (continued) 3.3.3.
Connectors Controls, LEDs, and Connectors Table 3-4 Ethernet Connectors (J4A/J4B) Pin Assignments (continued) 3.3.3.3 Pin # 10/100/1000 Mb/s 8 _DD- PCI Mezzanine Card (PMC) Connectors (J11 – J14, J21 – J23) There are seven 64-pin SMT connectors on the MVME7100 to provide 32/64-bit PCI interfaces and P2 I/O for one optional add-on PMC. PMC slot connector J14 contains the signals that go to VME P2 I/O rows A, C, D, and Z.
Controls, LEDs, and Connectors Connectors Table 3-5 PMC Slot 1 Connector (J11) Pin Assignments (continued) Pin Signal Signal Pin 51 GND C/BE0# 52 53 AD06 AD05 54 55 AD04 GND 56 57 +3.3V (VIO) AD03 58 59 AD02 AD01 60 61 AD00 +5V 62 63 GND REQ64# 64 Table 3-6 PMC Slot 1 Connector (J12) Pin Assignments 54 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 +3.
Connectors Controls, LEDs, and Connectors Table 3-6 PMC Slot 1 Connector (J12) Pin Assignments (continued) Pin Signal Signal Pin 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# +3.3V 62 63 GND No Connect (MONARCH#) 64 Table 3-7 PMC Slot 1 Connector (J13) Pin Assignments Pin Signal Signal Pin 1 Reserved GND 2 3 GND C/BE7# 4 5 C/BE6# C/BE5# 6 7 C/BE4# GND 8 9 +3.
Controls, LEDs, and Connectors Connectors Table 3-7 PMC Slot 1 Connector (J13) Pin Assignments (continued) Pin Signal Signal Pin 51 GND AD36 52 53 AD35 AD34 54 55 AD33 GND 56 57 +3.
Connectors Controls, LEDs, and Connectors Table 3-8 PMC Slot 1 Connector (J14) Pin Assignments (continued) Pin Signal Signal Pin 51 PMC1_51 (P2-C26) PMC1_52 (P2-A26) 52 53 PMC1_53 (P2-C27) PMC1_54 (P2-A27) 54 55 PMC1_55 (P2-C28) PMC1_56 (P2-A28) 56 57 PMC1_57 (P2-C29) PMC1_58 (P2-A29) 58 59 PMC1_59 (P2-C30) PMC1_60 (P2-A30) 60 61 PMC1_61 (P2-C31) PMC1_62 (P2-A31) 62 63 PMC1_63 (P2-C32) PMC1_64 (P2-A32) 64 Table 3-9 PMC Slot 2 Connector (J21) Pin Assignments Pin Signal Sig
Controls, LEDs, and Connectors Connectors Table 3-9 PMC Slot 2 Connector (J21) Pin Assignments (continued) Pin Signal Signal Pin 51 GND C/BE0# 52 53 AD06 AD05 54 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 58 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 +3.
Connectors Controls, LEDs, and Connectors Table 3-10 PMC Slot 2 Connector (J22) Pin Assignments (continued) Pin Signal Signal Pin 51 AD07 REQ1B# 52 53 +3.3V GNT1B# 54 55 Not Used GND 56 57 Not Used EREADY1 58 59 GND Not Used 60 61 ACK64# +3.3V 62 63 GND No Connect (MONARCH#) 64 Table 3-11 PMC Slot 2 Connector (J23) Pin Assignments Pin Signal Signal Pin 1 Reserved GND 2 3 GND C/BE7# 4 5 C/BE6# C/BE5# 6 7 C/BE4# GND 8 9 +3.
Controls, LEDs, and Connectors Connectors Table 3-11 PMC Slot 2 Connector (J23) Pin Assignments (continued) 3.3.3.4 Pin Signal Signal Pin 51 GND AD36 52 53 AD35 AD34 54 55 AD33 GND 56 57 +3.3V (VIO) AD32 58 59 Reserved Reserved 60 61 Reserved GND 62 63 GND Reserved 64 Serial Port Connector (COM1/J1) There is one front access asynchronous serial port interface (SP0) that is routed to the mini DB-9 front-panel connector.
Connectors Controls, LEDs, and Connectors Table 3-13 VMEbus P1 Connector Pin Assignments (continued) 3.3.3.
Controls, LEDs, and Connectors Connectors Table 3-14 VME P2 Connector Pinouts (continued) 62 Pin P2-Z P2-A P2-B P2-C P2-D 2 GND PMC1_IO4 GND PMC1_IO3 E1-1- 3 SPITX PMC1_IO6 VRETRY_L PMC1_IO5 GND 4 GND PMC1_IO8 VA24 PMC1_IO7 E1-2+ 5 SP1CTS PMC1_IO10 VA25 PMC1_IO9 E1-2- 6 GND PMC1_IO12 VA26 PMC1_IO11 GND 7 SP1RTS PMC1_IO14 VA27 PMC1_IO13 E1-3+ 8 GND PMC1_IO16 VA28 PMC1_IO15 E1-3- 9 SP2RX PMC1_IO18 VA29 PMC1_IO17 GND 10 GND PMC1_IO20 VA30 PMC1_IO19
Connectors 3.3.3.7 Controls, LEDs, and 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. The MVME7100 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. See Table 3-15 and Table 3-8 for the pin assignments.
Controls, LEDs, and Connectors Headers Table 3-15 MVME721 Host I/O Connector (J10) Pin Assignments (continued) 3.3.3.8 Pin Signal Signal Pin 61 No Connect No Connect 62 63 No Connect No Connect 64 USB Connector (J2) There is one USB Type A connector located on the MVME7100 front panel. The pin assignments are as follows: Table 3-16 USB Connector (J2) Pin Assignments 3.4 Pin Signal 1 USB_VBUS (+5.
Boundary Scan Header (P5) 3.4.2 Controls, LEDs, and Connectors Boundary Scan Header (P5) The 20-pin boundary scan header provides an interface for programming the on-board PLDs and for boundary scan testing/debug purposes.
Controls, LEDs, and Connectors 66 Boundary Scan Header (P5) MVME7100 Single Board Computer Installation and Use (6806800E08A)
Functional Description 4.1 4 Overview The MVME7100 VMEbus board is based on the MC8640D (1.067 GHz versions) and the MC8641D (1.33 GHz versions) Integrated Processors. The MVME7100 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 Block Diagram The following figure is a block diagram of the MVME7100 architecture.
I2C Serial Interface and Devices Functional Description The MVME7100 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. Combinations of pull-up and pull-down resistors are used to set the options. Some options are fixed and some are selectable at build time by installing the proper pull-up/pull-down resistor.
Functional Description 4.6 Timers Timers Timing functions for the MVME7100 are provided by four global high-resolution timers integrated into the MC864xD plus four additional independent 32-bit timers. The four integrated 32-bit timers are clocked by the RTC input which is driven by a 1 MHz clock.
Flash Memory 4.8.1 Functional Description Flash Memory The MVME7100 is designed to provide 128 MB of soldered-on NOR flash memory. Two AMD +3.3 V devices are configured to operate in 16-bit mode to form a 32-bit flash bank. This flash bank is also the boot bank and is connected to LBC Chip Select 0 and 1. Also included is a second bank of NAND flash, up to 32 GB, connected to LBC Chip Select 2. The VPD flash packet(s) will determine which devices are populated and the size of the devices.
Functional Description 4.9 DUART Interface DUART Interface The MVME7100 provides a front access asynchronous serial port interface using Serial Port 0 from the MC864xD 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-E Port 0 One 8x PCI-E port from the MC864xD processor is connected to a five port PEX8533 PCI-E switch.
XMC Expansion 4.11 Functional Description XMC Expansion The MVME7100 provides an additional XMC/PMC module capability through the use of a 78pin stacking connector. This connector is connected to the second 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 datasheet for additional details and/or programming information. 4.
Functional Description 4.13.1 System Clock System Clock The system clock is driven by an oscillator. The following table defines the clock frequencies for various configurations. Table 4-1 Clock Frequencies 4.13.2 SYSCLK Core MPX (Platform) DDR2 66.67 MHz 1.3 GHz 533 MHz 266 MHz 66.67 MHz 1.067 GHz 533 MHz 266 MHz Real Time Clock Input The RTC clock input is driven by a 1 MHz clock generated by the Control and Timers PLD.
Transition Module 5.1 5 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. 5.2 Transition Module Layout The following illustration shows the component layout and connectors on the MVME7216E transition module.
Transition Module 5.3 Features 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 MVME7100 board.
Rear Panel Connectors Transition Module Table 5-2 SEEPROM Address Switch Assignments (RTM) Position SW4 SW3 SW2 SW1 Function WP A(2) A(1) A(0) Default (OFF) 0 1 1 1 Table 5-3 Switch Settings and Device Addresses 5.
Transition Module Rear Panel Connectors Figure 5-4 Rear Panel Connectors and LEDs COM2 COM3 COM4 COM5 ACT SPEED ACT G Enet 1 G Enet 2 SPEED PMC Site There are two sets of ACT and SPEED LEDs, one set for each Ethernet connector. They are described in the next table.
PMC Input/Output Module 5.6 Transition Module 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 40. Procedure For PIM installation, perform the following steps: 1. Attach an ESD strap to your wrist. Attach the other end of the ESD strap to the chassis as a ground.
Transition Module PMC Input/Output Module Figure 5-5 Installing the PIM PIM Alignment 80 MVME7100 Single Board Computer Installation and Use (6806800E08A)
MOTLoad Firmware 6.1 6 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 Tests 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.
Command List 6.3.3 MOTLoad Firmware Command List The following table provides a list of all current MOTLoad commands. Products supported by MOTLoad may or may not employ the full command set. Typing help at the MOTLoad command prompt will display all commands supported by MOTLoad for a given product.
MOTLoad Firmware Command List Table 6-1 MOTLoad Commands (continued) Command Description downLoad Down Load S-Record from Host ds 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 execProgram Execute Program fatDir FAT File System Directory Listing fatGet FAT File System File Load fdShow Display (Show) File Discriptor flashLock Flash Memory Sector Lock
Command List MOTLoad Firmware Table 6-1 MOTLoad Commands (continued) Command Description mpuFork Execute program from idle processor 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
MOTLoad Firmware Using the Command Line Interface Table 6-1 MOTLoad Commands (continued) 6.
Using the Command Line Interface MOTLoad Firmware The MOTLoad command line interface is similar to a UNIX command line shell interface. Commands are initiated by entering a valid MOTLoad command (a text string) at the MOTLoad command line prompt and pressing the carriage-return key to signify the end of input. MOTLoad then performs the specified action. An example of a MOTLoad command line prompt is shown below.
MOTLoad Firmware 6.4.1 Rules 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.
Firmware Settings 6.5 MOTLoad Firmware Firmware Settings The following sections provide additional information pertaining to the MVME7100 VME bus interface settings as configured by MOTLoad. A few VME settings are controlled by hardware jumpers while the majority of the VME settings are managed by the firmware command utility vmeCfg. VME settings in MOTLoad are preserved through the use of Global Environment Variables (GEVs). Configuration GEVs are executed only at power-on reset.
MOTLoad Firmware Default VME Settings Displaying the selected Default VME Setting - interpreted as follows: CRG Attribute Register = 00000000 CRG Base Address Upper Register = 00000000 CRG Base Address Lower Register = 00000000 MVME7100> The CRG Attribute Register is set to the default (RESET) condition.
Default VME Settings MOTLoad Firmware Outbound Image 2 Translation Offset Upper Register = 00000000 Outbound Image 2 Translation Offset Lower Register = 40000000 Outbound Image 2 2eSST Broadcast Select Register = 00000000 MVME7100> Outbound window 2 (OTAT2) is enabled, 2eSST timing at SST320, transfer mode of SCT, A24/D32 Supervisory access.
MOTLoad Firmware 6.5.2 Control Register/Control Status Register Settings Control Register/Control Status Register Settings The CR/CSR base address is initialized to the appropriate setting based on the Geographical address; that is, the VME slot number. See the VME64 Specification and the VME64 Extensions for details. As a result, a 512 KB CR/CSR area can be accessed from the VMEbus using the CR/CSR AM code. 6.5.
Deleting VME Settings 6.5.5 MOTLoad Firmware Deleting VME Settings To delete the changeable VME setting (restore default value), type the following at the firmware prompt: 6.5.
MOTLoad Firmware Boot Images CS/CSR Starting Address Slot Position 7 0x0038.0000 8 0x0040.0000 9 0x0048.0000 A 0x0050.0000 B 0x0058.0000 C 0x0060.0000 For further details on CR/CSR space, please refer to the VME64 Specification, listed in Appendix B, Related Documentation. The MVME7100 uses a TSi148 for its PCI/X-to-VME bus bridge.
Checksum Algorithm 6.7.1 MOTLoad Firmware Name Type Size Notes ImageOffset unsigned integer 1 Offset from header start to entry ImageFlags unsigned integer 1 Refer to Image Flags on page 95 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. The image must be a multiple of 4 bytes in length (word-aligned).
MOTLoad Firmware User Images z IMAGE_POST If set, this flag defines the image as being a power-on self-test image. This bit flag is used to indicate that the image is a diagnostic and should be run prior to running either USER or MCG boot images. POST images are expected, but not required, to return to the boot block code upon completion. z DONT_AUTO_RUN If set, this flag indicates that the image is not to be selected for automatic execution.
Alternate Boot Data Structure 6.7.4 MOTLoad Firmware Alternate Boot Data Structure The globalData field of the alternate boot data structure points to an area of RAM which was initialized to zeroes by the boot loader. This area of RAM is not cleared by the boot loader after execution of a POST image, or other alternate boot image, is executed. It is intended to provide a user a mechanism to pass POST image results to subsequent boot images.
MOTLoad Firmware Startup Sequence 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. The user may then display the available boot images and select the desired image. The feature is provided to enable recovery in cases when the programmed Alternate Boot Image is no longer desired.
A Battery Exchange A.1 A Battery Exchange Some blade variants contain an on-board battery. The battery location is shown in the following figure.
Battery Exchange 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.
B Related Documentation B.1 B 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 Manufacturers’ Documents Table B-2 Manufacturer’s Publications (continued) Document Title and Source Publication Number 2-Wire Serial EEPROM Rev. 1116K-SEEPR-1/04 512K (65,536 x 8) AT24C512 NEC Corporation Data Sheet S16265EJ3V0DS00 µPD720101 April 2003 USB2.
Related Specifications 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 PEX8112AA Version 1.2 ExpressLane PCI Express-to-PCI Bridge Data Book ExpressLane PEX 8114BC Version 3.0 PCI Express-to-PCI/PCI-X Bridge Data Book ExpressLane PEX 8525AA Version 0.95 5-Port/24-Lane Versatile PCI Express Switch Data Book B.
Related Documentation Related Specifications Table B-3 Related Specifications (continued) Organization and Standard Document Title 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.
Index A H alternate boot images 97 help command MOTLoad 88 B battery exchange 100 board initialization 97 boot code 96 boot images, types 94 bootloader 97 C checksum 95 command line rules MOTLoad 88 command line rules and help 86 completing the installation 45 compliances 27 control register 93 control status register 93 I inspecting shipment 30 installation, completing 45 L Linux 45 list of commands MOTLoad 83 lithium battery, 100 M edit VME settings 92 EMC requirements 27 environment customizati
S V settings, VME 89 specifications board 31 standard compliancy 27 startup overview 29 VME configuration 89 VME settings 89, 93 delete 93 display 92 edit 92 restore 93 vmeCfg 89 T thermal requirements 30 transition module PIM installation 79 X XMCspan 29, 43 U user images 97 106 MVME7100 Single Board Computer Installation and Use (6806800E08A)
