GE Fanuc Automation VMIVME-7810 Specifications ® ® Intel Pentium M Processor- Based VME Single Board Computer Features: • Reliability, Availability, Serviceability, Usability and • Dual slot VMEbus single board computer (SBC) Manageability (RASUM) features: ® ® • Intel Pentium M processor, 478-pin µPGA – Supports S4EC/D4ED ECC and x4 chipkill ECC • Processor speeds up to 1.8 GHz – Primary hub interfaces protected by ECC • 1 Mbyte L2 cache on-die – Secondary hub interface protected by parity • Up to 4 Gbyte PC1600 DDR SDRAM in 2 DIMMs • Streaming SIMD Extensions 2 • New microarchitecture supporting Micro-ops fusion, • One 10/100 Ethernet port on the front panel dedicated stack manager capabilities, and advanced – IEEE 802.3/802.3u instruction prediction capability – 100BaseTX • Includes real time endian conversion hardware for little- – IEEE 802.3x full-duplex flow control endian and big-endian data interfacing – 3 Kbyte TX/RX FIFO (patent no. 6,032,212) • Two 10/100/1000 Ethernet ports on the front panel • Intel E7501 chipset – IEEE 802.3 Ethernet interface for 1000BaseT, 100BaseTX, and 10BaseT applications (802.3ab, 802.3u, 802.3) – 16 Kbyte TX FIFO, 48 Kbyte RX FIFO – IEEE 802.3 Ethernet interface for 1000BaseT, 100BaseTX • Dual channel SCSI support – One Ultra320 SCSI channel available on front panel – One single-ended channel available through P2 backplane connector – Software RAID support (features continued on next page) ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer • One enhanced parallel port on the front panel Ordering Options – IEEE1284 – EPP 1.7/1.9 support Sept. 20, 2005 800-007810-000 J A B C D E F – ECP Level 2 support 0 0 VMIVME-7810 – • Two USB ports on the front panel A = Processor – USB Revision 1.1 compliant 0 = Reserved • Ultra DMA/100 IDE support out P2 rear panel connector 1 = 1.1 GHz Pentium M Processor • Up to 1 Gbyte CompactFlash 2 = 1.6 GHz Pentium M Processor 3 = 1.8 GHz Pentium M Processor • PS/2-style keyboard and mouse ports B = SDRAM Memory • Real time clock and miniature speaker 0 = Reserved • GE Fanuc Embedded Systems’ suite of real time support 1 = 512 Mbyte functions: 2 = 1 Gbyte 3 = 2 Gbyte – Two 32-bit programmable timers 4 = 4 Gbyte – Two 16-bit programmable timers C = CompactFlash – One programmable watchdog timer 0 = No CompactFlash – 32 Kbyte NVRAM 1 = 128 Mbyte CompactFlash 2 = 256 Mbyte CompactFlash • Passive heatsink solution 3 = 512 Mbyte CompactFlash ® • Operating system support for Windows 2000, Windows XP, 4 = 1 Gbyte CompactFlash ® ® Linux and VxWorks D = 0 (Option reserved for future use) E = 0 (Option reserved for future use) F = Special Sales Order Functional Characteristics 0 = VME Standard 1 = 1101.10 Front Panel Overview: The VMIVME-7810 brings the power of the Intel 2 = VME Standard with Conformal Coating Pentium M processor coupled with dual data rate (DDR) SDRAM 3 = 1101.10 Front Panel with Conformal Coating memory, Gigabit Ethernet and the high speed PCI-X internal bus Connector Adapters to provide the highest level of data processing and handling Adapter Length Part Number capabilities in a VME form factor. The two PMC expansion sites Micro-DB9 to Standard DB9 4 inches 360-010050-001 utilize the PCI-X bus to provide higher I/O bandwidth than Micro-DB25 to Standard DB25 4 inches 360-010051-000 previously available in a VME SBC. The higher speed PCI-X bus VMIACC-0045 Cable Kit contains: provides up to 1 Gbyte/s bandwidth to support faster I/O Qty. 2 – Micro-DB9 to Standard DB9, 4 inches Qty. 1 – Micro-DB25 to Standard DB25, 4 inches devices such as Fibre Channel, Gigabit Ethernet, SCSI, Reflective VMIACC-0562 VMEbus Rear Transition Utility Board ™ Memory and InfiniBand . The VMIACC-0562 installs in the rear transition area of the VMEbus Microprocessor: The VMIVME-7810 supports the Intel backplane. The VMIACC-0562 is sold separately. Pentium M processor. The Pentium M processor provides higher Note levels of performance in an Intel Architecture (IA-32) processor All VME single board computer products come standard with a VME through the use of 1 Mbyte L2 advanced transfer cache and a specification compliant front panel. new, redesigned microarchitecture. This new microarchitecture For Ordering Information, Call: features higher clock speeds, a 400 MHz system bus, micro-ops 1-800-322-3616 or 1-256-880-0444 • FAX (256) 882-0859 fusion, dedicated stack manager capabilities, and advanced Email: info.embeddedsystems@gefanuc.com instruction prediction capability. These features are Web Address: www.gefanuc.com/embedded incorporated specifically to increase performance and Copyright © 2005 by GE Fanuc Embedded Systems Specifications subject to change without notice. throughput while reducing power demands. These features are critical to providing increased processing power in power- limited environments like the VME. • Two 133/100/66 MHz PCI-X expansion sites • PMC rear I/O support (P2 connectors) The following list provides some of the key features on the • PCI graphics (32-bit/66 MHz) using ATI Mobility Radeon M6 Intel Pentium M processor: processor: • Supports Intel architecture with dynamic execution – 16 Mbyte internal SGRAM • High performance, low power core – Video resolutions up to 1600 x 1200 x 16 • On-die, primary 32 Kbyte instruction cache and 32 Kbyte – Front panel DVI-I connector providing analog video with write-back data cache digital flat panel support • On-die, 1 Mbyte level two cache with Advanced Transfer • Two high performance serial ports on the front panel Cache architecture – DTE RS232 support • Advanced branch prediction and data prefetch logic – 16550-compatible UART operates up to 1.5 Mbps • Streaming SIMD Extensions 2 (SSE2) Enhanced ESD protection • 400 MHz, source-synchronous processor system bus 2 ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer 400 MHz System Bus: The Intel Pentium M processor’s 400 MHz end-user productivity. The Intel E7501 chipset utilizes a modular processor system bus utilizes a split-transaction, deferred reply design and offers platform implementation flexibility to meet the protocol. The 400 MHz processor system bus uses source- expanding needs of high-end processors through three core synchronous transfer (SST) of address and data to improve components: The memory controller hub (MCH), the 64-bit performance by transferring data four times per bus clock PCI/PCI-X Controller Hub 2 (P64H2), and I/O controller hub 3-S (4x data transfer rate, as in AGP 4x). Along with the 4x data bus, (ICH3-S). the address bus can deliver addresses two times per bus clock Memory Controller Hub (MCH): The MCH is the central hub for and is referred to as a “double-clocked” or 2x address bus. all data passing through core system elements such as the Working together, the 4x data bus and 2x address bus provide a processor via the system bus interface, the memory via the data bus bandwidth of up to 3.2 Gbyte/s. memory interface, and both the 64-bit PCI/PCI-X and I/O Level 1 Execution Trace Cache: The Pentium M processor more controller hubs via Intel hub interfaces. The Intel E7501 chipset than doubles the L1 cache of previous Intel processors, offering delivers compelling performance at 3.2 Gbyte/s of bandwidth a 32 Kbyte data cache and a 32 Kbyte instruction cache. The across the 400 MHz system bus and up to 3.2 Gbyte/s of processor also features an advanced branch prediction bandwidth across two high performance double data rate architecture that significantly reduces the number of SDRAM memory channels. To balance the performance offered mispredicted branches. The result is a means to deliver a high by the processor and memory interfaces, the MCH allows volume of instructions to the processor's execution units. several high bandwidth I/O configuration options for a total of 3.2 Gbyte/s of I/O bandwidth. Level 2 Advanced Transfer Cache: The Pentium M processor offers 1 Mbyte L2 advanced transfer cache (ATC). The 64-bit PCI/PCI-X Controller Hub 2 (P64H2): The P64H2 connects processor’s data prefetch logic speculatively fetches data to the to the MCH through a point-to-point Hub Interface 2.0 L2 cache before an L1 cache requests occurs, resulting in connection. In the VMIVME-7810, three P64H2 devices are reduced bus cycle penalties and improved performance. attached to the MCH, each providing an I/O bandwidth greater than 1 Gbyte/s for a total of 3.2 Gbyte/s of I/O bandwidth. Each Higher Core Frequencies: The new Pentium M P64H2 contains two independent 64-bit PCI-X for a total of six microarchitecture allows for higher core frequencies, independent 64-bit PCI-X buses. The VMIVME-7810 uses these significantly increasing the performance and scalability of the PCI-X buses to provide the highest throughput available to the processor. built-in dual Gigabit Ethernet ports, SCSI controller and the two PMC sites. Streaming SIMD Extensions 2 (SSE2): With the introduction of ™ SSE2, the Intel NetBurst microarchitecture now extends the I/O Controller Hub 3-S (ICH3-S): The ICH3-S connects to the SIMD capabilities that MMX™ technology and SSE technology MCH through a point-to-point Hub Interface 1.5 connection. The delivered by adding 144 new instructions. These instructions ICH3-S provides legacy I/O interfaces through integrated include 128-bit SIMD integer arithmetic and 128-bit SIMD features including a two-channel Ultra ATA/100 bus master IDE double-precision floating-point operations. These new controller and three USB controllers. The ICH3-S also offers an instructions reduce the overall number of instructions required integrated System Manageability Bus 2.0 (SMBus 2.0) controller, to execute a particular program task and as a result can an integrated 10/100 ethernet controller and a PCI 2.2- contribute to an overall performance increase. They accelerate compliant interface. a broad range of applications including video, speech, image, photo processing, encryption, financial, engineering and DDR SDRAM: The VMIVME-7810 supports PC1600 registered scientific applications. dual data rate (DDR) SDRAM and can accommodate two low-profile (1.2 inches or less) 184-pin DIMMS that allow up to The processor maintains support for MMX technology and 4 Gbyte total memory. Data transfers to and from the SDRAM internet streaming SIMD instructions, and full compatibility with on every clock edge at a 200 MHz rate for an overall transfer IA-32 software. The high performance core features rate of 3.2 Gbyte/s. architectural innovations like micro-op fusion and advanced stack management that reduce the number of micro-ops 10/100 Ethernet Controller: The VMIVME-7810 has a single handled by the processor. This results in more efficient 10/100 Ethernet controller that is integrated into the E7501 scheduling and better performance at lower power. chipset’s I/O controller hub (ICH) and utilizes an RJ45 connector located on the front panel. The controller supports an interface The Streaming SIMD Extensions 2 enables break-through levels fully compliant with the IEEE 802.3/802.3u standard including of performance in multimedia applications including 3D the Auto-Negotiation (and 100BaseTX) standard and the IEEE graphics, video decoding/encoding, and speech recognition. The 802.3x full-duplex flow control standard. The controller features new packed double-precision floating-point instructions enhanced scatter-gather bus mastering capabilities which enhance performance for applications that require greater allows the LAN controller to perform high speed data transfers range and precision, including scientific and engineering over the PCI bus. The bus mastering capabilities enable the LAN applications and advanced 3D geometry techniques such as controller to process high level commands and perform multiple ray tracing. operations, thereby offloading communication tasks from the system processor. Two large transmit and receive FIFOs E7501 Chipset: The VMIVME-7810 uses the latest Intel E7501 (3 Kbyte each) are also included in the architecture to enhance chipset designed to deliver maximized system bus, memory and performance while minimizing the use of system resources. I/O bandwidth to enhance performance, scalability and 3 ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer 10/100/1000 Ethernet Controller: The VMIVME-7810 has a dual Table 1. Video Resolutions Supported 10/100/1000 Gigabit Ethernet controller. The dual Gigabit Screen Resolution Colors (bpp)* Refresh Rate (Hz) Ethernet controller is a discrete device connected to the chipset via a private PCI-X bus segment, allowing for maximum data 640 x 480 32 bpp 160, 120, 100, 90, 85, 75, 72, 60 transfer rates of 800 Mbyte/s between the processor and 800 x 600 32 bpp 160, 120, 100, 90, 85, 75, 72, 70, 60 Ethernet controller. The Gigabit Ethernet controller uses dual 1,024 x 768 32 bpp 120, 100, 90, 85, 75, 72, 70, 60 RJ45 connectors located on the front panel and provides an interface to the host processor by using on-chip command and 1,280 x 1,024 32 bpp 120, 100, 90, 85, 75, 70, 60 status registers and a shared host memory area. The 1,600 x 1,200 32 bpp 100, 85, 75, 60 controller's descriptor ring management architecture is *bpp = bits per pixel. optimized to deliver both high performance and PCI-X bus Digital Visual Interface (DVI): The VMIVME-7810 has a digital efficiency. Using hardware acceleration, the Ethernet controller visual interface (DVI) located on the front panel that provides can offload various tasks from the host processor, such as both a high speed digital video connection and legacy analog TCP/UDP/ IP checksum calculations and TCP segmentation. The (VGA) connection. DVI supports a single transition minimized Gigabit Ethernet controller caches up to 64 packet descriptors in differential signal (TMDS) link allowing for flat panel resolutions a single burst for efficient PCI-bandwidth usage while the large up to 1,600 x 1,200. DVI also supports the VESA display data 64 Kbyte on-chip packet buffer maintains superior performance channel (DDC) and extended display identification data (EDID) as available PCI bandwidth descriptors change. Fully integrated specification, which provide for varying display device physical layer circuitry provides a standard IEEE 802.3 Ethernet parameters such as timing, resolution and color depth to be interface for 1000BaseT, 100BaseTX, and 10BaseT applications accommodated. For legacy VGA support, an adapter is supplied (802.3ab, 802.3u, 802.3). to convert the DVI-I connector to a DB15HD female connector. Remote Ethernet Booting: The VMIVME-7810 utilizes the Argon Serial Ports: The VMIVME-7810 offers two RS232 serial ports Manage Boot BIOS that provides the ability to remotely boot the controlled by 16550-compatible UARTS. Each port has an VMIVME-7810 using PXE, NetWare, TCP/IP or RPL network independent 16-byte FIFO to support baud rates up to protocols. 115 Kbaud. The serial ports provide enhanced ESD protection Remote Ethernet Features: for: • PXE, NetWare, TCP/IP, RPL network protocol support ±15kV, human body model • Unparalleled boot sector virus protection ±8kV, IEC1000-4-2, contact discharge • Detailed boot configuration screens ±15kV, IEC1000-4-2, air-gap discharge • Comprehensive diagnostics The serial ports are accessible via two micro-DB9 male • Optional disabling of local boots connectors located on the front panel. An adapter is available to • Dual-boot option lets users select network or local booting adapt the micro-DB9 connector to a standard male DB9 Dual Channel Ultra320 SCSI: A PCI-X Ultra320 SCSI controller connector (GE Fanuc Embedded Systems P/N 360-010050-001). provides two independent SCSI channels. One channel is CompactFlash: The VMIVME-7810 includes a CompactFlash capable of data transfers at up to 320 Mbyte/s and is accessed socket on the assembly. The CompactFlash can be configured via a front panel connector. For applications requiring as the boot device through the BIOS boot device set up. The connection through the backplane, the second channel is CompactFlash, as an ordering option, is available up to 1 Gbyte routed through user-defined pins on the VMEbus P2 connector of storage space. and supports single-ended SCSI-2. Parallel Port: The VMIVME-7810 offers a single enhanced “PCI-X on PMC” Expansion Sites: The VMIVME-7810 is the parallel port. The parallel port is IEEE1284 compliant and industry’s first VMEbus board to incorporate PMC expansion supports EPP 1.7/1.9 and ECP Level 2 standards. The parallel sites that support the PCI-X bus. Each PMC site is on a private port is accessible via a micro-DB25 connector located on the PCI-X bus segment allowing maximum data transfer rates of front panel. An adapter is available to adapt the micro-DB25 1 Gbyte/s between the processors and the PMC device. Each connector to a standard DB25 female connector PMC site is fully backward compatible with legacy 32-bit/33 (GE Fanuc Embedded Systems P/N 360-010051-000). MHz and 64-bit/66 MHz PMCs with 5V/3V signaling. USB Port: The VMIVME-7810 offers two USB ports compliant Super VGA Controller: The VMIVME-7810 offers an integrated with the USB 1.1 specification. The USB ports are accessible via high performance 3D super VGA (SVGA) controller, the ATI USB connectors located on the front panel. mobility radeon, that supports high-resolution graphics and multimedia quality video with 16 Mbyte of SGRAM. The SVGA Keyboard/Mouse Ports: The VMIVME-7810 supports a standard controller is on a private 66 MHz PCI bus allowing for maximum PS/2 keyboard and mouse. The keyboard and mouse ports are data transfer rates of 264 Mbyte/s. Video resolutions supported accessible via two 6-pin mini DIN connectors located on the by the graphics adapter are shown in the following table. front panel. Programmable Timer: The VMIVME-7810 provides the user with two 16-bit timers and two 32-bit timers. These timers are 4 ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer mapped in PCI memory space, are completely software All error processing VMEbus-related interrupts can be mapped programmable, and can generate PCI interrupts. to PCI INTA# or SERR#. Note: PCI SERR# initiates an SBC NMI. These include: Watchdog Timer: The VMIVME-7810 provides a software- programmable watchdog timer. The watchdog timer is enabled ACFAIL* interrupt under software control. Once the timer is enabled, software BERR* interrupt must access the timer within the specified time period, or the SYSFAIL* interrupt output of the watchdog timer will reset the VMIVME-7810. The interrupt handler has a corresponding STATUS/ID register Nonvolatile SRAM: The VMIVME-7810 provides 32 Kbyte of for each IRQ* interrupt. Once the handler receives an IRQ*, it nonvolatile SRAM. The contents of the SRAM are preserved when requests the VMEbus and, once granted, it performs an IACK power is interrupted or removed from the unit. cycle for that level. Once the IACK cycle is complete and the STATUS/ID is stored in the corresponding ID register, an Reset Switch and Annunciators: A push-button switch located appropriate interrupt status bit is set in an internal status on the front panel is used to reset the VMIVME-7810. Indicators register and a PCI interrupt is generated. The PCI interrupt can on the front panel include: Attention (Red), Power/Reset (Green), be mapped to PCI INTA# or SERR#. IDE Activity (Yellow), VMEbus SYSFAIL (Red), LAN activity and LAN link speed. Interrupter: Interrupts can be issued under software control on any or all of the seven VMEbus interrupt lines (IRQ7* to IRQ1*). A VMEbus Interface: The VMIVME-7810 VMEbus interface is based common ID register is associated with all interrupt lines. During on the Universe IID high performance PCI-to-VMEbus interface the interrupt acknowledge cycle, the interrupter issues the ID to from Tundra. The following VME64 modes are supported: the interrupt handler. A32/A24/D32/D16/D08(EO)/MBLT64/BLT32. The interrupter can be programmed to generate a PCI INTA# or System Controller: The VMEbus system controller capabilities SERR# interrupt when a VMEbus interrupt handler allow the board to operate as a slot 1 controller, or it may be acknowledges a software-generated VMEbus interrupt. disabled when another board is acting as the system controller. The system controller may be programmed to provide the Byte Swapping: The Intel 80x86 family of processors uses little- following modes of arbitration: endian format. To accommodate other VMEbus modules that transfer data in big-endian format (such as the 680x0 processor Round Robin (RRS) family), the VMIVME-7810 incorporates byte-swapping Single Level (SGL) hardware. This provides independent byte swapping for both Priority (PRI) the master and slave interfaces. Both master and slave interface byte swapping are under software control. The system controller provides a SYSCLK driver, IACK* daisy- chain driver, and a VMEbus access timeout timer. The system The VMIVME-7810 supports high throughput DMA transfers of controller also provides an arbitration timeout if BBSY* is not bytes, words and longwords in both master and slave seen within a specified period after a BGOUT* signal is issued. configurations. This period is programmable for 16 or 256 µs. If endian conversion is not needed, we offer a special “bypass” VMEbus Requester: The microprocessor can request and gain mode that can be used to further enhance throughput. control of the bus using any of the VMEbus request lines (Not available for byte transfers.) (BR3* to BR0*) under software control. The requester can be programmed to operate in any of the following modes: Master Interface: MA32:MBLT32:MBLT64 (A32:A24:A16:D32:D16:D8 (EO):BLT32) Release-On-Request (ROR) Release-When-Done (RWD) The VMEbus master interface provides nine separate memory VMEbus Capture and Hold (VCAP) windows into VMEbus resources. Each window has separate configuration registers for mapping PCI transfers to the VMEbus Mailboxes: The VMEbus interface provides four 32-bit (that is, PCI base address, window size, VMEbus base address, mailboxes, which are accessible from both the microprocessor VMEbus access type, VMEbus address/data size, etc.). The and the VMEbus, providing interprocessor communication. The maximum/minimum window sizes for the nine windows are as mailboxes have the ability to interrupt the microprocessor when follows: accessed by VMEbus. Window Minimum Size Maximum Size Interrupt Handler: The interrupt handler monitors, and can be 0, 4 4 Kbyte 4 Gbyte 1 to 3, 5 to 7 64 Kbyte 4 Gbyte programmed to respond to any or all VMEbus IRQ* lines. All Special Cycle 64 Mbyte 64 Mbyte normal-process VMEbus-related interrupts can be mapped to PCI INTA# or SERR# interrupts. These include: Slave Interface: Memory Access : Mailbox interrupts SAD032:SD32:SBLT32:SBLT64 VMEbus interrupts (A32:A24:A16:D32:D16:D8 (EO): BLT32) VMEbus interrupter IACK cycle (acknowledgment of VMIVME-7810 VMEbus-issued interrupts) The VMEbus slave interface provides eight separate memory windows into PCI resources. Each window has separate 5 ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer configuration registers for mapping VMEbus transfers to the PCI PMC Expansion Site Connector: 3.3V signaling, auto-VIO bus (that is, VMEbus base address, window size, PCI base 64-bit PCI-X bus, 133 MHz maximum address, VMEbus access type, VMEbus address/data size, etc.). (Backward compatible to 3V 33 MHz PCI) The maximum/minimum window sizes for the eight windows PMC Rear I/O Support: via the P2 connectors are as follows: Airflow: Heatsink with forced air cooling required: 400 LFM Window Minimum Size Maximum Size 0, 4 4 Kbyte 4 Gbyte minimum 1 to 3, 5 to 7 64 Kbyte 4 Gbyte Temperature: Operating: 0 to +50° C In addition, each window can be programmed to operate in Storage: -40 to +80° C coupled or decoupled mode. In decoupled mode, the window Altitude: utilizes a write-posting FIFO and/or a read prefetching FIFO for Operating: 0 – 10,000 ft (3,000m) increased system performance. In coupled mode, the FIFOs are Storage: 0 – 40,000 ft (12,000m) bypassed and VMEbus transactions are directly coupled to the PCI bus (that is, transfers on VMEbus are not completed until Humidity: they are completed on the PCI bus). Operating: relative humidity 10% to 90%, noncondensing Storage: relative humidity 10% to 90%, noncondensing Enhanced Bus Error Handling: Enhancements over the Universe chip’s bus error handling features are provided. A latch MTBF: 165,000 hours and register are provided to allow the SBC to read the VMEbus address that caused the bus error in all modes. The Universe chip’s support is limited to decoupled mode. Support for bus Trademarks cycle timeout and assertion of bus error is provided. The board MMX and NetBurst are trademarks and Intel and Pentium are may be configured to assert bus error upon timeout regardless registered trademarks of Intel Corporation. Microsoft and of its status as system controller. The Universe chip asserts bus Windows are registered trademarks of Microsoft Corporation. error only if it is system controller. In addition, this board may be Other registered trademarks are the property of their respective configured to assert an interrupt upon bus cycle timeout. owners. Operating System and Software Support The VMIVME-7810 supports a variety of operating systems ® including Microsoft Windows 2000, Windows XP, Linux and VxWorks Tornado/AE BSPs. The BSP provides support for the VMEbus interface, Ethernet and timers. Physical/Environmental Specifications Dimensions: 6U (8HP) dual slot Eurocard form factor Height 9.2 in. (233.4mm) Depth 6.3 in. (160mm) Thickness 0.8 in. (20.3mm) Power Requirements: +5VDC (±5 percent), 12A (typical), 14A maximum +12VDC (±5 percent), 10mA (typical), 25mA maximum -12VDC (±5 percent), 0mA (typical), 8mA maximum Note: Installing PMCs may increase one, or all, of the current requirements. No PMC boards were installed during power measurements. Power measurements were made running PassMark Software’s BurnIn Test ver. 4.0 which exercises the processor, chipset, memory bus, video chip, SCSI, USB, serial/parallel ports, and disk drives. For this product, the +12V and -12V supplies are not used to power any on-board devices and only go to the two PMC sites and the GE Fanuc Embedded Systems PCI expansion connector. The currents at +12 and -12VDC are specified with the serial connectors open. 6 ® ® VME-7810 Intel Pentium M Processor-Based VME Single Board Computer Figure 1. VMIVME-7810 Block Diagram GE Fanuc Embedded Systems Information Centers Additional Resources Americas: For more information, please visit the Huntsville, AL 1 800 322-3616 GE Fanuc Embedded Systems web site at: 1 (256) 880-0444 www.gefanuc.com/embedded Camarillo, CA 1 (805) 987-9300 Greenville, SC 1 (864) 627-8800 Richardson, TX 1 (972) 671-1972 Europe, Middle East and Africa: Edinburgh, UK 44 (131) 561-3520 Paris, France 33 (1) 4324 6007 7