MVME8100/MVME8105/MVME8110 Installation and Use
Contents
1. 109 Table 4 3 GPIO Pull Down Characteristics 109 Table 5 1 MVME8100 MVME8105 MVMES1 10Specific U Boot Commands 115 Table B 1 Artesyn Embedded Technologies Embedded Computing Publications 121 Table B 2 Related Specifications uuu RR EP meer 121 Table B 3 Manufacturer s Publications 123 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 7 List of Tables me 8 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K List of Figures _ Figure 1 1 Declaration of Conformity of MVME8100 38 Figure 1 2 Declaration of Conformity of MVME8105 39 Figure 1 3 Declaration of Conformity of MVME8110 40 Figure 2 1 Switch Locations ENP1 49 Figure 2 2 Switch Locations ENP4 Board 49 Figure 2 3 Typical Placement of aPMC XMC Module on a VME Module 54 Figure 2 4 SATA drive Installation 56 Figure 3 1 ENP1 Board Connectors LEDs Switches 61 Figure 3 2 ENP4 LEDs and Switches 62 Figure 3 3 ENP1 Board2. 50 2 42 PMC XMC Installation 51 2 4 3 SATAllnstall tion su a ae 54 2 5 Installing and Removing the 57 2 6 Completing the Installation 59 3 Connectors LEDS and Switches 61 Sel CONNECTORS 64 3 1 4 External Connectors 64 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K 3 Contents 3 1 1 1 Front Panel Connectors 64 3 1 1 2 Backplane Connectors 66 3 1 2 On Board Connectors n eese eek ER 71 3 2 LEDS ei 80 3 2 1 On board BEDS u u lere e a ee laser 81 3 3 SSWIECHIeS 81 3 3 1 Configuration Switches 2 82 1 1 252 I uu Rr 82 3 3 1 2 53 SWIER 255 2606 ees ae AN ea 83 33 13 SASWIECh nen ee Sr Lake lee 85 3 3 1 4 S5 Switcli esse 85 3 3 1 5 Reset Abort Switch 86 4 Functional Description 0 en 87 4 1 Block Diagram en eher ES 88 4
3. PMCIO 64 DATA 31 GND 5V PMCIO 63 Table 3 6 VXS P0 Connector applicable to MVME8100 only 5V GND Row Row E Row D Row C Row B P1_TX1_N P1_TX1_P P1 GND GND PI_RXO_N P1_RXO_P GND P1_RX1_N P1_RX1_P NC GND P1_TX2_N P1 PI 2 P1_RX2_P 2 3 4 GND P1 TX3 PI_TX3_P P1 RX3 P GND N GND N C 1 5 6 GND 7 GPIOO 70 GND SG TXO N SG RXO P MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Connectors LEDs and Switches Table 3 6 VXS PO Connector applicable to MVME8100 only continued Pin RowG 9 GPIO1 GND NC Row Row Row D Row C Row B Row GND SATA TX SATA TX P GND SATA SATA P SG TX1 _TX1_ SG_RX1_P P2_TXO_N P2 P2 RXO N P2 RXO P GND GND P2 TX1 _TX1_ GND P2_RX1_N P2 RXI P2_TX2_N P2_TX2_P P2_RX2_N P2_RX2_P GND 3 1 2 On Board Connectors The on board customized SATA connector is compatible with the MVME8100 SATA kit Following are the onboard connectors SATA connector PMC connector Asset Joint Test Access Group connector Common On chip Connector COP connector XMC connector SATA Connector The on board customized SATA connector is compatible with the Artesyn Embedded Technologies SATA kit MVME8100 HDMTKIT4 Table 3 7 Customized SATA Connector 3
4. Description Description SATA POWER ENABLE MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 71 Connectors LEDs and Switches Table 3 7 Customized SATA Connector J3 continued Pin Name Description Pin Name u Description PMC Connectors The MVME8100 MVME8105 MVMES81 10 supports two sites The connector is located on the middle portion of the board It utilizes 14 to support PMCI O that goes to RTM PMC Table 3 8 PMC J11 J21 Connector Pin Name Signal Description Pin Name Signal Description 1 JTAG TCK 33 FRAME 2 12V 34 GND 72 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Connectors LEDs and Switches Table 3 8 PMC J11 J21 Connector continued PinName Signal Description GND INTA Pin Name Signal Description z 36 IRDY 5V 37 DEVSEL 38 PRESENT SIGNAL 39 PCIXCAP 5V LOCK 3 4 5 6 INTC 7 8 9 3 3 PCI CLK GND GND MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 73 Connectors LEDs and Switches Table 3 8 PMC J11 J21 Connector continued PinName Signal Description Pin Name Signal Description Table 3 9 PMC J12 J22 Connector Pin Name Signal Description Pin Name Signal Description 1 12V 33 GND 2 JTAG TRST 34 IDSELB
5. mmc MMC sub system Display MMC info Reset nvram serial and write monitor to SPI flash mtest Simple RAM read write test mw Memory write fill nfs Boot image through network using NFS protocol nm Memory modify constant address pei List and access PCI Configuration Space pci_info Show information about devices on PCI bus 116 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800 25 Boot System Table 5 1 MVME8100 MVME8 105 MVME81 10Specific U Boot Commands continued Command Description Send ICMP ECHO_REQUEST to network host Boot image through network using RARP TFTP protocol reset Perform RESET of the CPU run Run commands in an environment variable saveenv Save environment variables to persistent storage script Run a delimited terminated list of commands setenv Set environment variables setexpr Set environment variable as the result of eval expression sf SPI flash sub system showvar Print local hushshell variables sleep Delay execution for some time Soft reset the board source Run script from memory test Minimal test like bin sh tftpboot Boot image through network using TFTP protocol tsil48 Initialize and configure Tundra Tsi148 version Print monitor version 5 4 Updating U Boot To update the U Boot place the image in the RAM address 0x1000000 in this example before copying it to the SPI flash MVME8100 MVME8105 MV
6. Marketing Processor MVME8110 01E P5010 1 2GHZ 2GB DDR3 2PMC XMC ENP1 IEEE MVME8110 01S P5010 1 2GHZ 2GB DDR3 2PMC XMC ENP1 SCANBE 1 4 2 Board Accessories This table lists the available expansion and transition modules for the MVME8100 MVME8105 MVME8110 Model Number Description VXS1 RTM1 RTM for MVME8100 supports ENP1 specifications only MVME8100 HDMTKIT4 SSD Mounting kit HDD not included MVME8110 RTM RTM FOR THE MVME8105 MVME8110 MVME8100 HDMTKIT4 CC MVME8100 HARD DRIVE MOUNTING KIT ENP1 AND 4 CONF COAT HDD not included 42 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Chapter 2 Hardware Preparation and Installation EM 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 XMC and Rear Transition Module RTM are also described in this chapter A fully implemented MVME8100 MVME8105 MVME81 10 consists of the baseboard plus Two single wide or one double wide PCI Mezzanine Card PMC slot for added versatility One rear transition module for support of the mapped from the 8100 8105 81 10 baseboard to the P2 connector Up to two optional XMC cards in place of PMC modules Following are the steps to be performed before using the board Be sure to read the entire c
7. TSEC Three Speed Ethernet Controller 2 55 Two edge Source Synchronous Transfer UART VITA VME VPD Universal Asynchronous Receiver Transmitter VMEbus International Trade Association VMEbus Versa Module Eurocard Vital Product Data XMC PCI Express Mezzanine Card MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 13 About this Manual Conventions The following table describes the conventions used throughout this manual Notation Description 0x00000000 Typical notation for hexadecimal numbers digits are O through F for example used for addresses and offsets 0 0000 Same for binary numbers digits are 0 and 1 bold Screen Courier Bold Used to emphasize a word Used for on screen output and code related elements or commands in body text Used to characterize user input and to separate it from system output Reference Used for references and for table and figure descriptions File gt Exit Notation for selecting a submenu text Notation for variables and keys Notation for software buttons to click on the screen and parameter description Repeated item for example node 1 node 2 node 12 Omission of information from example command that is not necessary at the time being Ranges for example 0 4 means one of the integers 0 1 2 3 and 4 used in registers 14 Logical OR MVME8100 MVME8105 MVME8110
8. interface 0 1 device 0 partition 1 fatload mmc 0 1 1000000 File_ulmage fatload mmc 0 1 2000000 File ramdisk fatload mmc 0 1 00000 File_dtb 5 Bootthe Linux in memory bootm 1000000 2000000 00000 5 2 5 Booting VxWorks Through the Network In this mode the U Boot downloads and boots VxWorks from an external TFTP server 1 Make sure that the VxWorks image is accessible by the board from the TFTP server 2 Configure U Boot environment variables setenv ipaddr lt IP address of MVME8100 MVME8105 MVME8110 gt setenv serverip lt IP address of TFTP server gt setenv gatewayip lt gateway IP gt setenv netmask lt netmask gt setenv vxboot tftpboot vxbootfile amp amp setenv bootargs Svxbootargs amp amp bootvx setenv vxbootfile lt VxWorks_image gt setenv vxbootargs dtsec 3 0 lt IP address of TFTP server gt VxWorks h lt IP address of TFTP server gt e lt IP address of MVME8100 MVME8105 MVME8110 gt ffffff00 b lt unused IP u vxworks pw vxworks f 0x80 saveenv 114 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K 5 3 Boot System 3 TFTP the files from the server to local memory then boot run vxboot MVME8100 MVME8105 MVME8110 Specific U Boot Commands Table 5 1 MVME8100 MVMES 105 MVMES 1 10Specific U Boot Commands base Print or set address offset bdinfo Print board info structure Boot default i e run bootcmd Boot default i e run bootcmd Boot from
9. 56 Figure 2 4 SATA drive Installation REMOVE PMC BRACKET Mounting Posts I STEP 1 V STEP 2 ASSEMBLE FOUR MTG SCREWS FROM SIDE 2 OF THE BOARD STEP 3 STEP 6 Use the following steps to install a SATA drive 1 Wear an ESD strap to your wrist and fix the other end of the ESD strap to an electrical ground Secure mounting brackets to each side of SATA drive as shown in step 1 of Figure 2 4 Attach SATA adapter board to SATA drive as shown in step 2 of Figure 2 4 Use two screws to secure adapter to mounting brackets as shown in step 3 of Figure 2 4 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Hardware Preparation and Installation 2 5 5 Remove PMC XMC bracket and mounting posts from site 2 as shown in step 4of Figure 2 4 6 Attach SATA drive assembly with adapter board and mounting brackets to the board at site 2 as shown in step 5 of Figure 2 4 Make sure that the SATA adapter connector is fully mated with the board SATA connector 7 Secure SATA drive assembly to board using four screws inserted from the bottom side of the board as shown in step 5 of Figure 2 4 Installing and Removing the Board This section describes the recommended procedure for installing the MVME8100 MVME8105 MVMES1 10 board in a chassis The MVME8100 MVMES8105 MVME81 10 does not support hot swap you must remove power to the slot or system bef
10. 7151148 SW LSRSTI N VME Bus PURST_N gt VSYSRESETIN lt LRSTO N Bridge From VME Bu PCIE PERST BRR N gt 151384 PWR_V1P8_PWRGD gt PWR_V1P2_PWRGD gt CPLD PCIE PERST BR2 N 9 151384 L PWR V3P3 PWRGD PWR V2P5 PWRGD LATTICE r PWRGD LCMXO2280C PCIE PERSTBRS 191394 PWR V1P1 PWRGD H PWR_V1P0_IDT_PWRGD gt PCIE PERST SATA N 3 9 88SE 91255 L PWR_V1P2_SW_PWRGD gt PWR V1P5_ PWRGB gt PWR_VTT_ PWRGB gt PCIESWI_PERST_N 32NT 24 PCIe SW Power Supply CLK 25MHZ RST N 1 583905 Units lt PWR V1P8 4 PWR V1P2_EN CLK MN_RST ICS840S07 lt PWR V3P3 PWR V2P5 EN gt 1CS841664 PWR PWR V1P1 lt PWR V1P0 EN CPU PWR V1P2 SW PORESET N _ gt lt PWR V1P5 S3 EN CPU HRESET N gt FREESCALE lt V1P5 55 CPU RESET REQ N P5020 P5010 PWR V3P3 MISC EN P2 BPSWITCH N 4 a Connector MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 107 Functional Description 4 22 Interrupt Controller Assignments The followin
11. Attach the other end of the strap to the chassis as a ground Make sure that it is securely fastened throughout the procedure 2 If the PMC XMC has a front filler panel remove the PMC XMC filler plate from the front panel cut out 3 Remove the two rear stand offs from the PMC XMC The MVME8100 MVME8105 MVMES1 10 heat frame has built in rear stand offs MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Hardware Preparation and Installation 4 Slide the front bezel of the PMC XMC into the cut out from behind The front bezel ofthe PMC XMC module will be flushed with the board when the connectors on the module align with the mating connectors on the board Note ENP4 PMC XMC modules do not have front bezels 5 Alignthe mating connectors properly and apply minimal pressure to the PMC XMC until it is seated to the board 6 Insert the two front PMC XMC mounting screws through the mounting holes on the bottom side of the board and then install the top side screws Tighten the screws Note Rugged PMC XMC modules installed on MVME8100 have more than four mounting screws 7 Install the board into the appropriate card slot Make sure that the board is well seated into the backplane connectors Do not damage or bend connector pins MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 53 Hardware Preparation and Installation 8 Replace the chassis or system cover 9 Reconnect the system to th
12. ON 001011 OFF ON OFF ON OFF 101010 84 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Connectors LEDs and Switches 3 3 1 3 54 Switch The 54 switch includes the SCON control and PCIE SRIO PO root complex endpoint configuration switches for MVME8100 The S4 switch of MVME8105 MVME8110 includes SCON control only The SCON AUTO 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 The VME SCON SEL switch is OFF to manually select SCON mode This switch is ON to manually select non SYSCON mode This switch is only effective when the VME SCON AUTO switch is ON Table 3 19 S4 Switch Settings Position Default Description 1 OFF Clear Environment Variables 2 OFF 3 OFF 4 OFF 3 3 1 4 S5 Switch The switch Bank S5 provides the boot SPI FLASH selection OFF Disable Clear Environment Variables ON Enable Clear Environment Variables At reset uboot ENV variables are set to default values OFF Configure PCle SRlo Switches as PO Root Complex applicable to MVME8100 only ON Configure PCle SRIO Switches as PO Endpoint applicable to MVME8100 only OFF Auto VME System Controller ON Manual VME System Controller OFF VME System Controller ON VME Non System Controller Table 3 20 S5 Switch Settings Position Default Descripti
13. 10 100 1000BASE T Ethernet channels to P2 RTM 32 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Introduction Serial Ports RS232 422 485 console port to front panel or P2 RTM Upto4RS232 422 485 COM ports to P2 VME Bus VME64x and 2 55 e Timers Eight 32 bit timers in CPU Watchdogtimer in CPU PMC XMC Two PMC XMC sites with 64 bit PMCIO on Site 1 Serial AT Attachment SATA SSD Option for 2 5 inch SATA drive PMC XMC Site 2 e GPIO Interface Two GPIOs to RTM VXSInterface VXS VITA 41 Specification compliant Support backplane PO connector e Form Factor Standard 6U one slot Support 0 8 and 0 85 inch slot chassis Support heat frame on both sides for Conduction cooled board e Miscellaneous One front panel RESET Switch LED front panel status indicators four user fail ready LEDs Planar status indicators Boundary scan support The main features of the MVME8110 board as follows Processor Subset of P5010 features used on MVME8110 Freescale QorlQ P5010 1 2Ghz 15W TDP Onee500mc64 core 512kB L2 cache MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 33 Introduction 1 Mbyte CoreNet platform cache with ECC DDR3 memory controller max 1333MT s data rate 1200MT s for 1 2GHz SKU 4x PCle 2 0 controllers 1xSATA 2 0 controller 2xUSB 2 0 controllers with integrated PHYs 5 GbE controllers SGMII RGMII
14. 1x 10GbE controller SD MMC eMMC controller Local bus controller controller 4 CS 2x12C controllers Dual UART RAID5 6 engine not present Programmable interrupt controller System Memory Up to AGB Single Channel DDR3 1333 memory with ECC e SMBus One512Kbituser configuration serial EEPROM 256BSPD EEPROMs One64Kbit VPD EEPROM RiICwith battery backup Temperature Sensors XMC VPD EERPOMs 34 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Introduction e FLASH Two soldered SPI FLASH 8MB each switchable for uboot primary backup support Hardware switch or Software bit write protection for entire logical bank Eight GB eMMC Flash NVRAM 512 KB MRAM e PCI Express One 8X Port to PMC XMC Site 1 One 4X Port to PMC XMC Site 2 USB USB 2 0 for front panel I O Two USBs 2 0 for backplane RTM I O Ethernet 10 100 1000BASE T Ethernet port to front panel only in air cooled variant Two 10 100 1000BASE T Ethernet channels to P2 RTM SerialPorts RS232 422 485 console port to front panel Upto 4RS232 422 485 COM ports to P2 RTM VME Bus VME64x and 2eSST Timers Eight 32 bit timers in CPU Watchdog timer in CPU PMC XMC Two PMC XMC sites with 64 bit PMCIO on Site 1 SSD Option for 2 5 inch SATA drive PMC XMC Site 2 CPIO Interface Two GPIOs to RTM MVME8100 MVME8105 MVM
15. 7 Simultaneously move the injector ejector levers if equipped an inward direction until locked If fitted with SCANBE ejectors adjust them inward and apply pressure to them to seat the board 8 Verify that the board is properly installed and secure it to the chassis using the two screws located adjacent to the injector ejector levers 9 When installing an version board the maximum torque that should be used on the wedge lock screws is 6 in Ibs 10 Connect the appropriate cables to the board When the MVME8100 MVME8105 MVME8110 and optionally an RTM is installed in a chassis you are ready to connect peripherals and apply power to the slot or system The front panel Micro DB9 connector provides a console interface to U boot It presents an RS 232 DTE interface TX RX CTS RTS The default serial configuration is 9600 8 N 1 This mates with an ITT MDSM 9SCZ1 1 or equivalent The Artesyn Embedded Technologies part number SERIAL MINI D2 converts this to a standard male DB9 interface MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Hardware Preparation and Installation 2 6 Removal Procedure 1 Turn off the power 2 Disconnect all the cables 3 Pressthe locking tabs IEEE handles only to eject the board 4 Loosen and remove the screws adjacent to the injector ejector levers that securing the module to the chassis a Move the injector ejector levers in outward direction 6 Hold t
16. C gt keys U Boot aborts the boot sequence and enters into a command line interface mode YE Enterthe command setenv bootdelay 1 saveenvto disable the U Boot auto boot WON feature and let the U Boot directly enter the command line interface after the next reboot power up 5 2 Boot Options 5 2 1 Booting from Network In this mode U Boot downloads and boots the Linux kernel from an external TFTP server and mounts a root file system located on a network server 1 Make sure thatthe kernel dtb and ramdisk are accessible to the board from the TFTP server 2 Configure U Boot environment variables setenv ipaddr lt IP address of MVME8100 MVME8110 gt setenv serverip lt IP address of TFTP server gt setenv gatewayip lt gateway IP gt setenv netmask lt netmask gt setenv bootargs root dev ram rw console ttyS0 9600n8 ramdisk_size 700000 cache sram size 0x10000 saveenv 3 Transfer the files through the TFTP from the server to the local memory tftp 1000000 lt kernel_image gt tftp 2000000 lt ramdisk gt tftp 00000 lt kernel dtb gt 4 Bootthe Linux from the memory bootm 1000000 2000000 00000 112 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Boot System 5 2 2 Booting from an Optional SATA Drive 1 Makesurethatthekernel dtb andramdisk are saved in the SATA drive with ext2 partition 2 Configure U Boot environment variable setenv File_ulmage lt kernel_image gt setenv
17. Current Vy lt Viy lt Vi Max Thermal Management The MVME8100 MVME8105 MVMES1 10 provides three on board temperature sensors using an ADT7461 dual temperature sensor and a TMP112A temperature sensor The ADT7461 internal temperature sensor provides the temperature atthe board edge on the CPU side ofthe board The ADT7461 remote temperature sensor measures the CPU temperature The ADT7461 can measure negative temperatures down to 64C with 1C accuracy on the remote sensor and accuracy on the internal sensor The ADT7461 registers can be used to configure the low temperature limit and high temperature limit for the local sensor as well as for the remote sensor An interrupt can be generated if limits are exceeded The TMP112A temperature sensor is used to measure the temperature at the board edge opposite from the CPU Since the airflow direction can be different in some VME chassis either temperature sensor can be used to get a measure of the board inlet air temperature depending on the air flow direction MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 109 Functional Description eee However to maintain proper CPU temperature the recommended airflow direction is to enter the board from the CPU side that is the air should flow in the direction from PMC XMC site 1 to PMC XMC Site 2 Figure 4 10 Thermal Management USER 1 LED Console Port Micro DB9 Reset Switch Board FAIL LED Rec
18. File_dtb lt kernel dtb gt setenv File_ramdisk lt ramdisk gt saveenv 3 Copy the files from the SATA drive to the memory option scsi interface 0 1 device 0 partition 1 ext2load scsi 0 1 1000000 File_ulmage ext2load scsi 0 1 2000000 SFile ramdisk ext2load scsi 0 1 00000 SFile dtb 4 Bootthe Linux in memory bootm 1000000 2000000 00000 5 2 3 Booting from a USB Drive 1 sure that the kernel dtb and ramdisk are saved in the USB drive with FAT partition 2 Configure the U Boot environment variable setenv File ulImage kernel image setenv File dtb kernel dtb gt setenv File ramdisk lt ramdisk gt saveenv 3 Initialize USB drive usb start 4 Load the files from the USB drive to the memory option usb interface 0 1 device 0 partition 1 fatload usb 0 1 1000000 File uImage fatload usb 0 1 2000000 File_ramdisk fatload usb 0 1 File_dtb 5 Bootthe Linux in memory bootm 1000000 2000000 00000 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800 25 113 Boot System 5 2 4 Booting from eMMC 1 Makesurethatthekernel dtb and ramdisk are saved inthe onboard eMMC device with FAT partition 2 Configure the U Boot environment variable setenv File_ulmage lt kernel_image gt setenv File_dtb lt kernel dtb gt setenv File_ramdisk lt ramdisk gt saveenv 3 Initialize eMMC mmcinfo 4 Loadthe files from the eMMC to the memory option mmc
19. JA 64 Table 3 3 USB Connector 6 2 2 2 rr re eeeeeg rere se arena 65 Table 3 4 zen T E 66 Table 3 5 PA CONMECLORS ua ee ie Vato eons ee ine 68 Table 3 6 VXS PO Connector applicable to MVME8100 only 70 Table 3 7 Customized SATA Connector J3 71 Table 3 8 PMCJ11 21 n e Ehre eR ee 72 Table 3 9 PMCJ12 22 Connector rede eher erbe T 74 Table 3 10 PMCJ13 J23 Connectors 75 Table 3 11 Connector erreichte ee a a ed 76 Table 3 12 Asset JTAG Header Pin Assignment P12 78 Table 3 13 XMC Connectors ee eds aa 79 Table 3 14 FrontPanel LEDS ere dla fale q nitet ee x Rn Rb E ee D 80 Table 3 15 On board LEDs Stat s 22H Bes a me ER PRA 81 Table 3 16 S2 Switch Settings oem itte ee 82 Table 3 17 S3 Switch Settings Pee RR nee 83 Table 3 18 Three Row Backplane Manual Slot Addressing 84 Table 3 19 S4 Switch Settings ceu nee TREE RI I UE REPAIR CUR D edad 85 Table 3 20 55 Switch Settings 22 ee UR Rr en 85 Table 4 1 P5020 P5010 External Interrupt Assignments 108 Table 4 2 GPIO DC Electrical Characteristics
20. P2 RTM two with micro DB9 connectors RTM panel and two on planar headers Two 10 100 1000BASE T Ethernet channels to RJ45 connectors on RTM panel Two 1000 BASE BX Ethernet SERDES channels to backplane Two USB2 0 ports to RTM with USB type A connectors on RTM panel SATA port to RTM with eSATA connector on RTM Two GPIOs to planar headers on RTM Note The front panel I O connectors are available only in ENP1 air cooled variants I O signals in ENP4 conduction cooled variant are accessed through P2 only The main features of the MVME8105 are as follows Processor Subset of P5020 features used on MVME8100 Freescale QorlQ P5020 Two e5500 Power Architecture cores Five Gigabit Ethernet controllers Serial Gigabit Media Independent Interface SGMII and Reduced Gigabit Media Independent Interface RGMII interfaces MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Introduction e Software Support VxWorks OS support Linux OS supports 32 bit e RTM Compatible with RTM assembly 0106852 micro DB9 connector for console port on front panel Two front panel 5 connector with integrated LEDs for 10 100 1000 Ethernet channel PMC XNC site 1 front and rear PMC I O PMC XNC site two front Four Serial ports to P2 RTM two with micro DB9 connectors RTM panel and two on planar headers 10 100 1000 Ethernet channel
21. Requirements legal EN 60950 1 IEC 60950 1 CAN CSA C22 2 No 60950 1 CISPR 22 EMC requirements legal on system level predefined Artesyn EN 55022 Embedded Technologies system EN 55024 FCC Class A VCCI Japan AS NZS CISPR 22 Environmental Requirements ETSI 300 019 series Directive 2002 95 EC Directive on the restriction of the use of certain hazardous substances in electrical and electronic equipment RoHS The ENP1 version complies with RoHs 6 of 6 The version complies with RoHS 5 of 6 due to lead solder used in the ENP4 heat frame MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 37 Introduction Figure 1 1 Declaration of Conformity of 8100 EC Declaration of Conformity According to EN 17050 1 2004 Manufacturer s Name Artesyn Embedded Computing Embedded Computing Manufacturer s Address Zhongshan General Carton Box Factory Co Ltd No 62 Qi Guan Road West Shiqi District 528400 Zhongshan City Guangdong PRC Declares that the following product in accordance with the requirements of 2004 108 EC 2006 95 EC 2011 65 EU and their amending directives Product MVME84100 Series VMEbus Single Board Computer Model Name Number 8100 202180404 MVME8100 202200401E 8100 2022004015 8100 202200404 has been designed and manufactured to the following specifications EN55022 2010 EN55024 2010 IEC 60950 1 2005 2nd Edition EN60950 1 20
22. Row Row Pin Name P1 Connector 5th Signal Pin Signal Signal Signal Signal Description Name Description Description Description Description BBSY DATA 8 NC BCLR DATA 9 GND ACFAIL DATA 10 NC BGIN1 DATA 13 GND BGOUT1 DATA 14 NC BGIN2 DATA 15 GND BGOUT2 GND NC B10 BGIN3 SYSFAIL D10 GND fen fen 12 SYSRESET 3 3V not GND used LWORD GA2 NC 5 3 3V not GND NC 3 3V not GND used GA4 NC 3 3V not GND 66 used MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 Table 3 4 PT Connectors continued Connectors LEDs and Switches P1 Connector 15 P1 Connector 2nd 1 Connector 3rd P1 Connector 4th Row Row Row Row P1 Connector 5th Row Pin Signal Pin Signal Pin Signal Pin Signal Pin Signal Name Name Description Name Description Name Description Name Description NC IACK 3 3V not GND used IACKIN NC NC IACKOUT 3 3V not GND NC 3 3V not GND used NC NC 3 3V not GND NC 3 3V not GND used NC NC 3 d s GND NE GND MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 67 Connectors LEDs and Switches Table 3 5 P2 Connectors P2 Connector 15 P2 Connector 2nd P2 Connector 3rd P2 Connector 4th P2 Connector 5th Row Row Row Row Row Pin Signal P
23. VMEbus system enclosure e System console terminal Operating system and or application software Configuring the Board The board provides software control over most options Settings can be modified to fit the user s specifications To configure set the bits in the control register after installing the board in a system Make sure that all user defined switches are properly set before installing a PMC XMC module For more information about switches see Switches on page 81 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Hardware Preparation and Installation Prior to installing PMC modules on the MVME8100 MVME8105 MVME8110 baseboard ensure that all switches that are user configurable are set properly To do this referto Figure 2 1 or the board itself for the location of specific switches and set the switches according to the descriptions provided in Configuration Switches on page 82 Figure 2 1 Switch Locations ENP1 board Figure 2 2 Switch Locations ENP4 Board aam 53 Switch 52 Switch 2 4 Installing Accessories This section describes the procedures for installing the RTM of MVME8100 MVME8105 MVMES81 10 PMCs and the XMCspan on the baseboard MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 49 Hardware Preparation and Installation 2 4 1 50 Rear Transition Module The RTM of MVME8100 MVME8105 MVME8110 does not support
24. an ELF image in memory Boot application image from memory Boot image through network using BOOTP TFTP protocol Boot VxWorks from an ELF image Memory compare Print console devices and information Memory copy Multiprocessor CPU boot manipulation and release Checksum calculation Get set reset date amp time Runs POST diags Echo args to console Load binary file from a Ext2 file system ext2ls List files in a directory default fatinfo Print information about file system MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 115 Boot System Table 5 1 MVMES100 MVME8105 MVMES110Specific U Boot Commands continued Command Description fatload Load binary file from a DOS file system fatls List files in a directory default fdt Flattened device tree utility commands go Start application at address addr help Print online help i2c 12 sub system iminfo Print header information for application image imxtract Extract a part of a multi image interrupts Enable or disable interrupts Return true false on integer compare Load binary file over serial line kermit mode Load S Record file over serial line Load binary file over serial line ymodem mode loop Infinite loop on address range md Memory display memmap Displays memory map mii utility commands mm Memory modify auto incrementing address
25. are accessible with the PMC XMCs installed The onboard sites are configured to support 3 3 V I O PMC modules The onboard PMC sites do not support 5 0 V I O PMC modules The MVME8100 ENPA version only supports rugged conduction cooled PMC XMC modules see VITA 20 2001 for conduction cooled PMC for mechanical definition MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 51 Hardware Preparation and Installation 52 Follow the steps to install a PMC XMC module onto the MVME8100 MVME8105 MVME8110 board Installation Procedure Read all notices and follow the steps to install a PMC XMC on the baseboard Logic Ground to Chassis Ground Isolation The MVME8100 MVME8105 MVMES81 10 heat frames are isolated from the board logic ground Installing a PMC or XMC module which has mounting locations connected to the module logic ground will result in a short between chassis ground and the MVME8100 MVME8105 MVME81 10 logic ground 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 Before installing or removing additional devices or modules read the documentation that came with the product 1 Attach an ESD strap to your wrist
26. controller uses Chip Select 0 as the boot device so CPLD logic is used on the MVME8100 MVME8105 MVMES81 10 in order to swap the chip select to the boot devices The chip select control is based upon the configuration switch S5 1 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 4 7 4 8 4 9 Functional Description At power up the selection of the SPI boot device is strictly based upon the switch 55 1 setting The selected SPI device must contain a boot image The MVME8100 MVME8105 MVME8110 supports automatic SPI FLASH fail over If booting on one device is not successful then the watchdog will trigger a board reset and the CPLD logic automatically toggle chip selects and tries to boot on the other device MRAM The MVME8100 MVME8105 MVMES81 10 includes one MR2A16AVYS35 MR2A16AYS35 512 KB MRAM device to provide a non volatile memory that has virtually unlimited writes 100 trillion fast access and ten years data retention without power The MRAM is organized as 256Kx16 and accessible through the P5020 P5010 local bus eMMC The MVME8100 MVME8105 MVMES1 10 contains soldered down 8GB eMMC device connected to the P5020 P5010 eSDHC interface The eSDHC interface operates in four bit MMC mode and supports up to 200Mbps data transfer for MMC card using four parallel data lines Processor Console Port The MVME8100 MVME8105 MVMES1 10 utilizes P5020 P5010 UARTI port for the processor console interface This co
27. electronic components make sure that you are working in an ESD safe environment Shipment Inspection To inspect the shipment perform the following steps 1 Verify that you have received all items of your shipment MVME8100 board Quick Start Guide e Safety Notes Summary e Any optional items ordered 2 Check for damage and report any damage or differences to customer service 3 Remove the desiccant bag shipped together with the board and dispose of it according to your country s legislation The productis thoroughly inspected before shipment If any damage occurred during transportation or any items are missing contact customer service immediately MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Hardware Preparation and Installation 2 2 2 2 1 Requirements Make sure that the board when operated in your particular system configuration meets the requirements specified in the next sections Environmental Requirements The following table lists the currently available specifications for the environmental characteristics of the MVME8100 MVME8105 MVME8110 complete functional description of the MVME8100 MVME8105 MVMES1 10 baseboard appears in Chapter 4 Functional Description The MVME8100 has ENP1 and ENP4 variants which comply with the following environmental and regulatory specifications The MVME8105 has ENP 1variant only which comply with the following environmental and regulatory specific
28. for use on the RTM 12 Devices The 5020 P5010 provides four 12C controllers but only controller 1 and controller 4 are used The 2C ports are connected to multiple devices such as VPD SPD User EEPROMs switch configuration EEPROMs temperature sensors RTM EEPROM EEPROMS and clock devices The RTM and XMC EEPROM addresses are configured such that they do not have an address conflict with other on board device address The I2C busses and device addresses are MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 101 Functional Description shown in Figure 4 6 For more information refer MVME8100 MVME8105 MVMES110 Programmer s Reference Figure4 6 12C Busses 0x51 PCIE EP FREESCALE ne P5020 P5010 0x50 0x50 0552 U79 MVME8100 loca m mE FREESCALE P5020 XJ1 x 12 1 22 4 EEPROM 03 0 55 0 54 0 74 0 6 SWITCH 0120 075 2 Buffer 1128 2 purer TEMP TEMP RTM SENSE SENSE CLOCK RTC VPD 2 3 1 0112 024 ung 022 0x4C 0x48 0x6E 0x68 0x57 4 18 Reset Control CPLD The MVME8100 MVME8105 MVME8110 uses a Lattice LCMXO2280C CPLD to provide reset power up sequencing timers miscellaneous board logic and status control registers accessibl
29. 05 MVME81 10 Installation and Use 6806800P25K Connectors LEDs and Switches Connector MVME8100 MVME8105 MVME8110 supports two sites The board only supports 15 for site 1 and J25 for site 2 Table 3 13 XMC Connectors 1 2 ROW A 1 2 ROW B 2 ROW C 1 2 ROW D 2 ROW E XJ1 2 ROW F ME Signal Pin Signal Signal Signal Pin Signal i Signal Description No Description PinNo Description PinNo Description No Description Description JTAG TRST HRESET RX2 3 3V 3 3V JTAG TCK MRSTO PULLED UP RX4 3 3V 3 3V RX6 3 3V 3 3V JTAG TDI 12V 3 3V JTAG TDO GAO BIST 3 3V PULLED UP GA1 PRESENT 3 3V AUX 3 3V GA2 I2C DATA 3 3V MVMRO I2C CLOCK PULLED DOWN NC NC GND NC ROOTO NC PULLED UP Note1 All are NC on XJ2 Note2 Default configuration XMC1 is x8 2 is x4 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 79 Connectors LEDs and Switches 3 2 LEDS Table 3 14 describes the LEDs on the front panel of the MVME8100 MVME8105 MVMES1 10 Refer to Figure 3 1 for LED locations Table 3 14 Front Panel LEDs Label Function Description USER 1 D16 User Defined Off By Default Yellow User Software Controllable Red User Software Controllable FAIL D8 Board Fail Off Normal operation after successful firmware boot One
30. 06 A11 2009 2011 65 EU RoHS Directive As manufacturer we hereby declare that the product named above has been designed to comply with the rele vant sections of the above referenced specifications This product complies with the essential health and safety requirements of the above specified directives We have an internal production control system that ensures compliance between the manufactured products and the technical documentation 04 028 2014 Tom Tuttle Manager Product Testing Services Date MM DD YYYY EMBEDDED TECHNOLOGIES 38 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Introduction Figure 1 2 Declaration of Conformity of MVME8 105 EC Declaration of Conformity According to EN 17050 1 2004 Manufacturer s Name Artesyn Embedded Computing Embedded Computing Manufacturer s Address Zhongshan General Carton Box Factory Co Ltd No 62 Qi Guan Road West Shiqi District 528400 Zhongshan City Guangdong PRC Declares that the following product in accordance with the requirements of 2004 108 EC 2011 65 EU and their amending directives Product MVME8105 Series VMEbus Single Board Computer Model Name Number MVME8105 01E has been designed and manufactured to the following specifications EN55022 2010 EN55024 2010 A1 2015 2011 65 EU RoHS Directive As manufacturer we hereby declare that the product named above has been designed to comply with the rele vant sections of the above r
31. 100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 2 4 2 Hardware Preparation and Installation Ensure that the levers of the two injector ejectors are in the outward position Slide the RTM into the chassis until resistance is felt Simultaneously move the injector ejector levers in an inward direction o Verify that the RTM is properly seated and secure itto the chassis using the two screws located adjacent to the injector ejector levers 9 Connectthe appropriate cables to the RTM Removal Procedure 1 Turn off the power 2 Disconnect all the cables 3 Loosen and remove the screws located adjacent to the injector ejector levers that securing board to the chassis 4 Movethe injector ejector levers in an outward direction 5 Hold top and bottom edges of the board and exert minimal force when pulling the board from the chassis to prevent pin damage 6 Remove the transition module from the chassis and insert the filler panels Installation The PMC connectors are placed to support two single width PMCs or one double width PMC PMC site 1 supports front PMC I O and rear I O via the Jn4 connector PMC 1 I O is routed to the VME P2 connector PMC site 2 only supports front PMC I O and does not have Jn4 connector The PMC 1 Jn4 user I O signals only support low current high speed signals and thus do not support current bearing power supply usage The user configured switches
32. 2 Processor nase near eine ee 91 4 3 System MOMON sad S ee ee ees 91 Times era ee fee 91 4 4 1 RealTime Clock 92 4 4 2 P5020 P5010 Internal Timers 92 4 4 3 Watchdog pere exe schenken en ee 92 4 4 3 1 Initial Hardware Watchdog 93 4 43 2 QS Watchdog m Rn 93 4 4 4 93 4 5 EthernetInterfaces 2 2 u en 93 4 6 tenti ee une 94 4 6 1 SPI Flash Memory 94 4 6 2 Firmware Redundancy 94 4 7 MRAM zusehen ERR E E Ca pala kiya wa 95 8 puasa EEES 95 4 9 Processor Console Port 95 4 10 Rear UART Poms anne ee ea PR RR A Ra Yr EP rS 96 AAV PCIe To CAE Lc 96 4 12 SRIO Ports iie elite eek 97 4 13 PMCE XME Sites na ne ehe 99 4 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Contents 4 13 1 PMC Add on Card ee 99 4 13 2 Add on u u eere ee 100 4 14 SATA interface onen ee en 100 2 15 VME SUP POM eee ee ee ee neh 100 4 1
33. 3 JTAG TMS 35 TRDY 4 JTAG TDO 36 3 3V 5 JTAG TDI 37 GND 6 GND 38 STOP 7 GND 39 PERR 8 NC 40 GND 9 NC 41 3 3V 10 NC 42 SERR 11 BUSMODE2 43 Pulled UP 12 3 3V 44 GND 13 PCI RESET 45 AD 14 14 BUSMODE3 46 AD 13 PULLED DWN 15 3 3V 47 M66EN 16 BUSMODE4 48 AD 10 PULLED DWN 17 NC 49 AD 8 18 GND 50 3 3V 19 AD 30 51 AD7 74 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Connectors LEDs and Switches Table 3 9 PMC J12 J22 Connector continued Pin Name Signal Description PinName Signal Description 20 AD 29 52 REQB 21 GND 53 3 3V 22 AD26 54 GNTB 23 AD 24 55 NC 24 3 3V 56 GND 25 IDSEL 57 NC 26 AD 23 58 EREADY 27 3 3V 59 GND 28 AD 20 60 RSTOUT 29 AD 18 61 ACK64 30 GND 62 3 3V 31 AD 16 63 GND 32 CBE2 64 NC Table 3 10 13 23 Connectors PinName Signal Description GND AD48 AD47 AD46 AD 45 GND 3 3V AD 44 AD 43 AD 42 AD41 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 75 Connectors LEDs and Switches Table 3 10 13 23 Connectors continued Pin Name Signal Description PinName Signal Description GND GND AD 40 AD 39 AD 38 AD 37 GND GND AD 36 AD 35 AD 34 AD 33 GND 3 3V AD 32 NC NC NC GND GND NC Signal Description Pin Name Signal Description PMCIO 1 33 PMCIO 33 PMCIO 2 34 P
34. 5 1 Tsi148 VME Controller 101 4 15 2 Tsi384 to PCI PCI X 4 101 16 USB D MROR 101 4 17 I2C Devices seat Du ee 101 4 18 Reset Control CPLD 102 4 19 Power Management es a 103 4 19 1 Power Distribution Structure 104 4 19 2 Power Sequence 5 104 4 20 Clock Structure sese err ner bee ee a u sqa 105 4 21 RESERSTrUCKUTe Haare en 106 4 22 Interrupt Controller 5 108 4 23 GPIO Electrical Characteristics 109 4 24 Thermal Management 109 5 BootSystem sau 111 5 1 Accessing W BOOE sessi ae 111 5 2 BOGE OPTIONS oorr e Re erbe ERRARE PI ioe A HERE 112 5 2 1 Booting from a Network 112 5 2 2 Booting from an Optional SATA 113 5 2 3 Booting from a USB Drive 113 5 2 4_Bootingfrom 114 5 2 5 Booting
35. 81 10 Installation and Use 6806800P25K Sicherheitshinweise aa Dieses Kapitel enth lt Hinweise die potentiell gef hrlichen 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 au erdem alle anderen Vorsichtsma nahmen treffen die f r den Betrieb des Produktes innerhalb Ihrer Betriebsumgebung notwendig sind Wenn Sie diese Vorsichtsma nahmen oder Sicherheitshinweise die an anderer Stelle diese Handbuchs enthalten sind nicht beachten kann das Verletzungen oder Sch den am Produkt zur Folge haben Artesyn Embedded Technologies ist darauf bedacht alle notwendigen Informationen zum Einbau und zum Umgang mit dem Produkt in diesem Handbuch bereit zu stellen Da es sich jedoch um ein komplexes Produkt mit vielf ltigen Einsatzm glichkeiten handelt k nnen wir die Vollst ndigkeit der im Handbuch enthaltenen Informationen nicht garantieren Falls Sie weitere Informationen ben tigen sollten wenden Sie sich bitte an die f r Sie zust ndige Gesch ftsstelle von Artesyn Embedded Technologies Das Produkt wurde entwickelt um die Sicherheitsanforderungen f r SELV Ger te nach der Norm EN 60950 1 f r informationstechnische Einrichtungen zu erf llen Die Verwendung des Produkts in einer anderen Anwendung erfordert eine Sicherheits berpr fung f r diese spezifische Anwendung
36. Batterie kann gef hrliche Explosionen und Besch digungen 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 k nnen die Zeiteinstellungen verloren gehen Eine Backupversorgung verhindert den Datenverlust w hrend des Austauschs Wenn Sie die Batterie schnell austauschen bleiben die Zeiteinstellungen m glicherweise erhalten MVME8100 MVME8105 MVMES81 10 Installation and Use 6806800P25K Sicherheitshinweise Datenverlust Wenn die Batterie wenig oder unzureichend mit Spannung versorgt wird wird der RTC initialisiert Tauschen Sie die Batterie aus bevor sieben Jahre tats chlicher Nutzung vergangen sind Sch den an der Platine oder dem Batteriehalter Wenn Sie die Batterie mit einem Schraubendreher entfernen k nnen die Platine oder der Batteriehalter besch digt werden Um Sch den zu vermeiden sollten Sie keinen Schraubendreher zum Ausbau der Batterie verwenden Umweltschutz Entsorgen Sie alte Batterien und oder Blades Systemkomponenten RTMs stets gem der Ihrem Land g ltigen Gesetzgebung wenn m glich immer umweltfreundlich MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 25 Sicherheitshinweise eee EEE 26 MVME8100 MVME8105 MVMES81 10 Installation and Use 6806800P25K Chapter 1 Introduction 1 1 The 8100 Single Board Co
37. Complex Programmable Logic Device Cyclic Redundancy Check Double Data Rate Dual In line Memory Module Direct Memory Access Error Correction Code EEPROM Electrically Erasable Programmable Read Only Memory eMMC Enhanced Module Management Controller Federal Communications Commission First In First Out Gigabit Media Independent Interface Institute of Electrical and Electronics Engineers Inter IC Initial Hardware Watchdog Joint Test Access Group Local Bus Controller Magnetoresistive random access memory OS Watchdog Peripheral Component Interconnect Express Peripheral Component Interconnect X Programmable Interrupt Controller PIM PCI Mezzanine Card Input Output Module 12 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K About this Manual TERM PMC PLD PrPMC QUART MEANING PCI Mezzanine Card Programmable Logic Device Processor PCI Mezzanine Card Quad Universal Asynchronous Receiver Transmitter RGMII Reduced Gigabit Media Independent Interface RTC Real Time Clock RTM SATA SBC SDRAM Rear Transition Module Serial AT Attachment Single Board Computer Synchronous Dynamic Random Access Memory SELV Safety Extra Low Voltage SMT Surface Mount Technology SGMII SPD SRAM SRIO Serial Gigabit Media Independent Interface Serial Presence Detect Static Random Access Memory Serial Rapid
38. Connectors LEDs Switches 63 Figure 4 1 Block Diagram ofMVME8100 88 Figure 4 2 Block Diagram of MVME8110 89 Figure 4 3 Block Diagram of MVME8105 90 Figure 4 4 PCIE POMS an a aan 97 Figure 4 5 SRIO Bus Topology io he 98 Figure 4 6 I2 C Busses na ei een re 102 Figure 4 7 Power Distribution 104 Figure 4 8 Clock Structure He 105 Figure 4 9 Reset Control Diagram 107 Figure 4 10 Thermal Management 110 Figure A 1 Battery LOGON nee 119 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 9 List of Figures me gLeuuUuui Pre M 10 MVME8100 MVME8105 MVMES81 10 Installation and Use 6806800P25K About this Manual EN Overview of Contents This manual provides the information required to install and configure an MVME8100 MVME8105 MVME8110 Additionally this manual provides specific preparation and installation information and data applicable to the board The MVME8100 is a high performance dual core processor board featuring the Freescale QorlQ P5020 processor The MVME8105 is a high performance dual core processor board featuring the Freescale QorlQ P5020 proc
39. E8110 Installation and Use 6806800 25 35 Introduction e Form Factor Standard 6U one slot Support 0 8 and 0 85 inch slot chassis Support heat frame on both sides for Conduction cooled board e Miscellaneous One front panel RESET Switch LED front panel status indicators four user fail ready LEDs Planar status indicators Boundary scan support e Software Support VxWorks OS support Linux OS supports 32 bit e RTM Compatible with RTM assembly 0106852 micro DB9 connector for console port on front panel DOneUSB2 0type A connector on front panel One front panel RJ45 connector with integrated LEDs for 10 100 1000 Ethernet channel PMC XNC site 1 front and rear PMC I O PMC XNC site two front Four Serial ports to P2 RTM two with micro DB9 connectors RTM panel and two on planar headers Two 10 100 1000BASE T Ethernet channels to RJ45 connectors on RTM panel Two 1000 BASE BX Ethernet SERDES channels to backplane Two USB2 0 ports to RTM with USB type A connectors on RTM panel SATA port to RTM with eSATA connector on RTM Two GPIOs to planar headers on RTM 36 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Introduction 1 2 Standard Compliances The MVME8100 MVME8105 MVME8110 is designed to be CE compliant and to meet the following standard requirements Table 1 1 Board Standard Compliances UL 60950 1 Safety
40. Einbau Wartung und Betrieb d rfen nur von durch Artesyn Embedded Technologies ausgebildeter oder im Bereich Elektronik oder Elektrotechnik qualifiziertem Personal durchgef hrt werden Die in diesem Handbuch enthaltenen Informationen dienen ausschlie lich dazu das Wissen von Fachpersonal zu erg nzen k nnen dieses jedoch nicht ersetzen Halten Sie sich von stromf hrenden Leitungen innerhalb des Produktes fern Entfernen Sie auf keinen Fall Abdeckungen am Produkt Nur werksseitig zugelassenes Wartungspersonal oder anderweitig qualifiziertes Wartungspersonal darf Abdeckungen entfernen um Komponenten zu ersetzen oder andere Anpassungen vorzunehmen Installieren Sie keine Ersatzteile oder f hren Sie keine unerlaubten Ver nderungen am Produkt durch sonst verf llt die Garantie Wenden Sie sich f r Wartung oder Reparatur bitte an die f r Sie zust ndige Gesch ftsstelle von Artesyn Embedded Technologies So stellen Sie sicher dass alle sicherheitsrelevanten Aspekte beachtet werden MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 21 Sicherheitshinweise EMV Betrieb 22 Das Produkt wurde in einem Artesyn Embedded Technologies Standardsystem getestet Es erf llt die f r digitale Ger te der Klasse A g ltigen Grenzwerte in einem solchen System gem den FCCRichtlinien Abschnitt 15 bzw EN 55022 Klasse A Diese Grenzwerte sollen einen angemessenen Schutz vor St rstrahlung beim Betrieb des Produktes in Gewerbe sowie I
41. Installation and Use 6806800P25K About this Manual Notation Description A Indicates a hazardous situation which if not avoided A could result in death or serious injury XXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXNXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX Indicates a hazardous situation which if not avoided may result in minor or moderate injury XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX Indicates a property damage message XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX i IL XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX No danger encou ntered Pay attention to importa nt iN Y 3OO00000000000000000000000000000000000000000000000 information This is the first edition of the MVME8100 MVME8105 MVME8110 Single Board Computer Installation and Use Part Number Publication Date Description 6806800P25A May 2012 First edition 6806800P25B November 2012 GA release 6806800P25C December 2012 Updated Standard Compliances on page 34 6806800P25D September 2013 Updated Table 1 1 Table 1 2 Table 2 1 Table 2 3 PMC XMC Installation on page 48 Table 3 2 on page 61 and Table 3 5 on page 64 Added Fi
42. MCIO 34 PMCIO 3 35 PMCIO 35 76 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Connectors LEDs and Switches Table 3 11 14 Connector continued 4 PMCIO 4 36 PMC IO 36 5 5 37 PMC IO 37 6 PMCIO 6 38 38 7 PMCIO 7 39 PMC 39 8 PMCIO 8 40 PMC IO 40 9 PMC IO 9 41 PMC IO 41 10 PMC IO 10 42 PMC IO 42 PMCIO 11 43 PMC IO 43 14 46 15 47 16 IO 48 17 49 20 IO 52 21 IO 53 PMCIO 22 PMCIO 54 PMCIO 23 PMC IO 55 PMCIO 26 58 27 59 PMCIO 28 PMCIO 60 PMCIO 29 PMCIO 61 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 77 Connectors LEDs and Switches Table 3 11 PMC 14 Connector continued 32 PMCIO 32 64 PMCIO 64 Asset JTAG Connector The MVME8100 MVME8105 MVMES81 10 contains a 20 0 1 header for an Asset JTAG header The pinout for the header is given in the following table Table 3 12 Asset TAG Header Pin Assignment P12 PIN Number Description PIN Number TC ASSET PRSNT L GNDon cable 1 T K 2 DO 4 GND DI 10 GND TRST_L T No Pin Key Reserved NC GND Reserved NC GND 16 Reserved NC GND 18 Reserved NC GND 20 Reserved NC 78 MVME8100 MVME81
43. MES1 10 Installation and Use 6806800P25K 117 Boot System The following procedure will replace the image in SPI bank 0 1 Ensure FLASH WP in Surface Mount Technology SMT Configuration Switch 53 1 is the OFF position 2 Select SPI flash 0 sf probe 0 3 Erase 0x90000 bytes starting at SPI address 0 sf erase 0 0x90000 4 Write 0x90000 bytes from RAM address 0x1000000 starting at SPI address 0 sf write 0x1000000 0 0x90000 To replace the image in SPI bank 1 replace step 2 with Select SPI flash 1 sf probe 1 118 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Battery Exchange A 1 Battery Exchange The ENP1 variant contains an on board battery The battery location is shown in the following figure Figure A 1 Battery Location Battery MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 119 Battery Exchange 120 The battery provides data retention of seven years summing up all periods of actual data use Artesyn Embedded Technologies 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 If the respective battery model is not available contact your local Artesy
44. MVME8100 MVME8105 MVME8110 Installation and Use P N 6806800P25K October 2015 v m w jiwa wn Copyright 2015 Artesyn Embedded Technologies Inc All rights reserved Trademarks Artesyn Embedded Technologies Artesyn and the Artesyn Embedded Technologies logo are trademarks and service marks of Artesyn Embedded Technologies Inc 2015 Artesyn Embedded Technologies Inc 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 Java and all other Java based marks are trademarks or registered trademarks of Oracle America Inc in the U S and other countries Microsoft Windows and Windows Me are registered trademarks of Microsoft Corporation and Windows XP is a trademark of Microsoft Corporation PICMG CompactPCI AdvancedTCA and the PICMG CompactPCI and AdvancedTCA logos are registered trademarks of the PCI Industrial Computer Manufacturers Group UNIX is a registered trademark of The Open Group in the United States and other countries Notice While reasonable efforts have been made to assure the accuracy of this document Artesyn assumes no liability resulting from any omissions in this document or from the use of the information obtained therein Artesyn reserves the right to revise this document and to make changes from time to time in the content hereof w
45. MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Functional Description 4 20 Clock Structure Figure 4 9 shows the clock tree implementation for the MVME8100 MVME8105 MVME8110 Figure 4 8 Clock Structure 100 Mhz Differential HCSLJ 5020 P5010 SERDES REF1 100 Mhz Differential HCSLJ lt P5020 P5010 SERDES REF2 ICS9FG104 100 Mhz Differential HCSL 32NT24AG2 GCLKO 100 Mhz Differential HcSL lt 32NT24AG2 GCLK1 25Mhz LVCMOS 25Mhz LVCMOS BCM5482 PHY 25Mhz 25MHz 1CS83905 546165 PHY XTAL I 25Mhz 25Mhz LVCMOS LVCMOS 133Mhz LVCMOS TSI 148 ICS840S07 133Mhz LVCMOS TSI 384 VME 133Mhz LVCMOS P5020 P5010 SYSCLK 25Mhz Lvcmos 88SE9125 SATA CTRL 25Mhz LVCMOS 125Mhz LVCMOS gt P5020 P5010 ETH CTRL1 2 100 Mhz Differential HCSL y XMC1 E100 Mhz Differential HCSL XMC2 25Mhz LVCMOS LLL oo Mhz Differential ics J 32NT24AG2 PCLK0 100 Mhz Differential HCSL 32NT24AG2 PCLK2 ICS9FG108 U112 E100 Mhz Differential HCSLJ TSI 384 PMC1 E7100 Mhz Differential HCSLJ TSI 2 E100 Mhz Differential HCSL TSI 384 VME 100 Mhz Differentia
46. PrPMC The PMC site has two IDSELs two REQ GNT pairs and EREADY to support PrPMC modules as defined by VITA39 XMC Add on Card add on cards are required to operate off of 5V or 12V from carrier to XMC The MVME8100 provides 5V to the VPWR Variable Power pins The MVME8100 MVME8105 MVME8110 does not provide 12V to the XMC VPWR pins Voltage tolerances for VPWR and all carrier supplied voltage 3 3V 12V 12V are defined by the base XMC standard SATA interface The MVME8100 MVME8105 MVMES81 10 is designed to support an optional 2 5 inch SATA HDD SDD in PMC XMC site 2 The heat frame has mounting holes to support the 2 5 SSD HDD on board The connector interface to the MVME8100 MVME8105 MVME8110 board is compatible with the Artesyn Embedded Technologies SATA mounting kit MVME8100 HDMTKIT4 which contains a SATA adapter board screws and mounting brackets The SATA adapter board provides a standard SATA connector to support horizontal mounting of the HDD SSD MVME8100 MVME8105 MVME8110 utilizes Marvell s 88SE9125B1 885 9125 0 SATA controller This is PCI Express 2 0 to dual SATA 3 0 Host Bus Adapter It employs the latest SATA PHY technology operating at 1 5Gbps or 3 0Gbps VME Support The MVME8100 MVME8105 MVMES81 10 is designed to comply with VME ANSI VITA 1 5 2003 2eSST The MVME8100 MVME8105 MVME8110 supports most of the addressing and data transfer modes defined by the VME64 VME64x and 2eSST specific
47. SQW which is used to drive the P5020 P5010 RTC input signal The RTC internal oscillator has been disabled before the board was shipped from the factory Use the following process to turn on the RTC oscillator from Uboot MVME8100 gt i2c mm 0x68 e 1 0000000e 98 18 0000000 80 n To set the date usethe following uboot command MVME8100 gt date MMDDhhmm CC YY ss P5020 P5010 Internal Timers The P5020 P5010 provides a total of eight global timers it is divided into two groups group Aand group B Each group has four timers Each timer has four individual configuration register However these two groups of timers cannot be cascaded together Watchdog Timers The CPLD has two watchdogs timers the Initial Hardware Watchdog IWD and the OS Watchdog OSWD The Initial Hardware Watchdog is used to guard loading of U Boot and to prevent board hanging up U Boot has to service IWD before timeout or IWD will request Power On Reset Following a board reset the board will try to boot from the U Boot Flash selected by the configuration switches If IWD is not serviced in time by U Boot then following the IWD reset the board will attempt to boot from the alternate SPI1 U Boot Flash device MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K Functional Description 4 4 3 1 4 4 3 2 4 4 4 4 5 The OS Watchdog OSWD is used to guard loading of the operating system The OS has to service OSWD befor
48. TRPBF x T T 400mA 1A max Lattice LCMXO 2280C National SCANSTA112 12A max 1 0V 5 0V TPS40193DRCR Freescale P5020 P5010 15A max 1 0V_IDT IDT32NT24AG2 iod TPS40193DRCR n n or CPS1616 15A max MarvelB8SE9125 m 1 1V TPS40140RHHR 22 Freescale P5020 P5010 20A max V 1 5V DDR VIT MAX17000AETG T Freescale P5020 P5010 DDR3 Memory Devices 1 2V TPS54620RGYT psr 384 2A max IDT TSI 148 1 8V d TPS54620RGYT Ly Pericom PI 3L301 DAE 1 3 A Pericom PI 2PCIE2412 Marvell 885 9125 i2V SW een BCM54616S BCM5482SH 2 IFBG IDT 51616 Freescale P5020 P5010 2 5V Broadcom BCM 546165 LTC3026EDD PBF u Broadcom 1 5A max 54825 2 IFBG IDT32NT24AC2 Exar ST16C 554 QUART 3 3V IDT 32NT24AG2 TPS40193DRCR IDT TSI 384 15A max IDT 151148 1 CPS 1616 4 19 2 Power Sequence Requirements Freescale P5020 P5010 Freescale 2 16MRAM Broadcom BCM54616S Marvell 88SE9125 Maxim MAX 3160E SMSC USB 2512 Bi USB Hub Texas SN74LVTH126 Texas SN74 VMEH22501 Texas SN74LVC125A The CPLD power sequence timing is designed to support all the MVME8100 MVMES8105 MVMES81 10 devices supply voltage sequencing requirements 104
49. VME8110 Installation and Use 6806800 25 63 Connectors LEDs and Switches 3 1 Connectors This section describes the assignments and signals for the connectors on the MVME8100 MVME8105 MVME8110 3 1 1 External Connectors 3 1 1 1 Front Panel Connectors The following are the Front Panel Connectors Serial Console Port J1 Front Panel Ethernet Connector J1 USB Connector J5 Table 3 1 Console Front Panel Connector J1 PIN No RS232 SIGNALING RS485 SIGNALING NC NC COM_O_RX COM 0 RX COM 0 TX 0 TX 0 RTS COMO TX COM 0 CTS COMO RX NC NC Table 3 2 Front Panel Tri Speed Ethernet Connector J4 Note J4 is assembled only on ENP1 1 VCC 64 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K Connectors LEDs and Switches Table 3 2 Front Panel Tri Speed Ethernet Connector J4 continued Note J4 is assembled only on ENP1 Pin No Signal Description 2 TDO 3 TDO 4 TD1 5 TD2 6 7 8 9 TD2 TD1 TD3 TD3 10 GND Table 3 3 USB Connector J6 Note 6 is assembled only on 1 Pin No Signal Description MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 65 Connectors LEDs and Switches 3 1 1 2 Backplane Connectors Table 3 4 P1 Connecto P1 Connector 1st Row rs P1 Connector 2nd Row P1 Connector 3rd Row P1 Connector 4th
50. VME8110 utilizes dTSECA for a dedicated front panel 10 100 1000BASE T interface and dTSEC5 for a 10 100 1000BASE T interface to the RTM via P2 MVME8105 uses DTSEC3 and DTSECA to the front panel A Broadcom BCM5482 dual transceiver provides the RGMII gt 10 100 1000BASE T interfaces A second 10 100 1000BASE T interface to the RTM through P2 is provided using dTSEC2 in SGMII mode A Broadcom 5461 65 transceiver provides the SGMII gt 10 100 1000BASE T interface The registers of these transceivers can be accessed via the P5020 P5010 s two wire Ethernet Management interface Thefront panel RJ45 connector has integrated speed and activity status indicator LED s Similar to the front panel Ethernet the RJ45 connectors found in the RTM have integrated speed and activity status indicator LED s Isolation transformers are provided on board for each of the RTM ports The MVME8100utilizes dTSEC1 and dTSEC5 in SGMII mode for two additional 1000Base BX Ethernet ports to PO SPI Interface Firmware boot Flash resides on the P5020 P5010 eSPI bus interface SPI Flash Memory The P5020 P5010 contains two Eight MB serial flash devices These devices contain the 512 bits of the Reset Configuration Word the boot firmware image U boot and the ENV environment variables Firmware Redundancy The MVME8100 MVME8105 MVMES1 10 utilizes two separate Eight MB boot devices in order to provide boot firmware redundancy The P5020 P5010 SPI device
51. VxWorks Through the Network 114 5 3 MVME8100 MVME8105 MVMES81 10 Specific U Boot Commands 115 5 4 Updating ae he tre RR ee soe PRETIO EV ERE C TER en 117 A Battery ioo ERO a 119 Battery Exchange 119 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 5 Contents B Related Docimentation u nn u 121 B 1 Artesyn Embedded Technologies Embedded Computing Documentation 121 B 2 5 121 B 3 Manufacturers Documents 123 6 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K List of Tables EN Table 1 1 Board Standard Compliances 37 Table 1 2 Mechanical Data u Re rye E CORR RE UE 41 Table 1 3 Board cit hard reo nee 41 Table 2 1 MVME8100 MVME8105 MVME8110 Specifications 45 Table 2 2 Operating Voltages 47 Table 2 3 Power Requirements sesser 2 hei ree ern 47 Table 3 1 Console Front Panel Connector J1 64 Table 3 2 Front Panel Tri Speed Ethernet Connector
52. annel Direct Memory Access DMA engines Enhanced local bus controller Two Express controller ports Serial Rapid IO controller ports SRIO port v1 3 compliant with features of v2 1 Enhanced secure digital host controller SD MMC MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 27 Introduction Enhance Serial Peripheral Interfaces eSPI Two high speed USB 2 0 controllers with integrated PHYs System Memory Two banks of DDR3 SDRAM with ECC Total 4 GB 2GB per Bank 1333 MHz DDR3 data rate SMBus One 512 Kbit user configuration serial EEPROM 256BSerial Presence Detect SPD EEPROMs One 64 Kbit Vital Product Data VPD EEPROM Real Time Clock RTC with battery backup Temperature Sensors and XMC VPD EERPOMs e FLASH Two soldered SPI FLASH 8MB each switchable for uboot primary backup support Hardware switch or Software bit write protection for entire logical bank Eight GB eMMC Flash NVRAM 512 KB MRAM e PCI Express Two 4X Ports to VXS backplane PO muxed with SRIO ports 8X Port to PMC XMC Site 1 One 4X Port to PMC XMC Site 2 SRIO Two 4X Ports to VXS backplane PO muxed with PCle ports USB One USB 2 0 for front panel I O Two USBs 2 0 for backplane RTM I O 28 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800 25 Introduction e Ethernet 10 100 1000BASE T Ethernet port to front panel only in a
53. ard s VMEbus geographical address Note that this switch is wired parallel with geographical address pins on the 5 row connector to these switches must be in the off position when installed in a 5 row chassis in order to get the correct address from P1 connector This switch reflects the inverted states on the geographical address signals Table 3 17 S3 Switch Settings Position Default Description OFF SPI FLASH Write Protect is Disabled ON SPI FLASH Write Protect is Enabled PO Connector Port B PCIE SRIO Fabric Selection Applicable to MVME8100 only OFF Port B same as Port A selection and is controlled by SW2 8 ON Port B selection is opposite Port A and is controlled by 52 8 selection MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 83 Connectors LEDs and Switches Below is the switch configuration for corresponding slot address in a 21 slot chassis 3 row backplane Table 3 18 Three Row Backplane Manual Slot Addressing 51 3 S1 4 51 5 51 6 51 7 51 8 GAP GA 4 0 Slot Address OFF OFF OFF OFF OFF ON 111110 OFF OFF OFF ON OFF 111101 ON OFF 011100 111011 011010 0 11001 OFF OFF orr orr OFF 110111 ON OFF 0 10110 0 10101 1 10100 010011 o FF ON ON AE 110010 OFF FF 110001 ra OFF 0 10000 101111 001110 001100 OFF OFF ON 101100 FEE OFF
54. ations The MVME8110 has ENP1variant only which comply with the following environmental and regulatory specifications For ENP1 boards the operating temperatures refer to the temperature of the air circulating around the board and not to the component temperature For 4 board the operating temperature refers to the temperature at the card edge frame Table 2 1 MVME8100 MVMES 105 MVMES 1 10 Specifications Characteristics ENP1 ENP4 Cooling Method Forced Air Conduction Operating temperature 0 C to 55 40 85 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 45 Hardware Preparation and Installation Table 2 1 MVME8100 MVMES 105 MVMES1 10 Specifications continued Characteristics ENP1 Storage Temperature 40 Cto 85 C 55 Cto 105 C Note The MVME8100 ENP 4 version includes NAND Flash memory in the form ofthe eMMC The specified storage limitsforthe MVME8100 ENP 4 version are 55 Cto 105 C However it should be noted that the industry standard for Flash as well as the specific vendor of this component only warrants performance without data degradation from 40 C to 85 C Storage of the MVME8100 outside this range while supported by other components on the board may result in an unspecified reduction in the data retention capabilities of the eMMC Relative humidity To 95 RH To 100 RH Vibration Sine 10min axis 2G 5 to 500 H
55. ations The MVME8100 MVME8105 MVME8110 can operate in System Controller SCON mode or in Non SCON mode This is determined by on board switch settings on S4 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K 4 15 1 4 15 2 4 16 4 17 Functional Description 151148 VME Controller The Tsi148 provides the required VME64 VME64X and 2eSST functions TISN74VMEH22501 transceivers buffer the VME signals between Tsi148 and the VME backplane Refer to the IDT 751148 User s Manual for additional details and programming information Tsi384 PCIe to PCI PCI X Bridge The PCle to PCI PCI X Bridge function required to interface to the Tsi148 is provided by the Tundra Tsi384 device The Tsi384 is responsible for bridging bi directional traffic between the PCle switch and the Tundra Tsi148 Per ANSI VITA 1 5 2003 the theoretical maximum transfer rate for a 6U VME card in 2eSST mode is 320MBps or 2 62 Gbps USB The P5020 P5010 provides two USB 2 0 controllers with integrated PHYs The MVME8100 MVMES1 10 routes USB port 1 to the front panel to an upright USB Type A receptacle The DC power for the front panel USB port is supplied through Micrel s MIC2076 power switch which provides soft current limiting over current detection and power enable The P5020 P5010 USB port 2 is routed to USB2512 hub device which provides two additional downstream USB 2 0 ports The two additional downstream ports are routed to the P2 connector
56. ber 2005 VITA 42 0 2005 XMC PCI Express Protocol Layer Standard June 2006 VITA 42 3 2006 Conduction Cooled PMC ANSI VITA 20 2001 PMC I O Module PIM Draft Standard VITA 36 Draft Rev 0 1 July 19 1999 Universal Serial Bus Universal Serial Bus Specification Revision 2 0 April 27 2000 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 PCI X EM 2 0a Revision 2 0a August 22 2003 PCI X Protocol Addendum to the PCI Local Bus Specification Revision 2 0a PCI X PT 2 0a July 22 2003 Institute for Electrical and Electronics Engineers Inc IEEE Standard for a Common Mezzanine Card CMC Family IEEE1386 Oct 25 2001 IEEE Standard Physical and Environmental Layer for PCI Mezzanine Cards IEEE1386 1 PMC Oct 25 2001 IEEE 1101 2 1992 IEEE 1101 10 1996 IEEE 1101 1 1998 Conduction cooled VME mechanics Additional Mechanical Specifications IEEE Standard for Mechanical Core Specifications for Microcomputers 122 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Related Documentation B 3 Manufacturers Documents For additional information refer to the following table for manufacturers data sheets or user s manuals As an additional help a source for the listed document is provided Please note that while these sources have been verified the information is subject to c
57. complexity of this product and its various uses we do not guarantee that the given information is complete If you need additional information ask your Artesyn Embedded Technologies representative This product is a Safety Extra Low Voltage SELV device designed to meet the EN60950 1 requirements for Information Technology Equipment The use of the product in any other application may require safety evaluation specific to that application Only personnel trained by Artesyn Embedded Technologies or persons qualified in electronics or electrical engineering are authorized to install remove or maintain the product The information given in this manual is meant to complete the knowledge of a specialist and must not be used as replacement for qualified personnel Keep away from live circuits inside the equipment Operating personnel must not remove equipment covers Only Factory Authorized Service Personnel or other qualified service personnel may remove equipment covers for internal subassembly or component replacement or any internal adjustment Do not install substitute parts or perform any unauthorized modification of the equipment or the warranty may be voided Contact your local Artesyn Embedded Technologies representative for service and repair to make sure that all safety features are maintained This equipment has been tested and found to comply with the limits for a Class A digital device pursuant to Part 15 of the FCC Rules These limi
58. e ENP4 temperature The following table shows the power limits due to the available 5 volts pins when the MVME8100 MVME8105 is installed in either a 3 row or 5 row chassis and when PMCs XMCs are present Chassis Type Power limits PMCs or XMCs 5 Row 90 W maximum Below 90 W 1 Keep below power limit Cooling limitations must be considered MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 47 Hardware Preparation and Installation 2 2 3 2 2 4 2 2 5 2 3 48 Thermal Requirements The MVME8100 MVME8105 MVMES81 10 module requires a minimum air flow of 10 uniformly distributed across the board with the airflow traveling in the direction from PMC XMC 1 to PMC XMC 2 when operating at a 55 C 131 F ambient temperature Thermally Significant Components The chassis into which the MVME8100 MVME8105 MVMES1 10 is installed must provide sufficient airflow to maintain proper board operating temperature The P5020 P5010 processor temperature should be monitored while the board is operational to ensure that the processor core temperature does not exceed 100 C The processor core temperature can be read using the I2C sensor at address 4 on the processor I2C bus 1 For more information refer MVME8100 MVME8 105 MVMES81 10 Single Board Computer Programmer s Reference Equipment Requirements The following equipment is recommended to complete an MVME8100 MVME8105 MVME8110 system e
59. e PO ports The selection of the root complex or end point eeprom for loading the configuration data after reset is determined by the root complex configuration switch S4 2 see S4 Switch on page 85 The eeproms can be reprogrammed over the processor 12C bus 4 interface The eeprom device addresses are listed in section 2C Devices on page 101 A diagram of the SRIO port topology is shown in the figure below YE The 80HCPS1616 SRIO switch does not support auto baud rate discovery The switch MM configuration EEPROMs must program the PO fabric ports to match the SRIO baud rate of the system The default baud rate for the PO fabric ports is 2 5 Gbaud Figure4 5 5 Bus Topology Port A Port B 98 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Functional Description 4 13 Sites The MVME8100 MVME8105 MVMES81 10 provides two PMC XMC sites Each PMC XMC site will accept either a PMC or an XMC add on card For a given PMC XMC site only an XMC or a PMC maybe populated at any given time as they occupy the same physical space on the PCB The PMC XMC1 site provides rear PMC I O The PMC XMC sites are fully compliant with the following VITA 39 PCI X for PMC VITA 35 2000 for PMC P4 to VME P2 Connection PMC XMC1 site only PCI Rev 2 2 for PCI Local Bus Specification PCI X PT 2 0 for PCI X Protocol Addendum to the PCI Local Bus Specs IEEE Standard P1386 2001 for Standard for Common Mezzanine Card Famil
60. e power source and then turn on the system Figure 2 3 Typical Placement of a PMC XMC Module on Module 2 4 3 SATA Installation A 2 5 SATA drive can be installed in PMC XMC site 2 The MVME8100 HDMTKIT4 SATA mounting kit 6706881A01x provides the mounting hardware A SATA drive which meets the intended board operating environment for temperature and vibration must be used 54 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Hardware Preparation and Installation Read all notices and follow the steps to install a SATA drive on the baseboard Logic Ground to Chassis Ground Isolation The MVME8100 MVME8105 MVME8110 heat frames are isolated from the board logic ground Installing a SATA drive which has a metallic case connected to the drive logic ground will result in a short between chassis ground and the MVME8100 MVME8105 MVME8110 logic ground 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 Before installing or removing additional devices or modules read the documentation that came with the product MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 55 Hardware Preparation and Installation
61. e through the P5020 P5010 LBC interface The CPLD uses early 3 3V power from the 5V backplane and be programmed through JTAG interface pins through the connector It uses a 1 8 MHz oscillator for logic control The CPLD provides the following functions e Power control and fault detection Reset sequence and reset management 102 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Functional Description Status and Control registers e Miscellaneous control logics Watchdog timer e 32 bit Tick Timers e Clock generator e Switch decoder and LED controller 4 19 Power Management The5 volt coming from the back plane is utilized to derive all on board voltage rails To provide the required voltage sequencing each voltage rail is controlled by the CPLD through enable pin of each regulator and the output is being monitored by CPLD through each regulator power good signal If one voltage rail fails the CPLD will disable all of the regulators and the only way to restart the board is by power cycling the chassis 5 volt power MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 103 Functional Description 4 19 1 Power Distribution Structure Figure 4 7 displays the MVME8100 MVME8105 MVME8110 power distribution structure Figure 4 7 Power Distribution VME BACKPLANE 3 3V MGT Early Power LT1963AESF3 3
62. e timeout or OSWD will request a hard reset sequence to reset the board If IWD is not serviced after switching over to the SPI1 U Boot Flash board will infinitely try to boot to SPI1 U Boot Flash By default U Boot will disable both the IWD and the OSWD The configuration switch S2 1 is used to enable or disable both watchdogs By default the watchdogs are disabled Initial Hardware Watchdog Initial Hardware Watchdog IWD starts after reset deassertion This watchdog has to be serviced within 8s after a reset deassertion otherwise a IWD reset will be requested The Initial Hardware Watchdog is serviced by writing OXEEA1 to CPLD Command Status Register OS Watchdog The OS Watchdog OSWD is not armed after reset It is enabled right after the is disabled The OSWD timeout is setto 1085 If the timer terminates the OSWD reset sequence will be initiated OSWD is serviced and disabled by writing OXBBC2 to CPLD Command Status Register CPLD Tick Timer The 8100 supports four independent 32 bit timers that are implemented on the CPLD to provide fully programmable registers for the timers Ethernet Interfaces The P5020 P5010 has five dTSEC controllers The controllers can be configured to implement RGMII GMII or SGMII interfaces to external Ethernet transceivers MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 93 Functional Description 4 6 4 6 1 4 6 2 94 The MVME8100 MVME8105 M
63. e 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 The setting of switches which are not marked as reserved has to be checked and changed before board installation 18 MVME8100 MVME8105 MVMES81 10 Installation and Use 6806800P25K Safety Notes Installation Data Loss Powering down or removing a board before the operating system or other software running on the board has been properly shut down may cause corruption of data systems Make sure all software is completely shut down before removing power from the board or removing the board from the chassis Product Damage Only use injector handles for board insertion to avoid damage to the front panel and or PCB Deformation ofthe front panel can cause an electrical short or other board malfunction Product Damage Inserting or removing modules with power applied may result in damage to module components Before installing or removing additional devices or modules read the documentation that came with the product 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 1 line to an Ethernet connecto
64. eferenced specifications This product complies with the essential health and safety requirements of the above specified directives We have an internal production control system that ensures compliance between the manufactured products and the technical documentation 10 13 2015 Tom Tuttle Manager Product Testing Services 74 EMBEDDED TECHNOLOGIES MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 39 Introduction Figure 1 3 Declaration of Conformity of 8110 EC Declaration of Conformity According to EN 17050 1 2004 Manufacturer s Name Artesyn Embedded Computing Embedded Computing Manufacturer s Address Zhongshan General Carton Box Factory Co Ltd No 62 Qi Guan Road West Shiqi District 528400 Zhongshan City Guangdong PRC Declares that the following product in accordance with the requirements of 2004 108 EC 2011 65 EU and their amending directives MVME8110 Series VMEbus Single Board Computer Model Name Number MVME8110 01E MVME8110 01S MVME8110 RTM has been designed and manufactured to the following specifications EN55022 2010 EN55024 2010 Edition 2 2011 65 EU RoHS Directive As manufacturer we hereby declare that the product named above has been designed to comply with the rele vant sections of the above referenced specifications This product complies with the essential health and safety requirements of the above specified directives We have an internal p
65. essor The MVME8110 is a high performance single core processor board featuring the Freescale QorlQ P5010 processor This manual is divided into the following chapters and appendices Safety Notes contains the cautions and warnings applicable to the use of this product Sicherheitshinweise is a German translation of the Safety Notes chapter Chapter 1 Introduction gives an overview of the features of the product standard compliances mechanical data and ordering information Chapter 2 Hardware Preparation and Installation outlines the installation requirements hardware accessories switch settings and installation procedures Chapter 3 Connectors LEDs and Switches describes external interfaces of the board This includes connectors LEDs and switches Chapter 4 Functional Description includes a block diagram and functional description of major components of the product Chapter 5 Boot System describes the boot load software Appendix A Battery Exchange describes the procedure for replacing a battery Appendix B Related Documentation provides listings for publications manufacturer s documents and related industry specification for this product MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 11 About this Manual Abbreviations This document uses the following abbreviations TERM MEANING ANSI American National Standard Institute Common Mezzanine Card Common On chip Processor
66. g table shows the external interrupts connected to the P5020 P5010 Table 4 1 P5020 P5010 External Interrupt Assignments P5020 P5010 Interrupt Description IRQO None Reserved IRQ1 BCM5482 INT1 BCM5482 PHY interrupt 1 from LED P1 2 pin IRQ2 BCM5482 INT2 5482 PHY interrupt 2 from LED P2 2 pin IRQ3 GPIO21 QUART IRQO Quart Interrupt INTA IRQ4 GPIO22 QUART_IRQ1 Quart Interrupt INTB IRQ5 GPIO23 QUART IRQ2 Quart Interrupt INTC IRQ6 GPIO24 QUART IRQ3 Quart Interrupt INTD IRQ7 GPIO25 CPLD TEMP INT L Board Temperature interrupt routed through CPLD IRQ8 GPIO26 TIMER INT L CPLD Internal Timers and Abort IRQ IRQ9 GPIO27 BCM54616S INT BCM54616S PHY interrupt from LED4 pin IRQ10 GPIO28 SRIO IRQ INT 80HCPS1616 SRIO IRQ_N pin applicable to MVME8100 only IRQ11 GPIO29 RTC INT L RIC interrupt routed through CPLD YE IRQ10 GPIO28 with interrupt source SRIO IRQ INT Lis applicable to MVME8100 only 7 108 MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K Functional Description 4 23 4 24 GPIO Electrical Characteristics The four GPIO signals routed to the PO of MVME8100 and P2 connectors have the following electrical characteristics Table 4 2 GPIO DC Electrical Characteristics lot mA mA 2 9 4 4 3 1 0 1 0 1 Table 4 3 GPIO Pull Down Characteristics Parameter Condition Min Max Units IJO Active Pull down
67. gure 2 2 on page 46 SATA Installation on page 51 Figure 2 4 on page 53 Figure 3 2 on page 60 Interrupt Controller Assignments on page 105 and GPIO Electrical Characteristics on page 106 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 15 About this Manual Part Number Publication Date Description 6806800 25 December 2013 Added chapter Boot System 6806800 25 2014 Re branded to Artesyn template 6806800P25G September 2014 Changed title as MVME8100 8110 Added information about MVME8110 and Declaration of Conformity 6806800 25 July 2015 Updated CPLD Tick Timer section 6806800P25K October 2015 Changed as MVME8100 MVME8105 MVME8110 16 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Safety Notes EN EMC 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 Failure to comply with these precautions or with specific warnings elsewhere in this manual could result in personal injury or damage to the equipment Artesyn Embedded Technologies intends to provide all necessary information to install and handle the product in this manual Because of the
68. hange without notice Table B 3 Manufacturer s Publications Document Title and Source Publication Number Freescale Corporation P5020 P5010 QorlQ Integrated Processor Hardware Specifications P5020EC P5020 QorlQ Integrated Multicore Communication Processor Reference P5020RM Manual Integrated Devices IDT 89HPES32NT24xG2 PCI Express Switch User Manual CPS 1616 User Manual MVME8100 MVME8105 MVME81 10 Installation and Use 6806800P25K 123 Related Documentation _ re 124 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K A mS Y SAI r Eu EMBEDDED TECHNOLOGIES Artesyn Embedded Technologies Artesyn and the Artesyn Embedded Technologies logo are trademarks and service marks of Artesyn Embedded Technologies Inc All other product or service names are the property of their respective owners 2015 Artesyn Embedded Technologies Inc
69. hapter including all caution and warning notes before you begin 1 2 Unpack the hardware Unpacking and Inspecting the Board on page 44 Configure the hardware by setting jumpers on the board and RTM Configuring the Board on page 48 Install the RTM VXS1 RTM1 of MVME8100 or MVME8110 RTM of MVME8110 in the chassis Rear Transition Module on page 50 Install PMC module if required Installing Accessories on page 49 Install XMC module if required Installing Accessories on page 49 Install the MVME8100 MVME8105 MVME81 10 in the chassis Installing and Removing the Board on page 57 Attach cabling and apply power Completing the Installation on page 59 Install PIM on transition module if required Refer VXS 1 RTM 1and 1 10 RTM Installation and Use manual Examine and or change environmental parameters MVME8100 MVME8105 MVME8 110 Single Board Computer Programmer s Reference Program the board as needed for your applications 105 8 110 Single Board Computer Programmer s Reference MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 43 Hardware Preparation and Installation 2 1 44 Unpacking 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
70. 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 60 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Connectors LEDs and Switches eee This chapter summarizes the Front Panel Connectors LEDs Switches and their configuration for the MVME8100 MVME8105 MVME8110 board The following components are found on MVME8100 MVME8105 MVME8110 front panel Refer to Figure 3 1 forthe location of each component Figure 3 1 ENP1 Board Connectors LEDs Switches Board Fail LED Console Port Micro DB9 Reset Switch User LED USB 2 0 Link LED Gigabit Ethernet Activity LED Port MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 61 Connectors LEDs and Switches me Figure3 2 ENP4 LEDs and Switches Board FAIL LED USER 1 LED RESET 62 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Connectors LEDs and Switches Figure3 3 Board Connectors LEDs Switches i Board User LED Console Port Micro DB9 8 Reset Switch Board Fail LED PMC XMC Site2 PMC XMC Site Gigabit Ethernet Port Link LED Ati LED in Gigabit Ethernet Port a lt Activity LED MVME8100 MVME8105 M
71. hes on 52 The four ports can be configured for RS 232 or RS 422 RS 485 modes RS 232 mode supports RX TX RTS and CTS signals Only four wire full duplex RX TX is supported in RS422 485 mode The signaling mode is selected through on board configuration switches on S2 4 11 Ports The MVME8100 MVME8105 MVME8110 provides multiple PCI Express ports The P5020 P5010 is configured to use two x4 PCle controllers 1 and 3 on the MVME8100 MVME8105 MVME8110 Both controllers are configured to operate at Gen 1 data rate 2 5 Gbaud These ports are routed to IDT 32NT24AG2 PCle switch for expansion of the PCle ports The IDT switch is a 32 lane Gen 2 device and can support up to 24 ports 8 of which are capable of NT function Each port of the switch is configured to operate at Gen 1 data rate The configuration of the ports and the partitioning of the switch into a single or multiple domains is controlled by an I2C eeprom connected to the PCle switch master SMbus and loaded into the switch following reset The board provides two separate eeproms so that separate configuration data can be maintained for the MVME8100 MVME8105 MVMES81 10 operating as a root complex or as an end point the PO connector ports for MVME8100 The selection of the root complex or end point eeprom for loading the configuration data after reset is determined by the root complex configuration switch 54 2 see 54 Switch on page 85 The eeproms can be reprogrammed f
72. hot swap You must remove power to the system before installing the module Before installing the transition module you may need to manually configure the RTM switches and install a PMC I O Module PIM 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 Only use injector handles for board insertion to avoid damage to the front panel and or PCB Deformation of the front panel can cause an electrical short or other board malfunction 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 Installation Procedure To begin the installation of the RTM 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 Install the top and bottom edge of the RTM into the rear guides of the chassis MVME8
73. in Signal Pin Signal Pin Signal Pin Signal Name Description Name Description Name Description Name Description Name Description PMCIO 2 PMCIO 4 PMCIO 1 PMCIO3 MD GND PMCIO 6 RETRY PMCIO5 GIGE3_MD IO0_N PMCIO 8 PMCIO 10 ADDRESS 24 ADDRESS 25 PMCIO 7 PMCIO 9 GND MD IO1_P PMCIO 12 ADDRESS 26 PMCIO 11 GND PMCIO 14 PMCIO 16 ADDRESS 27 ADDRESS 28 PMCIO 13 PMCIO 15 USB2_N GIGE3_MD GND PMCIO 18 ADDRESS 29 PMCIO 17 RTM_SIO GIGE3_MD 102_P PMC IO 20 PMC IO 22 ADDRESS 30 ADDRESS 31 PMC IO 19 PMC IO 21 BPSWITCH N GPIO_2 GND GIGE3_MD IO2_N PMCIO 24 GND PMC IO 23 3 GND 26 5 PMC IO 30 5V 14 PMCIO28 B14 DATA16 C14 A1 C15 B15 DATA 17 PMC IO 25 PMC IO 27 PMC IO 29 12C DATA GIGE3_MD 103_P D14 12C CLK 214 GND D15 COMI RX COMI RX N 215 GIGE3 MD IO3_N 68 MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 Connectors LEDs and Switches Table 3 5 P2 Connectors continued P2 Connector 15 P2 Connector 2nd P2 Connector 3rd P2 Connector 4th P2 Connector 5th Row Row Row Row Row Pin Signal Pin Signal Pin Signal Pin Signal Pin Signal Name Description Name Description Name Description Name Desc
74. ir cooled variant Two 10 100 1000BASE T Ethernet channels to P2 RTM Two 1000BASE BX Ethernet SERDES channels to PO backplane RTM SerialPorts RS232 422 485 console port to front panel or P2 RTM Upto 4RS232 422 485 COM ports to P2 RTM VME Bus VME64x and 2eSST Timers Eight 32 bit timers in CPU Watchdog timer in CPU PMC XMC Two PMC XMC sites with 64 bit PMCIO on Site 1 Serial AT Attachment SATA SSD Option for one 2 5 inch SATA drive PMC XMC Site 2 e Interface Two GPIOs to RTM VXS Interface VITA 41 Specification compliant Support backplane PO connector Form Factor Standard 6U slot Support 0 8 and 0 85 inch slot chassis Support heat frame on both sides for Conduction cooled board e Miscellaneous One front panel RESET Switch LED front panel status indicators four user fail ready LEDs Planar status indicators Boundary scan support MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 29 Introduction 30 Software Support VxWorks OS support Linux OS supports 32 bit e RTM Compatible with RTM assembly 0106852 e micro DB9 connector for console port on front panel OneUSB2 0 type A connector on front panel One front panel RJ45 connector with integrated LEDs for 10 100 1000 Ethernet channel PMC XNC site 1 front and rear PMC I O PMC XNC site two front Four Serial ports to
75. ithout obligation of Artesyn to notify any person of such revision or changes Electronic versions of this material may be read online downloaded for personal use or referenced in another document as a URL to an Artesyn website The text itself may not be published commercially in print or electronic form edited translated or otherwise altered without the permission of Artesyn It is possible that this publication may contain reference to or information about Artesyn products machines and programs programming or services that are not available in your country Such references or information must not be construed to mean that Artesyn intends to announce such Artesyn products programming or services in your country Limited and Restricted Rights Legend If the documentation contained herein is supplied directly or indirectly to the U S Government the following notice shall apply unless otherwise agreed to in writing by Artesyn Use duplication or disclosure by the Government is subject to restrictions as set forth in subparagraph b 3 of the Rights in Technical Data clause at DFARS 252 227 7013 Nov 1995 and of the Rights in Noncommercial Computer Software and Documentation clause at DFARS 252 227 7014 Jun 1995 Contact Address Artesyn Embedded Technologies Artesyn Embedded Technologies Marketing Communications Lilienthalstr 17 19 2900 S Diablo Way Suite 190 85579 Neubiberg Munich Tempe Arizona 85282 Germany Conten
76. l HcSL lt 88SE9125 SATA CTRL ICS841664 156 25 Mhz Differential 51616 SRIO SW gt 0124 125 Mhz Differential HCSLJ R P5020 P5010 SERDES REF3 RTC 32 768 KHz 1 8432MHz 3 QUART CPLD ra 1 8432MH 32 768 KHz P5020 P5010 RTC 24MHz SG 24Mhz gt USB2512 HUB 24MHz MH 24Mhz P5020 P5010 USB MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 105 Functional Description me 4 21 Reset Structure The MVME8100 MVME8105 MVMES81 10 reset begins after the power up sequence is completed A board reset can also be initiated using the front panel reset switch the RTM reset switch through P2 or under software control through the processor Reset Request 106 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Functional Description Figure 4 9 illustrates the reset control structure Figure 4 9 Reset Control Diagram SRION gt sSRlOSW ey 5V_PGOOD BP_PHY_RST_N _ 546165 PHY an Monitor FP PHY RST N BCM5482PHY QUART RESET gt QUART USBHUB N USB2512HUB HRESET XMC XJ1 XJ2 PANEL FFEWITCHM LI TSHM48 RSTI
77. l Description Figure 4 3 Block Diagram of MVME8105 Front Panel PMC XMC I O 1 PMC XMC I O 2 PMC XMC 2 5 ens Site 2 PCIe Multi PEX Protocol DDR3 ECC PCle x4 Transceiver Yy PCle x4 1000BASE T 1000BASE T PCle x4 Local Bus Freescale QorIQ P5020 Quad UART 4 Multi Protocol Transceivers IDT 151148 USB Hub 1000BASE T 1 P1 P2 BP 90 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Functional Description 4 2 4 3 4 4 Processor The P5020 QorlQ processor combines two Power architecture processor cores with high performance data path acceleration logic and network and peripheral bus interfaces required for networking telecom datacom wireless infrastructure and aerospace applications The P5010 QorlQ processor has only one power architecture processor core This device can be used for combined control data path and application layer processing in routers switches base station controllers and general purpose embedded computing Its high level of integration offers significant performance benefits compared to multiple discrete devices while also greatly simplifies the board design The MVME8100 MVME8105 board ENP1 version is designed to use the 2 0 GHz core processor version while the ENP4 version uses the 1 8 GHz processor The 81 10 board ENP1 version is designed to use the 1 2 GHz core processor However MVME8105
78. mputer is VMEbus board based on the Freescale QorlQ P5020 processor It is a high performance 6U VME VXS board targeted towards high end military and industrial automation applications using VMEbus The MVME8100 is compliant with the VMEbus International Trade Association VITA standards VMEbus 2eSST and PCI X The MVME8105 is a dual core non VXS version of the MVME8100 board based on Freescale P5020 QorlQ processor It runs at 2 0 Ghz with 4 GB DDR3 The MVME8105 can accommodate two PCI Mezzanine Card PCI Express Mezzanine Card PMC XMC The MVME8110 is a single core non VXS version of the MVME8100 board based on Freescale P5010 QorlQ processor It runs at 1 2 Ghz with 2 GB DDR3 The MVME8110 can accommodate two PCI Mezzanine Card PCI Express Mezzanine Card PMC XMC The MVME8110 has MVME8110 RTM which is a reduced version of the VXS1 RTM1 MVME8105 uses the same RTM as MVMES81 10 Features The main features of the MVME8100 board are as follows Processor Subset of P5020 features used on MVME8100 Freescale QorlQ P5020 Two e5500 Power Architecture cores Five Gigabit Ethernet controllers Serial Gigabit Media Independent Interface SGMII and Reduced Gigabit Media Independent Interface RGMII interfaces Two64 bit DDR3 3L SDRAM memory controllers with ECC Multicore Programmable Interrupt Controller PIC Fourl2C controllers Two 4 pin Universal Asynchronous Receiver Transmitter s UART s Two4 ch
79. n Embedded Technologies sales representative for the availability of alternative officially approved battery models 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 orthe battery holder To prevent damage do not use a screw driver to remove the battery from its holder Exchange Procedure To exchange the battery proceed as follows 1 Remove the old battery 2 Install the new battery with the plus sign facing up 3 Dispose of the old battery according to your country s legislation and in an environmentally safe way MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Appendix B Related Documentation wwia B 1 B 2 Artesyn Embedded Technologies Embedded Computing Documentation The publications listed below are referenced in this manual You can obtain electronic copies of Artesyn Embedded Technologies Embedded Computing publications by contacting your local Artesyn sales office For released products you can also visit our Web site for the latest copies of our product documentation 1 Goto www artesyn com computi
80. ndustriegebieten gew hrleisten Das Produkt arbeitet im Hochfrequenzbereich und erzeugt St rstrahlung Bei unsachgem em Einbau und anderem als in diesem Handbuch beschriebenen Betrieb k nnen St rungen im Hochfrequenzbereich auftreten Wird das Produkt in einem Wohngebiet betrieben so kann dies mit grosser Wahrscheinlichkeit zu starken St rungen f hren welche dann auf Kosten des Produktanwenders beseitigt werden m ssen nderungen oder Modifikationen am Produkt welche ohne ausdr ckliche Genehmigung von Artesyn Embedded Technologies durchgef hrt werden k nnen dazu f hren dass der Anwender die Genehmigung zum Betrieb des Produktes verliert Boardprodukte werden in einem repr sentativen System getestet um zu zeigen dass das Board den oben aufgef hrten EMV Richtlinien entspricht Eine ordnungsgem sse Installation in einem System welches die EMV Richtlinien erf llt stellt sicher dass das Produkt gem ss den EMV Richtlinien betrieben wird Verwenden Sie nur abgeschirmte Kabel zum Anschluss von Zusatzmodulen So ist sichergestellt dass sich die Aussendung von Hochfrequenzstrahlung im Rahmen der erlaubten Grenzwerte bewegt Warnung Dies ist eine Einrichtung der Klasse A Diese Einrichtung kann im Wohnbereich Funkst rungen verursachen In diesem Fall kann vom Betreiber verlangt werden angemessene Ma nahmen durchzuf hren 1 Besch digung des Produktes Hohe Luftfeuchtigkeit und Kondensat auf der Oberfl che des Produktes k n
81. nen zu Kurzschl ssen f hren Betreiben Sie das Produkt nur innerhalb der angegebenen Grenzwerte f r die relative Luftfeuchtigkeit und Temperatur Stellen Sie vor dem Einschalten des Stroms sicher dass sich auf dem Produkt kein Kondensat befindet MVME8100 MVME8105 MVMES81 10 Installation and Use 6806800P25K Sicherheitshinweise Besch digung von Schaltkreisen Elektrostatische Entladung und unsachgem er Ein und Ausbau des Produktes kann Schaltkreise besch digen oder ihre Lebensdauer verk rzen Bevor Sie das Produkt oder elektronische Komponenten ber hren vergewissern Sie sich da Sie in einem ESD gesch tzten Bereich arbeiten Fehlfunktion des Produktes Schalter die mit Reserved gekennzeichnet sind k nnen mit produktionsrelevanten Funktionen belegt sein Das ndern dieser Schalter kann im normalen Betrieb St rungen ausl sen Verstellen Sie nur solche Schalter die nicht mit Reserved gekennzeichnet sind Pr fen und ggf ndern Sie die Einstellungen der nicht mit Reserved gekennzeichneten Schalter bevor Sie das Produkt installieren Installation Datenverlust Das Herunterfahren oder die Deinstallation eines Boards bevor das Betriebssystem oder andere auf dem Board laufende Software ordnungsmem ss beendet wurde kann zu partiellem Datenverlust sowie zu Sch den am Filesystem f hren Stellen Sie sicher dass s mtliche Software auf dem Board ordnungsgem ss beendet wurde bevor Sie das Board herunterfahren ode
82. ng support product technical documentation php 2 Under FILTER OPTIONS click the Document types drop down list box to select the type of document you are looking for 3 Inthe Search text box type the product name and click GO Table B 1 Artesyn Embedded Technologies Embedded Computing Publications Document Title Publication Number MVME8100 MVME8105 MVME8110 Programmer s 6806800P28 Reference MVME8100 MVME8110 Quick start Guide 6806800P26 MVME8100 MVME8110 Safety Notes Summary 6806800P27 nn 00 8110 VXS1 RTM1 RTM Installation 6806800P46 and Use 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 Please note that while these sources have been verified the information is subject to change without notice Table B 2 Related Specifications Organization and Standard Document Title VITA Standards Organization VME64 ANSI VITA 1 1994 VME64 Extensions ANSI VITA 1 1 1997 MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 121 Related Documentation Table B 2 Related Specifications continued Organization and Standard Document Title 2eSST Source Synchronous Transfer ANSI VITA 1 5 2003 Processor PMC ANSI VITA 32 2003 PCI X for PMC and Processor PMC ANSI VITA 39 2003 XMC Switched Mezzanine Card Auxiliary Standard Septem
83. nsole interface can be routed to the front panel or the P2 connector using configuration switches The front panel port can be configured for RS 232 or RS 422 RS 485 modes RS 232 mode supports RX TX RTS and CTS signals Only four wire full duplex RX TX is supported in RS422 485 mode The signaling mode is selected through on board configuration switches The default baud rate on the front panel serial is 9600 baud The physical front panel console connector is a male micro min DB 9 A male to male micro mini DB9 to DB9 adapter cable is available under Artesyn Embedded Technologies Part Number SERIAL MINI D 30 W2400E014 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 95 Functional Description 4 10 Rear UART Ports The MVME8100 MVME8105 MVMES81 10provides four asynchronous serial UART interfaces to the P2 RTM connector by utilizing Exar s ST16C554 quad UART The Quad Universal Asynchronous Receiver Transmitter QUART features 16 bytes of transmit and receive First In First Out FIFO it has a selectable receive FIFO trigger levels and data rates of up to 1 5Mbps Each UART has a set of registers that provide the user with operating status and control The QUART is a 8 bit device connected to the P5020 P5010 through the local bus controller QUART port A is multiplexed with the P5020 P5010 UART1 console port so that the console port be routed to the RTM COMI port The is controlled using configuration switc
84. ommended air flow direction Link LED Gigabit Ethernet Activity LED Port 110 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Boot System The MVME8100 MVME8105 MVME81 10 uses Das U Boot boot loader software based on the GNU Public License It boots the blade and is the first software to be executed after the system is powered on Its main functions are Initialize the hardware Pass boot parameters to the Linux kernel Start the Linux kernel Update Linux kernel and U Boot images This section describes U Boot features and procedures that are specific to the MVME8100 MVME8105 MVME8110 For general information on U Boot see http www denx de wiki U Boot WebHome 5 1 Accessing U Boot 1 Connect the board to a computer with a serial interface connector and a terminal emulation software running on it The serial connector of the board is found on the face plate 2 Configure the terminal software to use the access parameters that are specified in U Boot By default the access parameters are as follows Baudrate 9600 PCANSI 8databits e Noparity 1stopbit These serial access parameters are the default values These can be changed from within the 9 U Boot For details refer to the U Boot documentation MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 111 Boot System 3 Boot the MVME8100 MVME8105 MVMES1 10 4 When prompted press the lt Ctrl gt lt
85. on OFF Boot from SPI FLASH 0 ON Boot from SPI FLASH 1 Reserved MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 85 Connectors LEDs and Switches 33 13 86 Reset Abort Switch A dualfunction switch can be found in the front panel This switch can function either as a Reset or Abort button If the button is pressed for less than 3 seconds the CPLD will generate an abort interrupt to the P5020 P5010 processor If the button is pressed for more than 3 seconds the CPLD will generate a board hard reset If the board is configured as System Controller the backplane VME SYSRESET signal is also asserted during a board hard reset MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Chapter 4 Functional Description The MVME8100 Single Board Computer is a GU VME VXS board based on the Freescale QorlQ P5020 processor TheMVMES1 10 Single Board Computer is a GU VME board based on the Freescale QorlQ P5010 processor This section describes the features of MVME8100 MVME8105 MVMES1 10 The MVME8105 Single Board Computer is a6U VME board based on the Freescale QorlQ P5020 processor MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 87 Functional Description 41 Block Diagram Figure 4 1 illustrates the MVME8100 architecture Figure 4 1 Block Diagram of MVME8100 Front Panel Micro use ras O1 PMC 02 variant JACK RESET NOTE F
86. only have 2 0GHz version and do not have the ENP4 version For more information refer P5020 P5010 QorlQ Integrated Multicore Communications Processor Family Reference Manual System Memory The MVME8100 MVME8105 supports four GB DDR3 ECC memory using two banks of 2Gb memory devices The 81 10 supports memory using one bank of 2Gb memory devices The memory devices are soldered down and not modular solution using Dual In line Memory Module DIMM sockets The supported data rate is 1333MT s The memory is evenly distributed across both memory channels e g memory capacity requirement is AGB place 2GB of memory on each channel Timers This section describes the timer functions implemented on MVME8100 MVME8105 MVMES81 10 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 91 Functional Description 4 4 1 4 4 2 4 4 3 92 Real Time Clock The MVME8100 implements an Real Time Clock RTC to maintain seconds minutes hours day date month and year accurately It includes 32 768 KHZ crystal DS1337 and back up power For the ENP1 version of the MVME8100 MVME8105 MVMES8110 a battery is used forthe RTC back up power For the 4 version 3 3V regulator powered from the VME backplane 5V_STDBY voltage is used for back up power The DS1337 has an interrupt output INTA which can be programmed to assert a processor IRQ on a time day date match The DS1337 also has a 32 768 KHz clock output
87. op and bottom edges of the board and exert minimal force when pulling the board from the chassis to prevent pin damage 7 Carefully remove the board from the chassis and store the board in anti static envelope Completing the Installation The MVME8100 MVME8105 MVME8110 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 board is installed in a chassis you are ready to connect peripherals and apply power tothe board Figure 3 1 on page 61 show the locations of the various connectors on the board NOTICE Product Damage 45 connectors on modules are either twisted pair Ethernet TPE or E1 T1 J1 network interfaces Connecting an E1 T1 1 line to an Ethernet connector may damage your system Make sure that TPE connectors near your working area are clearly marked as network connectors Verify that the length of an electric cable connected to a TPE bushing does not exceed 100 meters Make sure the TPE bushing of the system is connected only to safety extra low voltage circuits SELV circuits If in doubt ask your system administrator MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 59 Hardware Preparation and Installation The console settings for the MVME8100 MVME8105 MVME81 10 are Eight bits per character One stop bit per character Parity disabled no parity Baud rate of 9600 baud Verify that
88. or more on board power rails have failed and the board has shutdown to protect the hardware Normal during power up during hardware reset such as a front panel reset May be asserted by the BDFAIL bit in the Tsi148 VSTAT register SPEED J4 Link Speed No link 10 100BASE T operation 1000 BASE T operation Activity No activity Blinking Green Activity proportional to bandwidth utilization 80 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Connectors LEDs and Switches 3 2 1 On board LEDs The on board LEDs are listed below The LEDs are located on the rear side of the board just opposite of the battery location To view the board see Figure 3 1 on page 61 Table 3 15 On board LEDs Status Label Function Color Description MMC Write Protect off WP disabled ENP1 PS1_LED_N Board FAIL ENP1 PS2_LED_N POWER ENP1 PS3_LED_N RESET Amber USR_LED2_N Red USR_LED3_N Yellow 3 3 Switches The board provides the following configuration switches S2Switch e S3Switch e S4Switch S5Switch e Reset Abort Switch MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 81 Connectors LEDs and Switches 3 3 1 3 3 1 1 82 Configuration Switches Thefollowing sections describe the on board switches and their configurations for the MVME8100 MVME8105 MVMES81 10 Board Malfunction Switches marked a
89. ore installing the module Before installing the MVME8100 MVME8105 MVME8110 ensure that the serial ports and switches are properly configured Installation 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 Product Damage Only useinjector handles for board insertion to avoid damage to the front panel and or PCB Deformation of the front panel can cause an electrical short or other board malfunction MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 57 Hardware Preparation and Installation 58 Use the following steps to install the MVME8100 MVME8105 MVME8110 into your computer chassis 1 Wear an ESD strap to your wrist 2 Attach the other end of the ESD strap to an electrical ground The ESD strap must be secured to your wrist and to ground throughout the procedure 3 Remove any filler panel that might fill the slot 4 Install the top and bottom edge of the MVME8100 MVME8105 MVME8110 into the guides of the chassis 5 Ensure that the levers of the two IEEE locking injector ejectors if equipped are in the unlocked outward position 6 Slide the board into the chassis until you feel resistance
90. r das Board aus dem Chassis entfernen Besch digung des Produktes Fehlerhafte Installation des Produktes kann zu einer Besch digung des Produktes f hren Verwenden Sie die Handles um das Produkt zu installieren deinstallieren Auf diese Weise vermeiden Sie dass das Face Plate oder die Platine deformiert oder zerst rt wird Besch digung des Produktes und von Zusatzmodulen Fehlerhafte Installation von Zusatzmodulen kann zur Besch digung des Produktes und der Zusatzmodule f hren Lesen Sie daher vor der Installation von Zusatzmodulen die zugeh rige Dokumentation MVME8100 MVME8105 MVME8110 Installation and Use 6806800 25 23 Sicherheitshinweise Kabel und Stecker Batterie 24 Besch digung des Produktes Bei den RJ 45 Steckern die sich an dem Produkt befinden handelt es sich entweder um Twisted Pair Ethernet oder E1 T1 J1 Stecker Beachten Sie dass ein versehentliches Anschlie en einer E1 T1 1 Leitung an einen TPE Stecker das Produkt zerst ren kann e Kennzeichnen Sie deshalb TPE Anschl sse in der N he Ihres Arbeitsplatzes deutlich als Netzwerkanschl sse e Stellen Sie sicher dass die L nge eines mit Ihrem Produkt verbundenen TPE Kabels 100 m nicht berschreitet e Das Produkt darf ber die TPE Stecker nur mit einem Sicherheits Kleinspannungs Stromkreis SELV verbunden werden Bei Fragen wenden Sie sich an Ihren Systemverwalter Besch digung des Blades Ein unsachgem er Einbau der
91. r may damage your system Make sure that TPE connectors near your working area are clearly marked as network connectors e Verify that the length of an electric cable connected to a TPE bushing does not exceed 100 meters Make sure the TPE bushing of the system is connected only to safety extra low voltage circuits SELV circuits If in doubt ask your system administrator MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 19 Safety Notes Battery 20 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 If the respective battery model is not available contact your local Artesyn Embedded Technologies sales representative for the availability of alternative officially approved battery models 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 To prevent damage do not use a screw driver to remove the battery from its holder MVME8100 MVME8105 MVMES
92. ription Name Description PMCIO 32 DATA 18 PMCIO 31 COMI CTS _N COM1_ RX_P PMC10 34 DATA 19 PMC 10 33 COM2_RX GIGE4_MD COM2_RX_ N PMCIO 36 DATA 20 PMCIO 35 COM2_CTS _N COM2_ RX_P PMCIO 38 DATA 21 PMC 10 37 COM3_RX GIGE4_MD COM3_RX_ PMCIO 40 DATA 22 PMCIO 39 COM3_CTS _N COM3_ RX_P PMCIO 42 DATA 23 PMCIO41 COM4_RXJ GIGE4_MD COM4_RX_ IO1_P N PMCIO 44 GND PMCIO 43 4 CTS _N COM4_ RX_P PMC 10 46 DATA 24 PMCIO45 COMI TX GIGE4_MD COM1_TX_ IO1_N N PMCIO 48 DATA 25 PMCIO 47 COM1_RTS _N COM1_ TX_P PMC IO 50 DATA 26 PMC10 49 COM2_TX GIGE4_MD COM2_TX_ 102_P N MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 69 Connectors LEDs and Switches Table 3 5 P2 Connectors continued P2 Connector 1st P2 Connector 2nd P2 Connector 3rd P2 Connector 4th P2 Connector 5th Row Row Row Row Row Pin Signal Pin Signal Pin Signal Pin Signal Pin Signal Name Description Name Description Name Description Name Description Name Description PMC IO 52 PMC IO 51 COM2_RTS _N COM2_ TX_P PMC IO 54 PMC IO 56 DATA 27 DATA 28 PMC IO 53 PMC IO 55 COM3_TX COM3_TX_ N COM3_RTS _N COM3_ TX P GIGE4_MD 102_N PMC IO 58 PMC IO 60 DATA 29 DATA 30 PMC IO 57 PMC IO 59 TXJ COMA TX N 4 RTS _N COM4_ TX_P GIGE4_MD 103_P PMC IO 62 PMCIO 61 GND GIGE4 MD IO3_N
93. roduction control system that ensures compliance between the manufactured products and the technical documentation 09 18 2014 Tom Tuttle Manager Product Testing Services Date MM DD YYY Y T aW EMBEDDED TECHNOLOGIES 40 MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K Introduction 1 3 Mechanical Data The MVME8100 is a full GU board with added mounting holes to support an ENP4 board variant The MVME8100 MVME8105 MVMES1 10 will occupy a single VME card slot Table 1 2 provides details on the board s mechanical data Table 1 2 Mechanical Data Characteristic Value Height 233 44 mm 9 2inches 261 8 mm 10 3 inches Maximum Component Height 14 8 mm 0 58 inches Weight estimated 0 58 Kg ENP1 0 90 Kg 4 1 4 Ordering Information When ordering board variants or board accessories use the order numbers given in the following tables 1 4 1 Supported Board Models Table 1 3 Board Variants Marketing MVME8100 202200401E 8100 2022004015 MVME8100 202200404 Processor P5020 2 0GHz 28W AGB DDR3 VXS 2 IEEE ENP1 P5020 2 0GHz 28W AGB DDR3 VXS 2 PMC XMC SCANBE ENP1 P5020 1 8GHz 27W AGB DDR3 VXS 2 PMC XMC ENP4 MVME8105 01E P5020 2 0 GHz AGB DDR3 2 ENP1 IEEE MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 41 Introduction Table 1 3 Board Variants continued
94. rom the processor using the I2C master interface in the IDT device A swap bit in CPLD control register can be used to temporarily swap the eeprom device addressing so that the alternate eeprom can be reprogrammed A diagram of the PCle port configuration is shown in the figure below 96 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Functional Description Figure4 4 Ports PCIe 8 4 SRIO X4 SRIO p gt Note P4 and P6 are disabled on MVME8105 MVME81 10 4 12 SRIO Ports The MVME8100 also provides multiple SRIO ports The P5020 provides a single x4 SRIO configured for 2 5 GBaud data rate This port is routed to an IDT 80HCPS1616 SRIO switch for expansion of the SRIO ports The SRIO switch supports multiple lane speeds including 1 25 2 5 3 125 and 5 0 Gbaud The MVME8100 provides two x4 SRIO ports which may be routed to the PO connector through a high speed mux The selection of SRIO or PCle ports to PO is controlled by the S2 8 configuration switch see 52 Switch on page 82 The configuration of MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 97 Functional Description the SRIO switch ports is controlled an 12C eeprom connected to the SRIO switch I2C bus and loaded into the switch following reset The board provides two separate eeproms so that separate configuration data can be maintained for the MVME8 100 operating as a root complex or as an end point on th
95. ront panel connectors are not assembled on conductiorcooled DB9 PORT PAI O PMC PMC 2 5 HDD SSD Site1 Site2 8GB PCle 64 bit PCle 133MHz 512kB a PCHX MRAM ls SDHC PCIe to PCIe to HE PCI X Multi Protoco Transceiver 16MB DDR3 ECC Pole CPLD Dua Flash MUX MUX BEN DEMUX DEMUX DDR3 ECC 0 1 PCle 4 x o 5 gp lt PCle SATA PCIe 8 PCle Laial PCle Bus SATA PCIe Switc CTRL Freescale PCle QorIQ P5020 Quad ges PCIe to UART PCI X sromf sRIO m ui 5 5 5 m 133MHz U d PCle x4 NTB PGUX nd z sRIO PCle x IDT 8 NTB TSI148 2 E MUX MUX 4 Multi Protocol DEMUX DEMUX Transceivers PHYL 2 3 USB Of Hub E ae 8 8 z 3 amp lt l E E sls 4133321 2 8 S 8212 x 8 x 2 P1 P2BP 88 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 Functional Description Figure 4 2 illustrates the MVME8110 architecture Figure4 2 Block Diagram of MVME8110 Front Panel 1 0 1 1 0 2 RESET PMC XMC ME ELA Site 1 Site 2 Multi Protocol Transceiver x4 Freescale QorIQ P5010 751148 4 Multi Protocol Transceivers 1 P4 LO 1000BASE T 1 2 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800 25 89 Functiona
96. s 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 S2 Switch The Switch Bank S2 provides watchdog control serial port configuration and PO fabric selection Table 3 16 S2 Switch Settings Position Default Description OFF OFF Watchdog Disabled ON Watchdog Enabled OFF Serial Console Port to Front Panel ON Serial Console Port to P2 RTM panel OFF P2 Serial Port 0 is RS232 ON P2 Serial Port 0 is RS422 485 OFF P2 Serial Port 2 is 5232 ON P2 Serial Port 2 is RS422 485 OFF P2 Serial Port 3 is RS232 ON P2 Serial Port is RS422 485 OFF OFF Front Panel console Port is RS232 ON Front Panel console Port is RS422 485 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 3 3 1 2 Connectors LEDs and Switches Table 3 16 52 Switch Settings continued Position Default Description OFF OFF Select SRIO for PO Backplane Fabric applicable to MVME8100 only ON Select PCle for PO Backplane Fabric applicable to MVME8100 only S3 Switch The TSI148 VMEbus Status Register provides the VMEbus geographical address of the MVME8100 MVME8105 MVME8110 Applications not using a 5 row backplane can use these switches to manually assign bo
97. s to RJ45 connectors RTM panel Two USB2 0 ports to RTM with USB type A connectors on RTM panel Two GPIOs to planar headers on RTM Two64 bit DDR3 3L SDRAM memory controllers with Multicore Programmable Interrupt Controller PIC FourlI2C controllers Two 4 pin Universal Asynchronous Receiver Transmitter s UART s Two 4 channel Direct Memory Access DMA engines Enhanced local bus controller Two PCI Express controller ports Enhanced secure digital host controller SD MMC Enhance Serial Peripheral Interfaces eSPI Two high speed USB 2 0 controllers with integrated PHYs MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 31 Introduction Memory Two banks of DDR3 SDRAM with Total4 GB 2GB per Bank 1333 MHz DDR3 data rate SM Bus SMBus One 512 Kbit user configuration serial EEPROM 2568 Serial Presence Detect SPD EEPROMs One 64 Kbit Vital Product Data VPD EEPROM Real Time Clock RTC with battery backup Temperature Sensors RIMand XMC VPD EERPOMs FLASH Two soldered SPI FLASH 8MB each switchable for uboot primary backup support Hardware switch or Software bit write protection for entire logical bank Eight GB eMMC Flash NVRAM 512 KB MRAM PCI Express One 8X Port to PMC XMC Site 1 One 4X Port to PMC XMC Site 2 USB Two USBs 2 0 for backplane RTM Ethernet Two 10 100 1000BASE T Ethernet port to front panel
98. ts About this Manual one 1 Safety Notes in 17 Sicherheits himi eise uso dur Rear REF 21 1 Introduction 27 Tel eh 27 1 2 Standard Combpliance s re a sa 37 1 3 Mech nicalData e e ea 41 1 4 Ordering Information eerte hehe ne es are 41 1 4 1 Supported Board Models 41 1 4 2 Board 55 5 42 2 Hardware Preparation and Installation 43 2 1 Unpacking and Inspecting the Board 44 2 2 Requirements esse gr eso ga dt dee ee 45 2 2 1 Environmental Requirements 45 2 2 2 PowerReq lremients cse lecker erre EXTRA Wah EO xa RR Wee 47 2 2 3 Thermal Requirements 48 224 Thermally Significant Components 48 2 2 5 48 2 3 Configuring the Board 48 2 4 Installing BRD e etm qaqa 49 2 4 1 Rear Transition Module
99. ts are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment This equipment generates uses and can radiate radio frequency energy and if not installed and used in accordance with the instruction manual may cause harmful interference to radio communications MVME8100 MVME8105 MVME8110 Installation and Use 6806800P25K 17 Safety Notes Operation ofthisequipment 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 Artesyn Embedded Technologies 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 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 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 Befor
100. y IEEE Standard P1386 1 2001 for Standard Physical and Environmental Layer for PCI Mezzanine Card VITA 42 for XMC VITA 42 3 PCle for XMC sites are keyed for 3 3V PMC signaling MVME8100 MVME8105 MVME8110 provides a x8 PCI Express interface link for PMC XMC1 and x4 PCI Express interface link for PMC XMC2 It is designed such that same PCI Express interface is used for either the or the to PCI X bridge required for a PMC This is made possible by using Pericom PI3PCIE3412 PCle mux devices The PCle Mux at both sites is controlled by the CPLD The CPLD detects the presence signal provided by the XMC or PMC board and it will be used to configure the routing of PCle Mux accordingly 4 13 1 PMC Add on Card The MVME8100 MVME8105 MVMES81 10 supports up to two PMC cards PCI X operation to each site is provided using a separate IDT TSI384 PCle to PCI X bridge for each site Each Tsi384 can support up to 8 5Gbps 64bits x 133 Mhz An onboard switch will configure the TSI384 to run on either 100 MHz or 133 MHz The default is 133 MHz MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K 99 Functional Description 4 13 2 4 14 4 15 100 The MVME8100 MVME8105 MVMES81 10 supports multi function PMCs and Processor PrPMCs The PCI signaling voltage VIO for the site is 3 3V as required by the Tundra Tsi384 and is keyed as such The power budget allocated to 3 3V is 16 5W max for either PMC or
101. z 10G 15 to 2000 Hz Vibration Random 0 002g2 Hz 15 to 2000 Hz 0 1g2 Hz 15 to 2000 Hz 12GRMS 2 1hr axis 2G RMS Shock 20g 11mS 40g 11mS Conformal Coating No Option Acrylic 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 46 MVME8100 MVME8105 MVMES1 10 Installation and Use 6806800P25K Hardware Preparation and Installation 2 2 2 Power Requirements The 8100 8105 81 10 uses the backplane 5 V source to power each on board power supply The 3 3 V backplane supply is not utilized in order to have backward compatibility with old 3 row chassis The 12 V and 12 V is routed through to the and PMC connectors The power estimates provided in the following table is the total board consumption from 5 V excluding the PMC XMC SATA HDD SSD and USB devices Table 2 2 Operating Voltages 5 0 V 4 875 V 2 5 5 0V 5 25 V 5 Table 2 3 Power Requirements Board Variant Power 8100 2022004015 Board idle at OS prompt 38 Watts typical MVME8105 01E Operating load 42 Watts typical MVME8110 01S E 54 Watts Max 55 C ENP1 Operating conditions No RTM PMC XMC or peripherals MVME8100 202180404 Operating load 65 Watts max 85 C card edg
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