AMC335 - Sonus
Contents
1. Command Spec Ref NetFn CMD MMC Req Get Device SDR Info 29 2 S E 20h Mandatory Get Device SDR 29 3 S E 21h Mandatory Reserve Device SDR Repository 29 4 S E 22h Mandatory Get Sensor Reading Factors 29 5 S E 23h Optional Set Sensor Hysteresis 29 6 S E 24h Optional Get Sensor Hysteresis 29 7 S E 25h Optional Set Sensor Threshold 29 8 S E 26h Optional Get Sensor Threshold 29 9 S E 27h Optional Set Sensor Event Enable 29 10 S E 28h Optional Get Sensor Event Enable 29 11 S E 29h Optional Get Sensor Event Status 29 13 S E 2Bh Optional Get Sensor Reading 29 14 S E 2Dh Mandatory FRU Device Commands Get FRU Inventory Area Info 28 1 Storage 10h Mandatory Read FRU Data 28 2 Storage 11h Mandatory Write FRU Data 28 3 Storage 12h Mandatory AdvancedTCA Commands Get PICMG Properties 3 10 PICMG 00h Mandatory FRU Control 3 25 PICMG 04h Mandatory FRU Control Capabilities 3 24 PICMG 1Eh Mandatory Get FRU LED Properties 3 27 PICMG 05h Mandatory Get LED Color Capabilities 3 28 PICMG 06h Mandatory Set FRU LED State 3 29 PICMG 07h Mandatory Get FRU LED State 3 30 PICMG 08h Mandatory Get Device Locator Record 1D 3 35 PICMG 0Dh Mandatory AMC Commands Set AMC Port State 3 26 PICMG 19h Optional Mandatory Get AMC Port State 3 27 PICMG 1Ah Optional Mandatory Set Clock State 3 44 PICMG 2Ch Optional Mandatory Get Clock State 3 42. 0 0 0 0 tee 77 NG 35 SUPponed Signals viga cr A lts 83 Console Serial PON ceras ice p is ies ri os 88 Serial Cable Connectors sama E ESA A A ia 88 RS232C Hydra Cable Connector das ass O A A A 89 RS449 RS422 Hydra Cable Connector Lakis 90 ElA530 Hydra Cable Connector vivia aa a 91 v 35 Hydra Cable Connector 10d een di te 92 Console Cab OPIO san ar as y A AA 93 Contents Chapter 6 MPC8270 Parallel I O Ports 95 OVBTNVIEW ze ee ed ee ee A ee 95 LER ONS e a O as MA e S Cata AN Ey a a pre na NG naa a EN a A 95 Serial Management Controllers aaa 96 MPC8270 Parallel Port Pin Assignments nennen tees 96 MPC8270 Port A Pin Assignments ser a Da he 97 MPG3270 Port B Pin Assignments 23 5 dei KG NG tes ee 98 MPC8270 Port C Pin Assignments eis ar A an at 99 MPG8270 Port D Pin Assignments cin 424 ca ss A IA 100 Chapter 7 Reset 101 OVENIEW 225 ea ste bs Bani sem e ine rasa Sa as ige 101 Power On Reseb ia skio sis He bh re 102 Had Resep esse ee ie eta 102 SON ROSE 2 Sest SE e e o po al a a a A rs Ga Aaa e A 104 PCI Express Interface Resets vu sa Ai sd 8 A A E A re 104 Chapter 8 Specifications 107 OVENIEW Se ae es a a e daa es i S PA 107 Absolute Maximum Ratings ista e lao ae 107 Electrical Specifications lt ss6 ans ur salai dos les dd KA NG 108 Power Requirements a si ad aa Mea e a mada io HU pah 108 Environmental Specifications naasa re en a a ka 108 Operating Temperature L kis cid rich 108 Tempe
3. Performance Technologies 205 Indigo Creek Drive Rochester NY 14626 USA 585 256 0248 support pt com www pt com 2009 Performance Technologies Inc All Rights Reserved AMC335 Four Port WAN Communications AdvancedMC Module Hardware Manual A se em PERFORMANCE TECHNOLOGIES w Document Revision History Part Number Date Explanation of Changes 126p0694 10 October 21 2008 Initial Release 126p0694 11 March 19 2009 Added caution about product handling in Product Safety Information 126p0694 12 June 17 2009 Standardized Module Management Controller Corrected board height specification on page 109 126p0694 13 October 2 2009 AMC335 has passed certifications testing updated Chapter 9 Agency Approvals accordingly Replaced Figure 2 2 126p0694 15 November 20 2009 Added note about FCLKA on page 36 and page 102 Copyright Notice O Copyright 2009 by Performance Technologies Inc All Rights Reserved The Performance Technologies logo is a registered trademark of Performance Technologies Inc All other product and brand names may be trademarks or registered trademarks of their respective owners This document is the sole property of Performance Technologies Inc Errors and Omissions Although diligent efforts are made to supply accurate technical information to the user occasionally errors and omissions occur in manuals of this type Refer to the Performance
4. Four LED indicators In Service IS Out of Service OOS Application APP and Hot Swap See LED Indicators on page 31 A push button reset switch See Push Button Reset Switch on page 42 Aninsert extraction hot swap handle See Hot Swap Handle Switch on page 42 Figure 2 1 AMC335 Front Panel In Service LED Out Of Service LED Application Controlled LED Dual VHDCI Connectors Black Jackpost mates with Black Jackscrew on Cable Reset Switch CJ Hot Swap LED 7 Hot Swap Handle 20 AMC335 Functional Blocks AMC335 Functional Blocks Figure 2 2 AMC335 Functional Block Diagram presents a functional block diagram of the AMC335 Figure 2 2 AMC335 Functional Block Diagram OT L Volt Temp BOOT Flash 7 i Monitors 32 MB Di jal nasa Four Port Stac d Serial Transceivers HOCI Custom RS 232 Logic PLD RS 422 v 35 Front Panel Interface sng ONV 26p3 pied RC EEPROM The following topics provide overviews for each major block on the AMC335 Freescale MPC8270 PowerQUICC II Processor on page 22 e AMC Interface on page 22 User I O on page 23 PCI Express Interface on page 24 Ethernet Interfaces on page 25 Memory on page 25 Interrupt Sources on page 27 Module Management Controller on page 29 Reset on page 30 Board Clocks and Frequencies on page 30 Clock Steering
5. M 34 K T27 CTS4 Input 5K Ohms to V 35 Clear To Send port 4 ground N 35 106 M 34 D T67 RXC A 4 Input 100 Ohms V 35 Receive Clock port 4 differential V 35 115 M 34 V 125 Ohms to ground T68 RXC B 4 Input 100 Ohms V 35 Receive Clock port 4 differential V 35 115 M 34 X 125 Ohms to ground 87 Chapter 5 Connectors Console Serial Port Table 5 7 Console Serial Port Pinout shows the pinout for the internal header used for the console serial port and the console serial port connections on the dual VHDCI I O connector Table 5 7 Console Serial Port Pinout Internal Dual VHDCI 2 N j k M Signal Name Header Pin Connector Pin 1 T17 Asynchronous RS232C TXD conforming to the V 28 electrical standard 2 T18 Asynchronous RS232C RXD conforming to the V 28 electrical standard and terminated with 5K to ground 3 T19 Signal Ground Note A three pin right angle internal header can be mounted on the bottom side of the card and used for debugging Contact Performance Technologies Customer Support and Services for more information Serial Cable Connectors The serial connections are brought out from the dual VHDCI connector to standard connectors through a set of shielded hydra style breakout cables See AMC335 I O Configurations and Accessories on page 18 for a list of the hydra cables available for the AMC335 The standard cable pinouts of the hydra cables are shown in the following tabl
6. a 83 power distribution network 108 MAXIMUM er ns NG aaa oe is a dag 108 requirements oooooocoocooo tenes 108 typical ae ea ne 108 R powWer On reset stiga ne a del 102 PowerQUIGE Il voii a eee a eee eee eee RS 22 product definiti n esinen eee AA 17 WAN Y ee ta tit 16 product safety information a 113 push button reset switch aks 42 rear panel VO st tauste gts Vs Lieta 32 reliability x ice nea batt en t the Bp Sa 110 removal e niaan ae re ee Aa 43 feset i sa sists ask O d tas 30 configuration SW3 1 L 39 DU ern 102 Master ia di EN a ee ee 39 MMC 57 setos een espanol 102 PGLEXpr ss gu Be O AA lath 104 SIAV un sen Bra A ee pas 39 SOM re ee ea sk 104 types and sources 2 1 eee eee eee 101 return merchandise authorization RMA 15 ROHS compliance LL 115 RS232C hydra cable options a 19 hydra cable pinout LL 89 Model S ee nr T 18 pinout add a LS Aa BE NA 74 signals on dual VHDCI connector 74 RS422 hydra cable pinout a 90 Model Hat seta a T 18 PINOUT PE ER eee ea 77 signals on dual VHDCI connector o oo oooo o 77 RS449 hydra cable options LL 19 hydra cable pinout a 90 model era tars en ds a S a JAN ei eka 18 pino t acto 77 signals on dual VHDCI connector o oo oooo o 77 RSTGONF intra a een 39 S safety precautions aaa 113 safety regulations AA 113 SDRAM is gees
7. on page 50 Serial Interface Subsystem on page 51 Firmware Upgrade Process on page 59 MMC Functions The MMC performs system monitoring and alarming functions using the flexible industry standard Intelligent Platform Management Interface IPMI The module comes equipped with an on board MMC and IPMI v1 5 firmware already installed on the module The MMC firmware is based on Pigeon Point System s PPS MMC firmware Some of the functions available on the module through the IPMI interface include Monitoring of the CPU and board temperatures with critical and non critical alerting Monitoring of the voltage rails with critical and non critical alerting Remote reset and shutdown of the module hard and soft 45 Chapter 4 System Monitoring and Alarms Monitoring of ejector switches for hot swap functionality Performance Technologies NexusWare IPMI driver and firmware provide additional payload features for hot swap Monitoring and event reporting of critical errors Fabric and clock e keying Interface to local IPMB IPMB L In order to take advantage of the features provided by the firmware IPMI aware applications must be developed Information on IPMI v1 5 is provided at http www intel com design servers ipmi spec htm Summary of Supported Commands 46 Table 4 1 IPMI PICMG Command Subset Supported by the MMC Firmware lists all the commands supported by the MMC The Spec Ref
8. 52 Serial Interface Subsystem Supported PPS Extension Commands The MMC firmware supports the following PPS extension commands see Pigeon Point Systems PPS Extension Commands on page 52 Table 4 5 PPS Extension Commands Supported by the MMC Command Likely Command usi Code y Description See Also Request Response Source s Get Status 0x00 Serial debug and Read the MMC status Get Status Command payload interfaces Get Serial Interface 0x01 Serial debug and Get the properties of a Properties payload interfaces serial interface Serial Line Properties Set Serial Interface 0x02 Serial debug and Set the properties of a Commands Properties payload interfaces serial interface Get Debug Level 0x03 Serial debug Get debug verbosity interface level Debug Verbosity Level Set Debug Level 0x04 Serial debug Set debug verbosity interface level Get Payload 0x09 Serial debug and Get the timeout for Communication payload interfaces payload Payload Timeout communications Communication Set Payload Ox0A Serial debug and Set the timeout for Timeout Communication payload interfaces payload Timeout communications Graceful Reset 0x11 Payload interface The payload is ready Graceful Payload to be shut down reset Reset Diagnostic Interrupt 0x12 Payload interface Return diagnostic Payload Diagnostic Results interrupt results Interrupt Get Payload 0x15 Serial debug and Get the timeout for Shutdown Timeout payload
9. 4 Output NA RS422 Transmit Data port 4 RS449 SD B ElA530 BA B T58 RTS A 4 Output NA RS422 RTS port 4 RS449 RS A EIA530 CA A T59 RTS B 4 Output NA RS422 RTS port 4 RS449 RS B EIA530 CA B T55 TXC A 4 Output NA RS422 TXC port 4 RS449 TT A EIA530 DA A 81 Chapter 5 Connectors Table 5 5 RS422 RS449 EIA530 Signals and Pins Continued 2 ignal TES Ka nag Pin Signa Direction Termination Description Name T56 TXC B 4 Output NA RS422 TXC port 4 RS449 TT B EIA530 DA B T61 TXCI A 4 Input 100 Ohms RS422 SCTE port 4 differential RS449 ST A EIA530 DB A T62 TXCI B 4 Input 100 Ohms RS422 SCTE port 4 differential RS449 ST B EIA530 DB B T64 DCD A 4 Input 100 Ohms RS422 DCD port 4 differential RS449 RR A EIA530 CF A T65 DCD B 4 Input 100 Ohms RS422 DCD port 4 differential RS449 RR B EIA530 CF B T33 DSR A 4 Input 100 Ohms RS422 DSR port 4 differential RS449 DM A EIA530 CC A T34 DSR B 4 Input 100 Ohms RS422 DSR port 4 differential RS449 DM B ElA530 CC B T27 CTS A 4 Input 100 Ohms RS422 CTS port 4 differential RS449 CS A ElA530 CB A T28 CTS B 4 Input 100 Ohms RS422 CTS port 4 differential RS449 CS B ElA530 CB B T67 RXC A 4 Input 100 Ohms RS422 RXC port 4 differential RS449 RT A ElA530 DD A T68 RXC B 4 Input 100 Ohms RS422 RXC port 4 differential RS449 RT B ElA530 DD B 82 V 35 Supported Signals This configuration
10. 92 Model tar ee een dard 18 PINOU te NA NG KAU Da Sakis dies ee la 83 signals on dual VHDCI connector 83 W warranty product en 16 WEEE compliance kaka 115 Windows u area da pida ba ne 19 33 123 Index 124
11. B35 DSR B 2 Input 100 Ohms RS422 DSR port 2 differential RS449 DM B ElA530 CC B B42 CTS A 2 Input 100 Ohms RS422 CTS port 2 differential RS449 CS A ElA530 CB A B41 CTS B 2 Input 100 Ohms RS422 CTS port 2 differential RS449 CS B EIA530 CB B B2 RXC A 2 Input 100 Ohms RS422 RXC port 2 differential RS449 RT A EIA530 DD A 79 Chapter 5 Connectors 80 Table 5 5 RS422 RS449 EIA530 Signals and Pins Continued Pin Signal Direction Termination Description Name B1 RXC B 2 Input 100 Ohms RS422 RXC port 2 differential RS449 RT B EIA530 DD B T9 GND Signal Ground for I O connector T5 RXD A 3 Input 100 Ohms RS422 Receive Data port 3 differential RS449 RD A EIA530 BB A T4 RXD B 3 Input 100 Ohms RS422 Receive Data port 3 differential RS449 RD B ElA530 BB B T14 DTR A 3 Output NA RS422 DTR port 3 RS449 TR A ElA530 CD A T13 DTR B 3 Output NA RS422 DTR port 3 RS449 TR B ElA530 CD B T11 TXD A 3 Output NA RS422 Transmit Data port 3 RS449 SD A EIA530 BA A T10 TXD B 3 Output NA RS422 Transmit Data port 3 RS449 SD B EIA530 BA B T45 RTS A 3 Output NA RS422 RTS port 3 RS449 RS A EIA530 CA A T44 RTS B 3 Output NA RS422 RTS port 3 RS449 RS B EIA530 CA B T48 TXC A 3 Output NA RS422 TXC port 3 RS449 TT A EIA530 DA A T47 TXC B 3 Output NA RS422 TXC port 3 RS449 TT B EIA530 DA B T42 TXCI A 3 Input 100 Ohms RS422 SCTE
12. Do you with to continue YA Yok OK U Target Product ID 15 Target Manufacturer ID 1556 Performing upgrade stage Upgrading AVR AMCm F W with Version Major 1 Minor 70 Aux 000 000 000 000 Writing firmware 100 completed Performing activation stage Firmware upgrade procedure successful IPMI Communication Utility ipmitool The ipmitool utility is a Linux application that can be used for a wide range of tasks involving IPMI based communications The following topics describe the installation process and provide information on specific applications of this utility Note Contact Performance Technologies Customer Support and Services for an enhanced version of ipmitool Besides the standard functionality it supports the following vendor specific enhancements which are not available in the official release as of version 1 8 9 e Support for the serial IPMI interface Terminal Mode Some improvements in HPM 1 upgrade protocol implementation Support for double bridging via LAN for accessing MMCs through the Shelf Manager and carrier IPMC The enhanced version is available in binary form for Windows and in source form for Linux Building the ipmitool Utility Build and install the ipmitool utility on a Linux host system using the following procedure 1 Unpack the source tarball obtained from the secure Web site and change to the ipmitool directory bash tar xzf lt ip
13. EEPROM devices are connected to components on the AMC335 to store initialization values and application code A small EEPROM device is connected to the 12C port port A on the MPC8270 which is used to store non volatile information for the operating system or the application code Reading and writing this device is currently under direct control of the operating system Asecond EEPROM device is connected to the 12C port on the PI7C9X110 PCI Express bridge which handles power up PCERST configuration of the PI7C9X110 PCI Express bridge This EEPROM device is configurable via a DIP switch selection See SW3 2 EEPROM Write Protect on page 40 for more information about configuring this EEPROM device Athird EEPROM device is connected to the 12C port on the BCM5704S Ethernet controller which is used to store the BCM5704S initialization boot code This EEPROM is programmed either by JTAG or over PCI through the BCM5704S Refer to the BCM57XX Programmer s Reference Guide for more information Memory Map The address map is defined by the AMC335 address decode scheme There are different levels of address decode built into the AMC335 The first level and primary decode is done by the MPC8270 s System Interface Unit SIU One of the SIU s subsections is the memory controller which is responsible for controlling a maximum of 12 memory banks shared by a high performance SDRAM machine a general purpose chip select machine GPCM and thr
14. If the activate parameter is specified the upgraded firmware is activated just after the upgrade procedure In the other case an additional command should be issued to activate the firmware Example ipmitool I lan H 192 168 0 2 A none T 0x82 B 0 t 0x74 b 7 hpm upgrade hpmlfw img Validating firmware image integrity OK Performing preparation stage Services may be affected during upgrade Do you wish to continue y n y OK Target Product ID oS Target Manufacturer ID 1556 Performing upgrade stage Upgrading AVR AMCm F W with Version Major 0 Minor 5 Aux 000 000 000 000 Writing firmware 100 completed activate Firmware Upgrade Process Activate the newly uploaded firmware This command can be used for activating the newly uploaded firmware if there was no activate parameter passed to the upgrade command ipmitool Example hpm activate ipmitool activate I lan H 192 168 0 2 A none T 0x82 B 0 t 0x74 b 7 hpm PICMG HPM 1 Upgrade Agent 1 0 rollback Perform a manual rollback on the IPM controller This command can be used to roll back from the newly uploaded firmware to the old one ipmitool Example ipmitool hpm rollback I lan H 192 168 0 2 A none T 0x82 B 0 t 0x74 b 7 hpm rollback PICMG HPM 1 Upgrade Agent 1 0 rollbackstatus Query the rollback status This command can be used to query the
15. Se sm Xy NA About This Guide Overview This manual describes the hardware specific functionality and usage of the Performance Technologies AMC335 Four Port WAN Communications AdvancedMC AMC module In these chapters you will find installation and configuration information plus a functional block description intended for the application developer of this board Here is a brief description of what you will find in this manual Chapter 1 About This Guide on page 13 this chapter provides links to all chapters in this guide plus text conventions customer support and services and product warranty information for the AMC335 Chapter 2 Introduction on page 17 provides an overview of the AMC335 and includes information such as module features front panel details functional block diagram with a brief description of each block and descriptions of software such as the supported operating systems and Intelligent Platform Management Interface IPMI Chapter 3 Getting Started on page 35 provides setup information and includes information such as unpacking the AMC335 system requirements configuration and installation Chapter 4 System Monitoring and Alarms on page 45 describes the commands supported by the on board Module Management Controller MMC sensor thresholds serial interface subsystem and firmware upgrade process Chapter 5 Connectors on page 69 provides connector location descri
16. Third Port 13 TX 52 GND First Logic Ground 119 GND First Logic Ground 53 RX5 Third Port 5 RX 118 RX13 Third Port 13 RX 54 RX5 Third Port 5 RX 117 RX13 Third Port 13 RX 55 GND First Logic Ground 116 GND First Logic Ground 56 SCL L Second IPMB L Clock 115 TX12 Third Port 12 TX IPMI Agent 57 PWR Carrier First Payload Pwr 114 TX12 Third Port 12 TX 58 GND First Logic Ground 113 GND First Logic Ground 59 TX6 Third Port 6 TX 112 RX12 Third Port 12 RX 60 TX6 Third Port 6 TX 111 RX12 Third Port 12 RX 61 GND First Logic Ground 110 GND First Logic Ground 62 RX6 Third Port6 RX 109 TX11 Third Port 11 TX 63 RX6 Third Port 6 RX 108 TX11 Third Port 11 TX 64 GND First Logic Ground 107 GND First Logic Ground 65 TX7 Third Port 7 TX 106 RX11 Third Port 11 RX 66 TX7 Third Port 7 TX 105 RX11 Third Port 11 RX 67 GND First Logic Ground 104 GND First Logic Ground 68 RX7 Third Port 7 RX 103 TX10 Third Port 10 TX 69 RX7 Third Port 7 RX 102 TX10 Third Port 10 TX 70 GND First Logic Ground 101 GND First Logic Ground 71 SDA L Second IPMB L Data 100 RX10 Third Port 10 RX IPMI Agent 71 Chapter 5 Connectors Table 5 2 AMC Connector Pinout Continued Pin Signal S Mating Krista Pin Signal A Mating al ie on 72 PWR Carrier First Payload Pwr 99 RX10 Third Port 10 RX 73 GND First Logic Groun
17. a a Whee Ben 100 MTBE sitas lideradas 110 MTTR aia a BEN ee Mn 110 Network Equipment Building System NEBS 112 NextisWare Core revoca ia as Est 33 NexusWare WAN 2 222 0c cee eee eee 33 non hot SWap unse paa ERBE Bernd Gan 22 operating systems 0 0 0 0 cee eee eee 19 33 operating temperature LL 108 out of service LED a NN KA BNG t a an 31 parallel port pinout MPC8270 a 96 PCI Express interface LLP ee tee 24 interr pt iaa en ai a Bote 28 INBOUNAL it ae nen lee 28 OUTDOUNd Likas ai ts ea Gs 28 reset aia A e aan 104 PCI Express configuration SW4 1 41 PCI to PCI Express bridge a 24 P 7 9X110 lt ada Matu dalu RANG Ban Da i Kana 24 Pigeon Point Systems LL 45 extension commands aaa 52 pinout AMG connector LL iui aa a een 70 Cable nn morts ehe as Of na leet 88 console cable nennen nn nen 93 console serial port LL 88 dual VHDCI I O connector LL 88 ElA530 hydra cable coco oo e i ar 91 on dual VHDCI connector a 77 MPC8270 port A are rar in 97 POB ANAN en ee 98 POLO beacon nah a Diana hir 99 POD air Ren AA 100 RS232C hydra cable sesi en Bere less 89 on dual VHDCI connector a 74 RS422 hydra cable sakiniai NAG an 90 on dual VHDCI connector 22222 77 RS449 hydra Cable 5 dsguihae Sag TUTA wa nes 90 on dual VHDCI connector n 2222222 77 V 35 hydra cable iss sk ik evan eee e 92 on dual VHDCI connector
18. port 1 differential RS449 RT B ElA530 DD B B43 GND Signal Ground for I O connector B39 RXD A 2 Input 100 Ohms RS422 Receive Data port 2 differential RS449 RD A ElA530 BB A B38 RXD B 2 Input 100 Ohms RS422 Receive Data port 2 differential RS449 RD B ElA530 BB B B48 DTR A 2 Output NA RS422 DTR port 2 RS449 TR A ElA530 CD A 78 Table 5 5 RS422 RS449 EIA530 Signals and Pins Continued Serial I O Connector Pin Signal Direction Termination Description Name B47 DTR B 2 Output NA RS422 DTR port 2 RS449 TR B EIA530 CD B B45 TXD A 2 Output NA RS422 Transmit Data port 2 RS449 SD A EIA530 BA A B44 TXD B 2 Output NA RS422 Transmit Data port 2 RS449 SD B EIA530 BA B B11 RTS A 2 Output NA RS422 RTS port 2 RS449 RS A EIA530 CA A B10 RTS B 2 Output NA RS422 RTS port 2 RS449 RS B EIA530 CA B B14 TXC A 2 Output NA RS422 TXC port 2 RS449 TT A EIA530 DA A B13 TXC B 2 Output NA RS422 TXC port 2 RS449 TT B EIA530 DA B B8 TXCI A 2 Input 100 Ohms RS422 SCTE port 2 differential RS449 ST A EIA530 DB A B7 TXCI B 2 Input 100 Ohms RS422 SCTE port 2 differential RS449 ST B EIA530 DB B B5 DCD A 2 Input 100 Ohms RS422 DCD port 2 differential RS449 RR A EIA530 CF A B4 DCD B 2 Input 100 Ohms RS422 DCD port 2 differential RS449 RR B EIA530 CF B B36 DSR A 2 Input 100 Ohms RS422 DSR port 2 differential RS449 DM A EIA530 CC A
19. 4 Ground RS232 CC T27 CTS4 Input 5K to RS232C Clear to Send port 4 Ground RS232 CB T23 GND Signal Ground for l O connector RS232AB T67 RXC4 Input 5K to RS232C Receive Data Clock port 4 Ground RS232 DD Serial I O Connector RS422 RS449 Supported Signals This configuration supports the RS422 RS449 standard in a DTE format The ElA530 standard is also supported through a hydra cabling option Table 5 5 RS422 RS449 EIA530 Signals and Pins shows the supported signals and their positions on the dual VHDCI connector Note Some of the pins on the connector may not be included in the table For each electrical standard the pins that are not included in the table for that standard MUST BELEFT UNCONNECTED Table 5 5 RS422 RS449 EIA530 Signals and Pins 2 ignal eer kaaa HE Pin Signa Direction Termination Description Name B3 B6 B9 B12 Signal B15 B16 B19 Ground B20 B23 B26 B29 B32 B37 B40 B46 B49 B50 B53 B54 B60 B63 B66 T3 T6 T12 T15 T16 T19 T20 T26 T29 T32 T37 T40 T43 T46 T49 T50 T53 T54 T57 T60 T63 T66 B57 GND Signal Ground for I O connector B64 RXD A 1 Input 100 Ohms RS422 Receive Data port 1 differential RS449 RD A RSEIA530 BB A B65 RXD B 1 Input 100 Ohms RS422 Receive Data port 1 differential RS449 RD B EIA530 BB B B55 DTR A 1 Output NA RS422 DTR port 1 RS449 TR A EIA530 CD A B56 DTR B 1 Output NA RS422 DTR port 1 RS449 TR B EIA
20. 7 GND First Logic Ground 164 GND First Logic Ground 8 RSRVD8 Second Reserved n a 163 TX20 Third Port 20 TX 9 PWR Carrier First Payload Pwr 162 TX20 Third Port 20 TX 10 GND First Logic Ground 161 GND First Logic Ground 11 TX0 Third Port 0 TX 160 RX20 Third Port 20 RX 12 TXO Third Port O TX 159 RX20 Third Port 20 RX 13 GND First Logic Ground 158 GND First Logic Ground 14 RX0 Third Port O RX 157 TX19 Third Port 19 TX 15 RXO Third Port 0 RX 156 TX19 Third Port 19 TX 16 GND First Logic Ground 155 GND First Logic Ground 17 GA1 Carrier Second Geo Adar 1 154 RX19 Third Port 19 RX 18 PWR Carrier First Payload Pwr 153 RX19 Third Port 19 RX 19 GND First Logic Ground 152 GND First Logic Ground 20 TX1 Third Port 1 TX 151 TX18 Third Port 18 TX 21 TX1 Third Port 1 TX 150 TX18 Third Port 18 TX 22 GND First Logic Ground 149 GND First Logic Ground 23 RX1 Third Port 1 RX 148 RX18 Third Port 18 RX 24 RX1 Third Port 1 RX 147 RX18 Third Port 18 RX 25 GND First Logic Ground 146 GND First Logic Ground 26 GA2 Carrier Second Geo Addr 2 145 TX17 Third Port 17 TX 27 PWR Carrier First Payload Pwr 144 TX17 Third Port 17 TX 28 GND First Logic Ground 143 GND First Logic Ground 29 TX2 Third Port 2 TX 142 RX17 Third Port 17 RX 30 TX2 Third Port 2 TX 141 RX17 Third Port 17 RX 70 Table 5 2 AMC C
21. Ethernet Port Mapping rennen en ren 25 Table 2 2 MPC8270 Interrupt SourceS 0 0 0 eee 27 Table 2 3 Locally Generated Frequencies and Sources aaa 30 Table 3 1 SW3 1 Settings 4 aa dees be had da wed ee le ar RES 39 Table 32 SW3 2 SCUMOS ae een A ae a 40 Table 3 3 SW3 3 Settings r ls n bob de V S i as 40 Table 3 4 SW3 4 Settings ida en nes ea 40 Table 3 5 SW4 1 Sellnge cdas Hrn A Ja 41 Table 3 6 SW4 4 Settings sn a Hrn ee 41 Table 4 1 IPMI PICMG Command Subset Supported by the MMC Firmware 46 Table 4 2 IPMB Management Controller Device Locator Record o ooooooooooo 48 Table 4 3 MMC Device ID u ws ee ee eX 49 Table 4 4 MMC Sensors sms kaka nn k k a k bee eee kee eee 50 Table 4 5 PPS Extension Commands Supported by the MMC LL 53 Table 4 6 MMC Status Bits eee 54 Table 4 7 The lt interface IDs Parameter Values aa 55 Table 4 8 The lt interface properties gt Parameter Bit Fields ooooooooooooo 55 Table 4 9 MMC Debug Levels 1 i een nenn 56 Tables Table 4 10 The lt geographic address gt Parameter Bit FieldS oooooo ooo 59 Table 5 1 AMC335 Connector Assignments 0002 eee eee 69 Table 5 2 AMC Connector Pinout Likas 70 Table 5 3 Cable Type Indicator Pins Lakis 73 Table 5 4 RS232C Signals and Pins x oras 74 Table 5 5 RS422 RS449 EIA530 Signals and Pins lt aks 77 Tabl
22. FCLKA to the module The AMC 1 R2 0 specification reguires that FCLKA is e keyed The AMC335 is shipped from the factory configured for AMC 1 R2 0 e keying of FCLKA AMC 1 R1 0 carriers do not e key FCLKA If the AMC335 does not come out of reset when powered on it is likely that FCLKA is not configured properly for the specific carrier For more information about configuring FCLKA on this AMC335 please contact Performance Technologies Customer Support and Services Hard Reset 102 The hard reset signal PQ_HRESET is generated by the MPC8270 or the control logic PLD The MPC8270 generates the hard reset signal in response to the following triggers Power on reset e Push button reset Software watchdog reset if enabled Bus monitor reset if enabled Checkstop reset if enabled The effect of a hard reset on the processor is different to a power on reset For more information refer to the Reset chapter in the MPC8270 PowerQUICC II Family User s Manual from http www freescale com The signal runs between the MPC8270 and the control logic PLD The MPC8270 normally read its HRESET configuration settings from the boot Flash To force the MPC8270 to take the default settings no reset configuration cycles on the bus because the CPU is set to be a RESET slave change the RSTCONF Switch SW3 1 to OFF See SW3 1 Reset Configuration on page 39 for more information about this switch setting Hard Reset The
23. MSB Graceful Reboot Request If set to 1 indicates that the payload is requested to initiate the graceful reboot sequence The MMG firmware notifies the payload about changes of all status bits except for bits 0 2 by sending an unprintable character ASCII 07 BELL over the payload interface The payload is expected to use the Get Status command to identify pending events and other SIPL commands to provide a response if necessary The event notification character is sentin a synchronous manner and does not appear in the contents of SIPL messages sent to the payload The Get Status command has the following synopsis B8 xx 00 OA 40 00 The MMC responds to the Get Status command with the following reply BC xx 00 00 OA 40 00 lt status gt Serial Interface Subsystem Serial Line Properties Commands The SIPL provides commands to get set the properties of the MMC serial interfaces the serial debug interface and the payload interface Get Serial Interface Properties Command on page 55 Set Serial Interface Properties Command on page 55 Get Serial Interface Properties Command The Get Serial Interface Properties command is used to get the properties of a particular serial interface This command has the following synopsis B8 xx 01 0A 40 00 lt interface ID gt The lt interface ID gt parameter can have one of the values shown in Table 4 7 The lt interface ID gt Parameter Values
24. Port D Pin Assignments Table 6 4 MPC8270 Port D Pin Assignments Pin Pin Function PPARD 1 PSORD 0 PSORD 1 PPARD 0 PDIRD 1 Out PDIRD 0 In PDIRD 1 Out PDIRD 0 In PDIRD 1 Out PDIRD 0 In PD31 SCC1 RXD PD30 SCC1 TXD PD29 SCC1 RTS PD28 Default Unassigned PD27 Default Unassigned PD26 SCC2 RTS PD25 Defau It Unassigned PD24 Defau It Unassigned PD23 SCC3 RTS PD22 SCC4 RXD PD21 SCC4 TXD PD20 SCC4 RTS PD19 SCC1 DTR PD18 SCC2 DTR PD17 SCC3 DTR PD16 SCC4 DTR PD15 Default Unassigned PD14 Default Unassigned PD13 LT PORT 1 V 35 PD12 LT PORT 2 V 35 PD11 PD10 V 35 V 35 LT PORT 3 V 35 LT PORT 4 V 35 PD9 SMC1 SMTXD PD8 SMC1 SMRXD PD7 RIPORT 1 V 35 PD6 RI PORT 2 V 35 PD5 PD4 V 35 V 35 RI PORT 3 V 35 RI PORT 4 V 35 100 Chapter PP LAS AA AN Vse sm Xy NA Reset Overview This chapter discusses the various reset types and sources supported by the AMC335 Because many embedded systems have different requirements for module reset functions the incorporation of this sub system on the AMC335 has been designed to provide maximum flexibility Key topics i
25. This command has the following synopsis B8 xx 03 OA 40 00 The MMC responds to the Get Debug Level command with the following reply BC xx 03 00 OA 40 00 lt debug level gt The lt debug level parameter contains the bit fields shown in Table 4 9 MMC Debug Levels below Table 4 9 MMC Debug Levels Bit Name Description 0 LSB Error Logging Enable If set to 1 the MMC outputs error diagnostic messages onto the serial debug interface 1 Low level Error Logging Enable If set to 1 the MMC outputs low level error diagnostic messages onto the serial debug interface 2 Alert Logging Enable If set to 1 the MMC outputs important alert messages onto the serial debug interface 3 Payload Logging Enable If set to 1 the MMC provides a trace of SIPL activity on the payload interface onto the serial debug interface 4 IPMB Dump Enable If set to 1 the MMC provides a trace of IPMB messages that are arriving to going from the MMC via IPMB L 5 7 NA Reserved Set Debug Level Command To change the current debug level the Set Debug Level command must be used This command has the following synopsis B8 xx 04 OA 40 00 lt debug level gt Serial Interface Subsystem Payload Communication Timeout Some of the SIPL commands are subject to payload communication timeouts If the payload does not respond with a correct reply within a definite period of time the MMC assumes that a pay
26. V 35 Transmit Clock port 1 V 35 113 M 34 W 83 Chapter 5 Connectors 84 Table 5 6 V 35 Signals and Pins Continued ignal ey Baka At Pin Signa Direction Termination Description Name B27 TXCI A 1 Input 100 Ohms V 35 Transmit Clock In port 1 differential V 35 114 M 34 Y 125 Ohms to ground B28 TXCI B 1 Input 100 Ohms V 35 Transmit Clock In port 1 differential V 35 114 M 34 AA 125 Ohms to ground B30 DCD1 Input 5K Ohms to V 35 Data Carrier Detect port 1 ground V 35 109 M 34 F B31 RH Input 5K Ohms to V 35 Ring Indicator port 1 ground V 35 125 M 34 J B67 DSR1 Input 5K Ohms to V 35 Data Set Ready port 1 ground V 35 107 M 34 E B56 LT1 Output NA V 35 Line Test port 1 V 35 M 34 K B61 CTS1 Input 5K Ohms to V 35 Clear To Send port 1 ground N 35 106 M 34 D B33 RXC A 1 Input 100 Ohms V 35 Receive Clock port 1 differential V 35 115 M 34 V 125 Ohms to ground B34 RXC B 1 Input 100 Ohms V 35 Receive Clock port 1 differential V 35 115 M 34 X 125 Ohms to ground B39 RXD A 2 Input 100 Ohms V 35 Receive Data port 2 differential V 35 104 M 34 R 125 Ohms to ground B38 RXD B 2 Input 100 Ohms V 35 Receive Data port 2 differential V 35 104 M 34 T 125 Ohms to ground B48 DTR2 Output NA V 35 Data Terminal Ready port 2 V 35 108 M 34 H B45 TXD A 2 Output NA V 35 Transmit Data port 2 V 35 103 M 34 P B44 TXD B 2 Output NA V 35 Transmit Da
27. below Table 4 7 The lt interface ID gt Parameter Values Interface ID Description 0 Serial debug interface 1 Payload interface The MMC responds to the Get Serial Interface Properties command with the following reply BC xx 01 00 OA 40 00 lt interface properties gt The lt interface properties gt parameter has the bit fields shown in Table 4 8 The lt interface properties gt Parameter Bit Fields below Table 4 8 The lt interface properties gt Parameter Bit Fields Bits Name Description 0 3 Baud Rate ID The baud rate ID defines the interface baud rate as follows 0 9600 bps 1 19200 bps 2 38400 bps 3 57600 bps 4 115200 bps 4 6 NA Reserved 7 MSB Echo On If this bit is set the MMC enables echo for the given serial interface Set Serial Interface Properties Command The Set Serial Interface Properties command is used to change the properties of a given interface B8 xx 02 OA 40 00 lt interface ID gt lt interface properties gt 55 Chapter 4 System Monitoring and Alarms 56 Debug Verbosity Level The SIPL provides commands to enable and disable output of error diagnostic messages to the serial debug interface at runtime Get Debug Level Command on page 56 Set Debug Level Command on page 56 Get Debug Level Command To get the current debug level the Get Debug Level command must be used
28. by software This reset takes the bridge state machines to a known state but does not reset internal registers It also causes the propagation of the Local PCI reset signal as PERI_PCIRST This signal is connected to the control logic PLD and causes a hard reset to MPC8270 when the PCI Express link is enabled The PCI bus reset condition is sustained until the bit in the control register is reset This is the preferred method to cause a Software Reset of the AMC335 If the PCI Express link is not enabled a Software Reset can be caused by writing to the SRST bit in the PLD to send a soft reset to the MPC8270 only Refer to the Pericom PI7C9X110 PCI Express to PCI Reversible Bridge Data Sheet at the Pericom Web site for a complete description of this reset http www pericom com 105 Chapter 7 Reset 106 Chapter KP AAA AN AN N A eer ie Specifications Overview This chapter describes the electrical environmental and mechanical specifications of the AMC335 Reliability information is also provided in this chapter Key topics in this chapter include Absolute Maximum Ratings on page 107 Electrical Specifications on page 108 Environmental Specifications on page 108 Mechanical Specifications on page 109 Reliability on page 110 Absolute Maximum Ratings The values below are stress ratings only Do not operate the AMC335 at these maximums See Power Requirements on page 10
29. control logic PLD generates aPQ_HRESET signal in response to a system module reset from the local PCI reset issued by the PI7C9X110 PCI Express interface This happens only if the host system is not generating a PCI Express reset at the same time and the PCI Express link is enabled The control logic PLD also asserts aPQ_HRESET signal in response to the reception of an RS232C double BREAK signal on the console serial port This happens if the Break Detect Enable Switch SW3 3 is ON When the hard reset signal is asserted because of an RS232C double BREAK signal it remains asserted until the break signal is removed See SW3 3 Break Detect Enable on page 40 for more information about this switch setting 103 Chapter 7 Reset Soft Reset The soft reset for the module is accomplished by asserting the PQ_SRESET signal The signal is connected to the MPC8270 and the control logic PLD The signal source for soft reset signal is the MPC8270 The MPC8270 asserts this signal in response to any power on reset or hard reset condition The effect of soft reset on the processor is different to a power on reset or a hard reset Refer to the Reset chapter in the MPC8270 PowerQUICC II Family User s Manual from http www freescale com PCI Express Interface Resets 104 The PI7C9X110 PCI Express bridge has more than one reset condition each is described in the following topics Primary PCI Express Reset The PI7C9X110 receives
30. interfaces payload shutdown Payload Shutdown Set Payload 0x16 Serial debug and Set the timeout for Timeout Shutdown Timeout payload interfaces payload shutdown Get Geographic Ox1F Serial debug and Get the geographic Get Geographic Address payload interfaces address Address Command The MMC accepts all PPS extension commands listed in Table 4 5 from both serial interfaces as well as IPMB L This is done to achieve additional flexibility and extensibility in the MMC functionality The PPS extension commands listed in Table 4 5 are referred to as the SIPL commands throughout this document The following sections discuss the SIPL commands in more detail 53 Chapter 4 System Monitoring and Alarms 54 Get Status Command The MMC status is one byte describing the logical state of tne MMC and the payload Table 4 6 MMC Status Bits provides a description of the MMC status bits Table 4 6 MMC Status Bits Bit Name Description 0 LSB Control If set to 0 the MMC control over the payload is disabled 1 2 NA Reserved 3 Sensor Alert If setto 1 indicates that at least one ofthe MMC sensors detects threshold crossing Reset Alert If set to 1 indicates that the payload is going to be reset 5 Shutdown Alert If set to 1 indicates that the payload is going to be shut down 6 Diagnostic Interrupt Request If set to 1 indicates that a payload diagnostic interrupt request has arrived 7
31. on page 30 LED Indicators on page 31 Rear Panel I O on page 32 User Configurable Switches on page 32 NexusWare Software Support on page 33 Operating Systems on page 33 21 Chapter 2 Introduction Freescale MPC8270 PowerQUICC II Processor The AMC335 incorporates a Freescale MPC8270 PowerQUICC II integrated communications processor as the primary controller on the module The processor supplies the 266 MHz PowerPC CPU core the 200 MHz Communications Processor Module CPM and the 66 MHz external 60X single master bus It has direct connections to and is the controller for the Synchronous DRAM SDRAM and the PCI side of the PI7C9X110 PCI Express interface controller It controls all of the on board resources via a buffered data and address bus and a set of local control registers See Freescale MPC8270 PowerQUICC II Processor on page 117 for links to additional information and related documents for this device AMC Interface 22 The AMC335 is compliant with the PICMG Advanced Mezzanine Card AMC O Specification R2 0 lt is designed to be hot swappable into a mid or full size bay on an AMC carrier board such as Performance Technologies AMP507x MicroTCA platform see Figure 2 3 AMC335 in the AMP507x MicroTCA Platform on page 22 The AMC335 can also function in a non hot swap AMC system lts AMC card edge connector provides rear I O connectivity to the AMC bus in accorda
32. primary resets from the PCI Express root complex on the PCI Express bus via the PCE_PERST signal It resets all of the PI7C9X110 s internal logic as well as initializing the rest of the AMC335 s logic to the power on reset condition Refer to the Pericom PI7C9X110 PCI Express to PCI Reversible Bridge Data Sheet at the Pericom Web site for a complete description of this reset http www pericom com The MPC8270 PORESET signal is held true as long as the PCI Express reset is held true and the PCI Express link is enabled PCI Express Reset Levels There are two further PCI Express reset levels supported in the AMC335 configuration forward nontransparent Hot Reset Level 1 and Secondary Bus Reset Hot Reset Level 1 Hot Reset Level 1 is received by the PI7C9X110 in the form of a PCI Express in band message lt causes the reset of internal registers and state machines but does not cause the reset of sticky bits in the internal registers It also propagates across the PI7C9X110 and is output on the local PCI reset signal as PERI PCIRST This signal is connected to the control logic PLD and causes a hard reset to the MPC8270 Refer to the Pericom PI7C9X110 PCI Express to PCI Reversible Bridge Data Sheet at the Pericom Web site for a complete description of this reset http www pericom com PCI Express Interface Resets Secondary Bus Reset The Secondary Bus Reset is invoked by setting the internal Bridge Control and Status register
33. shifts from the MCP8270 to the MMC The logic that watches the console receive line is located in the control logic PLD The reset on break detect can be enabled by setting the Break Detect Enable Switch SW3 3 to ON Setting the switch to OFF disables the feature See SW3 3 Break Detect Enable on page 40 for more information Note The reset on break detect can still be enabled with a software settable PAL register bit The secondary Serial I O channel is used to communicate with the MMC MPC8270 Parallel Port Pin Assignments 96 The MPC8270 parallel ports are configured to support serial I O modem control interrupts and other module required functions The program settings for the parallel port pins can be found in the files init inc and hardware c Individual pin assignments for each port are shown in the following tables Table 6 1 MPC8270 Port A Pin Assignments on page 97 Table 6 2 MPC8270 Port B Pin Assignments on page 98 Table 6 3 MPC8270 Port C Pin Assignments on page 99 Table 6 4 MPC8270 Port D Pin Assignments on page 100 MPC8270 Port A Pin Assignments Table 6 1 MPC8270 Port A Pin Assignments MPC8270 Parallel Port Pin Assignments Pin Function PPARA 1 Pin PPARA 0 PSORA 0 PSORA 1 PDIRA 1 Out PDIRA 0 In PDIRA 1 Out PDIRA 0In PDIRA 1 Ou
34. the Get target upgrade capabilities response or the Self test capabilities field of the Upgrade Image header 5 The HPM 1 Query Rollback Status command is mandatory for IPM Controllers supporting automatic or manual Roll back 6 The HPM 1 Manual Firmware Rollback command is mandatory for IPM Controllers indicating manual firmware Rollback is supported in the Manual firmware Rollback capabilities field of the Get target upgrade capabilities response Device Locator Record 48 The MMC firmware supports the Get Device Locator Record ID command for FRU device 0 the only FRU device represented by an MMC The MMC firmware obtains the ID of the IPMB management controller device locator record by scanning the Sensor Data Records SDR embedded into the firmware Table 4 2 IPMB Management Controller Device Locator Record shows an example of an IPMB management controller device locator record SDR type 0x12 describing the properties of the MMC Table 4 2 IPMB Management Controller Device Locator Record Parameter Value Power State Notification ACPI System Power State notification required No ACPI Device Power State notification required No Global Initialization Controller logs Initialization Agent errors No Log Initialization Agent errors accessing this controller No Event Generation Enable event message generation from controller Device Capabilities Chassis Device No Bridg
35. u wre Na NAGA PANER AKA NANA GG 25 SDRAM Machine 2 2 2 ern nnnn 26 Sensor Data Records SDR aaa 48 sensor events interpreting Le za a AA io aa NA 50 SONSOMS AT a Aa MAP ASG a Hy t s 29 50 serial Cable pinout aii saneren Haan a ana 88 WO connection akiai 23 management controllers een 96 SMET area No pn 96 SMC cai amd 96 SIP a ne AAP 51 raw IPMI messages 2 51 terminal mode messages a 51 SOftresel china ne a NP AGAD PNG a tat 104 Index software supported aka aka aaa 33 Sola Pages wa tor Ble ae P ee 19 33 SUMED u a en alta pla ai ee ee 33 SW2 switch bank 000 cece eee 39 SW3 switch bank ern nnn 39 SW3 1 reset configuration Las 39 SW3 2 EEPROM write protect 40 SW3 3 break detect enable 40 SW3 4 application code enable 40 SW4 switch bank 200 0002 cece eee 41 SW4 1 PCI express configuration 41 SW4 2 not used LL 41 SW4 3 not used aaa 41 SW4 4 JTAG enable aa 41 switch descriptions 1 nennen 39 T temperature monitoring LL 109 text conventions 0 6 cece eee ence eee eens 14 transparent mode aaa 96 U universal asynchronous receiver transmitter UART mode 96 ja sce ee en ae nal ea 27 USER VO o Band ne he 23 V V 35 hydra cable options ooooooooooooonooooo 19 hydra cable pinout lt lt
36. 232 CD B58 TXD1 Output NA RS232C Transmit Data port 1 RS232 BA B24 RTS1 Output NA RS232C Request to Send port 1 RS232 CA B21 TXC1 Output NA RS232C Transmit Data Clock port 1 RS232 DA B27 TXCI1 Input 5K to RS232C Transmit Signal Element Timing 1 Ground RS232 DB B30 DCD1 Input 5K to RS232C Data Carrier Detect port 1 Ground RS232 CF B67 DSR1 Input 5K to RS232C Data Set Ready port 1 Ground RS232 CC B61 CTS1 Input 5K to RS232C Clear to Send port 1 Ground RS232 CB B57 GND Signal Ground for I O connector RS232 AB B33 RXC1 Input 5K to RS232C Receive Data Clock port 1 Ground RS232 DD Table 5 4 RS232C Signals and Pins Continued Serial I O Connector j ignal Su a pale os Pin Signa Direction Termination Description Name B39 RXD2 Input 5K to RS232C Receive Data port 2 Ground RS232 BB B48 DTR2 Output NA RS232C Data Terminal Ready port 2 RS232 CD B45 TXD2 Output NA RS232C Transmit Data port 2 RS232 BA B11 RTS2 Output NA RS232C Request to Send port 2 RS232 CA B14 TXC2 Output NA RS232C Transmit Data Clock port 2 RS232 DA B8 TXCI2 Input 5K to RS232C Transmit Signal Element Timing 2 Ground RS232 DB B5 DCD2 Input 5K to RS232C Data Carrier Detect port 2 Ground RS232 CF B36 DSR2 Input 5K to RS232C Data Set Ready port 2 Ground RS232 CC B42 CTS2 Input 5K to RS232C Clear to Send port 2 Ground RS232 CB B43 GND Signal Ground for I O connector RS232 AB B2 RXC2 I
37. 5 PICMG 2Dh Optional Mandatory HPM 1 Upgrade Commands HPM 1 Get Target Upgrade Capabilities 3 3 PICMG 2Eh Mandatory Get Component Properties 3 5 PICMG 2Fh Mandatory Abort Firmware Upgrade 3 15 PICMG 30h Optional Initiate Upgrade Action 3 8 PICMG 31h Optional Mandatory Upload Firmware Block 3 9 PICMG 32h Mandatory Finish Firmware Upload 3 10 PICMG 33h Mandatory Activate Firmware 3 11 PICMG 35h Mandatory Query Self Test Results 3 12 PICMG 36h Optional Mandatory 47 Chapter 4 System Monitoring and Alarms Table 4 1 IPMI PICMG Command Subset Supported by the MMC Firmware Continued Command Spec Ref NetFn CMD MMC Req Query Rollback Status 3 13 PICMG 37h Optional Mandatory Initiate Manual Rollback 3 14 PICMG 38h Optional Mandatory 1 See Device ID below for the device ID data retrieved in response to a Broadcast Get Device ID command for this module 2 See Device Locator Record below for the IPMB management controller device locator record retrieved in response to a Get Device Locator Record ID command for this module 3 The HPM 1 Initiate Upgrade Action command is mandatory for an IPM Controller indicating that any of its implemented components supports preparation for Firmware Upgrade or comparison of the current firmware 4 The HPM 1 Query Self test Results command is mandatory for IPM Controllers indicating self test is supported in the Self test capabilities field of
38. 530 CD B B58 TXD A 1 Output NA RS422 Transmit Data port 1 RS449 SD A EIA530 BA A B59 TXD B 1 Output NA RS422 Transmit Data port 1 RS449 SD B EIA530 BA B B24 RTS A 1 Output NA RS422 RTS port 1 RS449 RS A EIA530 CA A B25 RTS B 1 Output NA RS422 RTS port 1 RS449 RS B EIA530 CA B 77 Chapter 5 Connectors Table 5 5 RS422 RS449 EIA530 Signals and Pins Continued 3 ignal a er Ng Pin signa Direction Termination Description Name B21 TXC A 1 Output NA RS422 TXC port 1 RS449 TT A EIA530 DA A B22 TXC B 1 Output NA RS422 TXC port 1 RS449 TT B EIA530 DA B B27 TXCI A 1 Input 100 Ohms RS422 SCTE port 1 differential RS449 ST A EIA530 DB A B28 TXCI B 1 Input 100 Ohms RS422 SCTE port 1 differential RS449 ST B ElA530 DB B B30 DCD A 1 Input 100 Ohms RS422 DCD port 1 differential RS449 RR A ElA530 CF A B31 DCD B 1 Input 100 Ohms RS422 DCD port 1 differential RS449 RR B ElA530 CF B B67 DSR A 1 Input 100 Ohms RS422 DSR port 1 differential RS449 DM A ElA530 CC A B68 DSR B 1 Input 100 Ohms RS422 DSR port 1 differential RS449 DM B ElA530 CC B B61 CTS A 1 Input 100 Ohms RS422 CTS port 1 differential RS449 CS A ElA530 CB A B62 CTS B 1 Input 100 Ohms RS422 CTS port 1 differential RS449 CS B ElA530 CB B B33 RXC A 1 Input 100 Ohms RS422 RXC port 1 differential RS449 RT A ElA530 DD A B34 RXC B 1 Input 100 Ohms RS422 RXC
39. 8 for actual operating conditions Supply Voltage Vcc12 12 V 10 14 V Supply Voltage Vcc3 3 3 V 3 0 3 6 V Storage Temperature 20 C to 80 C 4 F to 176 F Non Condensing Relative Humidity 5 to 90 RH 107 Chapter 8 Specifications Electrical Specifications This section describes the electrical requirements for the AMC335 Power Requirements The power distribution network on the AMC335 starts with the AMC card edge interface connecting to an AdvancedTCA or MicroTCA based platform The power pins are connected per the PICMG Advanced Mezzanine Card AMC O Specification R2 0 The voltages supplied are 3 30 V management and 12 V Maximum and typical operating power requirements are shown in Table 8 1 Power Consumption with 266 MHz Processor below Table 8 1 Power Consumption with 266 MHz Processor Typical Power Maximum Power Required Required Power Toleran Power Voltage Source olerance Current owe Current 12 V AMC B connector 25 0 875 A 10 5 W 11A 13 2 W 3 30 V MGNT AMC B connector 5 0 05 A 0 165 W 0 0525 A 0 173 W Total Power 10 665 W 13 373 W A Caution Use anti static grounding straps and anti static mats when you are handling the AMC335 to help prevent damage due to electrostatic discharge Electronic components on printed circuit boards are extremely sensitive to static electricity Ordinary amounts of static electricity generated by your clot
40. 9 Chapter 5 Connectors AdvancedMC Card Edge Connector The AMC connector provides the electrical interface between the AMC335 and the MicroTCA enclosure or ATCA carrier board The AMC connector is fixed to the enclosure or carrier board and the card edge interface at the back of the AMC335 plugs into it There are different styles of connectors for the different types of AMC bays and for different levels of connectivity The card edge interface on the AMC335 is compatible with the extended 170 pin B style connector found on Performance Technologies AMP507x MicroTCA platform Besides power and ground the AMC335 card edge interface routes two SerDes 1Gb Ethernet channels PCI Express x1 bus and System Management Bus SMB to the AMC connector See Table 5 2 AMC Connector Pinout on page 70 for pin definitions Table 5 2 AMC Connector Pinout Pin Signal aa Mating kivi Pin Signal a Mating K we on 1 GND First Logic Ground 170 GND First Logic Ground 2 PWR Carrier First Payload Pwr 169 TDI Carrier Second JTAG Test Data Input 3 PS1 Module Last Presence 1 168 TDO Module Second JTAG Test Data Output 4 MP Carrier First Mgmt Power 167 TRST Carrier Second JTAG Test Reset Input 5 GAO Carrier Second Geo Addr 0 166 TMS Carrier Second JTAG Test Mode Select In 6 RSRVD6 Second Reserved n a 165 TCK Carrier Second JTAG Test Clock Input
41. ANOS 4 44 asilas S ara nen a el 63 firmware upgrade Las 60 VO CONTIQUIALIONS Ss nude users 18 i o ports on MPC8270 1 aa 95 in service LED cuotas cas ar au na a eee eee Ch ee 31 installation waht e i ad neuer 42 interrupt MPG8270 ee Den re Ae a 27 SOCOS 4 kd ents degli copter E Mt a ae s 27 IPM nrg 4 A eee ere tate ee 45 communication utility o oo ooo oooooo o 61 POMO cinc ran ran 61 WILS firmware aa ee ana ul 45 Tel tojo PAA E A 61 accessing an MMC via serial interface 63 accessing an MMC via shelf manager 62 building a oi a Soh Ph PAD Da ee AR 61 for HPM 1 upgrades lt 63 JacKpost un unsern nana re een 20 43 lackserewW ee ana an 20 43 JTAG enable SW4 4 nenn 41 JTAGUENAN Veen aka man dung stati pan i S NE Ng aa 41 maximum power dissipation lt lt 36 mechanical specifications lt 109 MEMON Atos a Adi ol d 25 ME AAA AA 26 MMG rs ra ENDE 29 device record locator LL 48 devicelD rociar id batr a a a a 49 firmware upgrade eee eee 59 TUNGLONS Ha nn fu ln ka gd a aaa Aetra een 45 TOSO AA AA AN 102 SENSORS adi ict a na a saita d A asta na Gat sda 50 supported commands seen nennen 46 MP682702 ausa at ne ne 22 interrupts an a Saj NG NAG A a GA an 27 parallel port pinout een 96 BOrEKA PINOUL is na een nand Anon sm palanan 97 port Bipot riai a ee BRA enge 98 122 0 P port G PINOUL u ein Se ea ea 99 port D PIQUE
42. Automatic rollback timeout Rollback timeout timeout 4 HB BB Bi Bukaka A none T 0x82 B 0 t 0x74 b 7 hpm compprop Firmware Upgrade Process Get the specified component properties This command can be used to find out component specific properties ipmitool hpm compprop lt id gt lt select gt The lt id gt parameter specifies the component whose properties are read 0 corresponds to the firmware component and 1 corresponds to the boot loader component The lt select gt parameter specifies the property that should be acquired The properties are the following 0 1 2 3 4 Example ipmitool I compprop 0 PICMG HPM 1 GENERAL PROF General properties Current firmware version Description string Rollback firmware version Deferred firmware version lan H 192 168 0 2 A none T 0x82 Upgrade Agent 1 0 ES Payload col Def ac Comparison support Preparat tiva tion supported Rollback supported t req y upported y CEG ea zu n y y B O t 0x74 b 7 hpm 65 Chapter 4 System Monitoring and Alarms 66 upgrade Upgrade the firmware with the specified image This command can be used to upgrade the firmware using a valid HPM 1 image ipmitool hpm upgrade lt file gt activate The lt file gt parameter specifies the name of the HPM 1 upgrade image
43. B byte of timeout gt lt MSB byte of timeout gt The payload shutdown timeout is measured in hundreds of milliseconds and stored as a 2 byte integer The default value of the payload shutdown timeout is specified by a dedicated Configuration Parameter Set Payload Shutdown Timeout Command To change the payload shutdown timeout the Set Payload Shutdown Timeout command is used B8 xx 16 OA 40 00 lt LSB byte of timeout gt lt MSB byte of timeout gt Firmware Upgrade Process Get Geographic Address Command The MMC allows reading the geographic address of the module using the Get Geographic Address command which has the following synopsis B8 xx 1F 0A 40 00 The MMC responds to the Get IPMB Address command with the following reply BC xx 1F 00 OA 40 00 lt geographic address gt The lt geographic address gt parameter has the bit fields shown in Table 4 10 The lt geographic address gt Parameter Bit Fields below Table 4 10 The lt geographic address gt Parameter Bit Fields Bits Name Description 0 1 GAO Signal 0 GAO is grounded 1 GAO is unconnected 3 GAO is pulled up 2 3 GA1 Signal 0 GA1 is grounded 1 GA1 is unconnected 3 GA1 is pulled up 4 5 GA2 Signal 0 GA2 is grounded 1 GA2 is unconnected 3 GA2 is pulled up 6 7 NA Reserved Firmware Upgrade Process The MMC firmware supports a reliable field upgrade procedure compatible with the
44. C8270 is bi directional The Transmit Clock of any serial channel may be sourced from the MPC8270 s transmit clock signals TXCn or from the serial port s transmit clock in signal TXCIn LED Indicators The LEDs located on the AMC335 front panel are defined below See Figure 2 1 AMC335 Front Panel on page 20 for the location of these LEDs Out of Service OOS and In Service IS LEDs These LEDs are used to indicate an out of service condition or an in service status per the PICMG Advanced Mezzanine Card AMC O Specification R2 0 Although these LEDs are managed by the MMC a carrier manager or shelf manager can override the MMC s local LED settings The OOS LED is activated to indicate that the payload is known to be out of service payload power is off held in reset or faulted in a way that precludes operation Otherwise the OOS LED is off The health of the board cannot be inferred solely from the state of this LED The default local color of the OOS LED is determined by FRU data and is configurable as either red or amber Contact Performance Technologies Customer Support for information about configuring this color The IS LED is activated when the OOS LED is turned off It is never turned on when the OOS LED is on The IS LED is green when all sensors are within the critical thresholds or amber when one or more sensors have exceeded a critical threshold Board Status APP LED The front panel includes one appl
45. Connectors EIA530 Hydra Cable Connector A hydra cable providing four 25 pin D shell DB 25 DTE with male connectors pins is available for the AMC335 ElA530 model The pin assignments for the EIA530 hydra cable are shown in Table 5 10 ElA530 Hydra Cable Connector Pinout below Duplicate each pin four times to create the hydra cable for ports 1 4 Table 5 10 ElA530 Hydra Cable Connector Pinout Pin Signal Name Description 1 CGND Cable Shield 2 TXD Transmit Data 3 RXD Receive Data 4 RTS Request To Send 5 CTS Clear To Send 6 DSR Data Set Ready 7 GND Signal Ground 8 DCD Data Carrier Detect 9 RXC Receive Clock 10 DCD Data Carrier Detect 11 TXC Transmit Clock 12 TXClz Transmit Clock In 13 CTS Clear To Send 14 TXD Transmit Data 15 TXCI Transmit Clock In 16 RXD Receive Data 17 RXC Receive Clock 18 No connection 19 RTS Request To Send 20 DTR Data Terminal Ready 21 No connection 22 DSR Data Set Ready 23 DTR Data Terminal Ready 24 TXC Transmit Clock 25 No connection 91 Chapter 5 Connectors V 35 Hydra Cable Connector A hydra cable providing four 34 pin DTE with male connectors pins is available for the AMC335 V 35 model The pin assignments for the V 35 hydra cable are shown in Table 5 11 V 35 Hydra Cable Connector Pinout below Duplicate each pin four times to create the hydra cable fo
46. Connectors RS449 RS422 Hydra Cable Connector A hydra cable providing four 37 pin D shell DB 37 DTE with female connectors pins is available for the AMC335 RS449 RS422 model The pin assignments for the RS422 RS449 hydra cable are shown in Table 5 9 RS449 RS422 Hydra Cable Connector Pinout below Duplicate each pin four times to create the hydra cable for ports 1 4 Table 5 9 RS449 RS422 Hydra Cable Connector Pinout Pin Signal Name Description 1 CGND Cable Shield 2 No connection 3 No connection 4 TXD Transmit Data 5 TXCI Transmit Clock In 6 RXD Receive Data 7 RTS Request To Send 8 RXC Receive Clock 9 CTS Clear To Send 10 No connection 11 DSR Data Set Ready 12 DTR Data Terminal Ready 13 DCD Data Carrier Detect 14 No connection 15 No connection 16 No connection 17 TXC Transmit Clock 18 No connection 19 GND Signal Ground 20 No connection 21 No connection 22 TXD Transmit Data 23 TXCI Transmit Clock In 24 RXD Receive Data 25 RTS Request To Send 26 No connection 27 CTS Clear To Send 28 No connection 29 DSR Data Set Ready 30 DTR Data Terminal Ready 31 DCD Data Carrier Detect 32 No connection 33 No connection 34 RXC Receive Clock 35 TXC Transmit Clock 36 No connection 37 No connection 90 Serial Cable
47. HPM 1 Specification The key features of the firmware upgrade procedures are as follows HPM 1 The upgrade can be performed over the serial debug payload interface or over IPMB L The upgrade procedure is performed while the MMC firmware is online and operating normally Upgrades of the firmware component are reliable A failure in the download error or interruption does not disturb the MMC s ability to continue using the old firmware or its ability to restart the download process Upgrades of the boot loader component are not reliable and may render the MMC non functional in case of an incomplete upgrade Upgrades of the firmware component are reversible The MMC firmware automatically reverts back to the previous firmware if there is a problem when first running the new code and can be reverted manually using the HPM 1 defined Manual Rollback command Upgrades of the boot loader component are not reversible Boot Loader The HPM 1 boot loader does not perform any upgrade actions The HPM 1 boot loader is able to boot either of two redundant copies of the MMC firmware in flash The HPM 1 boot loader is able to automatically rollback a failed copy of the MMC firmware and activate the backup one The HPM 1 boot loader can be upgraded in field as an HPM 1 upgradeable component 59 Chapter 4 System Monitoring and Alarms HPM 1 Firmware Upgrade The HPM 1 upgrade procedure is managed by a utility called the upgrade agent The ipm
48. Industry Canada Class A Notice This Class A digital apparatus complies with Industry Canada s Equipment Standard for Digital Equipment ICES 003 Cet appareil num rique de la classe A est conforme la norme NMB 003 du Canada Product Safety Information Safety Precautions Review the following precautions to avoid injury and prevent damage to this product or any products to which it is connected To avoid potential hazards use the product only as specified Read all safety information provided in the component product user manuals and understand the precautions associated with safety symbols written warnings and cautions before accessing parts or locations within the unit Save this document for future reference 113 Chapter 9 Agency Approvals 114 AN Caution To Avoid Burns If there is a heat sink on this module it can get very hot during normal operation To avoid burns take extra care when removing the module from the chassis soon after shutdown Wait a few minutes to allow the heat sink to cool down Caution Handling the Module It is important to hold the module only by the front panel or PCB edges Avoid touching any components unless necessary to service the product Do not handle the heat sink as this can adversely affect the thermal connection between the heat sink and the processor and cause the processor to overheat under normal operating conditions Caution To Avoid Electric Overload To avoid ele
49. MC firmware implements a communication protocol over the payload and or serial debug interfaces The communication is in the form of formatted ASCII strings The Serial Interface Protocol Lite SIPL is based on the IPMI defined Terminal Mode of the serial modem interface The following sections describe the SIPL Terminal Mode Messages and Commands on page 51 Terminal Mode Line Editing on page 52 Supported PPS Extension Commands on page 53 Terminal Mode Messages and Commands Terminal Mode Message Format Terminal Mode messages have the following format lt message data gt lt newline gt The left bracket and the right bracket plus lt newline gt characters serve as START and STOP delimiters for a message The MMC does not support multi line IPMI messages Raw IPMI Messages The SIPL supports raw IPMI messages that are entered as sequences of case insensitive hex ASCII pairs each pair optionally separated from the previous one with a single lt space gt character What follows are examples of raw IPMI request messages in Terminal Mode 18 00 22 lt newline gt 180022 lt newline gt The MMC handles raw IPMI messages in the same way as it handles IPMI PICMG AMC messages coming from the IPMB L bus and with the exception that IPMI PICMG AMC replies are routed to the interfaces from which the respective requests have come i e either the serial debug or payload interface of the MMC Terminal Mo
50. Ohms V 35 Receive Clock port 3 differential V 35 115 M 34 X 125 Ohms to ground T30 RXD A 4 Input 100 Ohms V 35 Receive Data port 4 differential V 35 104 M 34 R 125 Ohms to ground T31 RXD B 4 Input 100 Ohms V 35 Receive Data port 4 differential V 35 104 M 34 T 125 Ohms to ground T21 DTR4 Output NA V 35 Data Terminal Ready port 4 V 35 108 M 34 H T24 TXD A 4 Output NA V 35 Transmit Data port 4 V 35 103 M 34 P T25 TXD B 4 Output NA V 35 Transmit Data port 4 V 35 103 M 34 S T58 RTS4 Output NA V 35 Request To Send port 4 V 35 105 M 34 C T23 GND4 NA V 35 port 4 Signal Ground V 35 102 M 34 B T55 TXC A 4 Output NA V 35 Transmit Clock port 4 V 35 113 M 34 U T56 TXC B 4 Output NA V 35 Transmit Clock port 4 V 35 113 M 34 W Table 5 6 V 35 Signals and Pins Continued Serial I O Connector 4 ignal s Baka At Pin Signa Direction Termination Description Name T61 TXCI A 4 Input 100 Ohms V 35 Transmit Clock In port 4 differential V 35 114 M 34 Y 125 Ohms to ground T62 TXCI B 4 Input 100 Ohms V 35 Transmit Clock In port 4 differential V 35 114 M 34 AA 125 Ohms to ground T64 DCD4 Input 5K Ohms to V 35 Data Carrier Detect port 4 ground N 35 109 M 34 F T65 RI4 Input 5K Ohms to V 35 Ring Indicator port 4 ground V 35 125 M 34 J T33 DSR4 Input 5K Ohms to V 35 Data Set Ready port 4 ground N 35 107 M 34 E T22 LT4 Output NA V 35 Line Test port 4 V 35
51. Specifications on page 108 The AMC335 operates between 0 C 32 F and 60 C 140 F ambient temperature It is the user s responsibility to ensure that the AMC335 is installed in a chassis capable of supplying adequate airflow External airflow must be provided at all times See Chapter 8 Specifications on page 107 for more details The maximum power dissipation is 3W peak generated by the MPC8270 and the linear regulator creating its core voltage In a normal environment where the ambient temperature does not exceed the thermal operating range a heat sink is not required by the AMC335 However a heat sink may be employed to give the module a thermal margin beyond its normal operating range Contact Performance Technologies Customer Support and Services for more information Connectivity A Warning Operating the AMC335 without adequate airflow may damage the processor The AMC335 may contain environmentally hazardous materials You must make sure that you dispose of any such materials in accordance with your local rules and regulations For disposal and recycling information contact your local authorities or the Electronic Industries Alliance EIA at http www eiae org Performance Technologies Compliance with RoHS and WEEE Directives statement is on page 115 Connectivity The AMC335 provides a dual VHDCI connector for interfacing with application specific devices Refer to Chapter 5 Connectors on pag
52. Technologies distributor or agent for support Many of our distributors or agents maintain technical support staffs Customer Support Packages Our configurable development and integration support packages help customers maximize engineering efforts and achieve time to market goals To find out more about our Customer Support packages visit http www pt com page support Other Web Support Support for existing products including manuals release notes and drivers can be found on specific product pages at http www pt com Use the product search to locate the information you need Return Merchandise Authorization RMA To submit a return merchandise authorization RMA request complete the online RMA form available at http pt com assets lib files rma request form doc and follow the instructions on the form You will be notified with an RMA number once your return request is approved Shipping information for returning the unit to Performance Technologies will be provided once the RMA is issued Chapter 1 About This Guide Product Warranty Performance Technologies Incorporated warrants that its products sold hereunder will at the time of shipment be free from defects in material and workmanship and will conform to Performance Technologies applicable specifications or if appropriate to Buyer s specifications accepted by Performance Technologies in writing If products sold hereunder are not as warranted Performance Techn
53. Technologies Inc Web site to obtain manual revisions or current customer information http www pt com Performance Technologies Inc reserves its right to change product specifications without notice Symbol Conventions The following symbols appear in this document AN Caution There is risk of equipment damage Follow the instructions A Warning Hazardous voltages are present To reduce the risk of electrical shock and danger to personal health follow the instructions A Caution Electronic components on printed circuit boards are extremely sensitive to static electricity Ordinary amounts of static electricity generated by your clothing or work environment can damage the electronic equipment We recommended using anti static groundig straps and anti static mats when installing the board in a system to help prevent damage due to electrostatic discharge AE E NA AA Gr Chapter 1 About This Guide 13 E Ie 13 TEX Conventions necks sera K ia e ada DE id AA 14 Customer Support and Services rennen een een 15 Customer Support Packages nennen nn 15 Other Web Support A 464 sk sis ee RAANG 15 Return Merchandise Authorization RMA seen een 15 PFOAUEL W arranty 254640 oda a is as aa sa sine 16 Chapter 2 Introduction 17 OvervieW 2c Becca aa en en ae V a Jai eg JA PE as wad 17 Product Definition 65 a is Ms ei S D eee eee wees 17 AMGC335 Features anne 19 ANG339 Fr nt Panel sores a
54. Unassigned PB19 Default Unassigned PB18 Default Unassigned PB17 Default Unassigned PB16 Default Unassigned PB15 SCC2 RXD PB14 SCC3 RXD PB13 Default Unassigned PB12 SCC2 TXD PB11 Default Unassigned PB10 Default Unassigned PB9 Default Unassigned PB8 SCC3 TXD PB7 DSR PORT 1 PB6 DSR PORT 2 PB5 DSR PORT 3 PB4 DSR PORT 4 98 MPC8270 Port C Pin Assignments Table 6 3 MPC8270 Port C Pin Assignments MPC8270 Parallel Port Pin Assignments Pin Function PPARC 1 Pin PPARC 0 PSORC 0 PSORC 1 PDIRC 1 Out PDIRC 0 In PDIRC 1 Out PDIRC 0 In PDIRC 1 Out PDIRC 0 In PC31 BRG1 BRGO PC30 Default Unassigned PC29 BRG2 BRGO SCC1 TXCLK PC28 SCC1 RXCLK PC27 SCC3 TXCLK BRG3 BRGO PC26 SCC3 RXCLK PC25 SCC4 TXCLK BRG4 BRGO PC24 SCC4 RXCLK PC23 Default Unassigned PC22 Default Unassigned PC21 SCC2 TXCLK PC20 SCC2 RXCLK PC19 Default Unassigned PC18 Default Unassigned PC17 JTAG_SDRAM_CLK PC16 Default Unassigned PC15 SCC1 CTS PC14 SCC1 CD PC13 SCC2 CTS PC12 SCC2 CD PC11 SCC3 CTS PC10 SCC3 CD PC9 SCC4 CTS PC8 SCC4 CD PC7 Default Unassigned PC6 Default Unassigned PC5 Default Unassigned PC4 Default Unassigned PC3 WAKE1 PC2 WAKE2 PC1 WAKE3 PCO WAKE4 99 Chapter 6 MPC8270 Parallel I O Ports MPC8270
55. W3 2 Settings SW3 2 Description Factory Setting OFF Open The PI7C9X110 s boot EEPROM is write protected ON Closed The PI7C9X110 s boot EEPROM can be written to by using the Default PI7C9X110 s internal programming register SW3 3 Break Detect Enable SW3 3 BRK_DET_EN is used to enable or disable a hard reset whenever a double break signal is sent to the AMC335 over the console serial port See Table 3 3 for switch settings The default factory setting is OFF Table 3 3 SW3 3 Settings SW3 3 Description Factory Setting OFF Open HRESETH is disabled Default ON Closed The control logic PLD enables a HRESET whenever a double break signal is sent to the AMC335 over the console serial port A break character enter or b for example shifts the console focus from the MPC8270 to the MMC SW3 4 Application Code Enable SW3 4 FACT JMPRA is used to configure the loading and execution of any application code that is present in the application flash See Table 3 4 for switch settings The default factory setting is ON Table 3 4 SW3 4 Settings SW3 4 Description Factory Setting OFF Open Disable the loading and execution of any application code that is present in the application flash ON Closed Enables the boot code to load and execute any application code Default that is present in the application flash Switches SW4 Switch Bank SWA al
56. agnetic Fields EN61000 4 11 Voltage Dips Variations and Short Interruptions 112 Safety Safety The product described in this manual meets the following safety regulations EN IEC 60950 Safety Requirements for Information Technology Equipment CB Scheme CB Scheme Certificate and Report UL60950 UL Recognized FCC USA Class A Notice 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 limits 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 Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense This device complies with Part 15 of the FCC Rules Operation is subject to the following two conditions 1 This device may not cause harmful interference and 2 This device must accept any interference received including interference that may cause undesired operation Note Modifications made to this device that are not approved by Performance Technologies Inc may void the authority granted to the user by the FCC to operate this equipment
57. ale MPC8270 PowerQUICC II Processor on page 117 for a link to this manual Any port pins that do not have a dedicated function in the AMC335 configuration should be configured as an output and set to either a high or low This eliminates the potential for an unterminated input that could create severe current draw and electrical noise within the part if it were floating Serial Management Controllers The MPC8270 features two general purpose serial management controllers SMC1 and SMC2 that may be used as general purpose RS232C communications interfaces The two SMCs are full duplex ports that can be configured independently to support one of three operating or modes Universal Asynchronous Receiver Transmitter UART Transparent General Circuit Interface GCI The AMC335 is designed to support UART operation on two ports one console and one MMC The default point for console access is through the dual VHDCI connector when the module is installed in a system An additional connection is available through a three pin header located on the top side of the AMC335 providing connectivity to the SMC which is configured as the console serial port The console serial port can be used to provide a debug monitor or download function The console serial port also has the ability to generate a PQ HRESET N if it receives two RS232 break signals that each lasts for longer than 13 ms If a break and a character is received the console focus
58. apea ena sa ss RL S an L ba Gee ejas 20 AMG335 Functional Blocks sir rociar ea S 21 Freescale MPC8270 PowerQUICC II Processor Ls 22 AMC ERAP na sg 22 Ser Gass vs ee O ee Had BUONG 23 PCI Express Interface ss as aa 24 Ethernet Interfaces sado us k ea sin LL 25 MEMO 12462284 245055 5 5 L ISA m RED LSS LiL bittet 25 INTSIUPISOUICES tenure nape WAG KAN NG beh ee Eee eee a ESET 27 Contents Module Management Controller 0 cece tee 29 R s tssese Seimi pis sasn dd beds PAA ee eben ne 30 Board Clocks and Frequencies x aa e425 a ana Va ada j I a 30 CIO SESINO sis A edits tadas ae aa 30 LED ale e io ee Cale ga Aa AA 31 Rear PanellD ur see i i uae Dean g na am 32 User Contigurable Switches ii ERA re ED Ham tk 32 Software SUpport brist rra a en la ss rags reise 33 NexusWare Software Support Liaukis oye en er nr 33 Operating Sysiems 2 4 tags saak enden ee edd ie or dae E 33 Chapter 3 Getting Started 35 OVGIWIOW an ri das a pesa e ad Bac a do Blast a od des ne Sa oe BU 35 LINDACKING tt n AR TA AE DA 35 System Requiremenis ceerd sasaites ee ana ds 36 Compatibility ar REN RT E A ta 36 Electrical and Environmental Requirements oooocccooooo eee 36 Benas a ee ee a ira la at URE 37 AA a ee 37 SWZ OWN BAR nn e e BS a ln da Sa KA Oca U AA 39 SW3 Switch Bank ug A a i S L 39 SW4 Switch Bank ss asas edge ads ad BAG md tE 41 Push Button Reset Switch 140 resns AAA ih 42 Hot Swap Handle Switch ve
59. are inherited by the next level of management MicroTCA MCMC or AMC carrier IPMC and sensor IDs are reassigned Table 4 4 MMC Sensors Lower Non Lower Lower Non Upper Non Upper Upper Non Sensor ID Description Recoverable Critical Critical Critical Critical Recoverable Threshold Threshold Threshold Threshold Threshold Threshold 1 3 3 V MGMT 3V 3 068 V 3 135 V 3 465 V 3 533 V 3 6 V 2 12V 10V 10 4 V 10 8 V 13 2 V 13 6 V 14V 3 1 203 V 1 083 V 1 113 V 1 143 V 1 263 V 1 293 V 1 323 V 4 1 5 V 1 35 V 1 388 V 1 425 V 1 575 V 1 613 V 1 65 V 5 3 3 V 2 97 V 3 053 V 3 135 V 3 465 V 3 548 V 3 63 V 6 1 8V 1 62 V 1 665 V 1 71V 1 89 V 1 935 V 1 98 V 7 1 8 V CPLD 1 7 V 1 72 V 1 739 V 1 861 V 1 88 V 1 9 V 8 2 546 V 2 291 V 2 355 V 2 419 V 2 673 V 2 737 V 2 801 V 9 BMC Watchdog NA NA NA NA NA NA 10 Version Change NA NA NA NA NA NA 11 CPU Temp 5 C 0 C 5 C 65 C 85 C 95 C 12 Inlet Temp 5 C 0 C 5 C 50 C 70 C 80 C Interpreting Sensor Events 50 The ATCA specification includes the following definitions for the sensor event severity levels IPMI non critical PICMG 3 0 minor telco minor a warning that things are somewhat out of normal range but not really a problem yet See Non Critical Events below IPMI critical PICMG 3 0 major telco major things are still in valid operating range but are getting close to the edge unit still operati
60. auris a ai ns kot var A a RG as jas vi ru r 42 Physicalilnstalalion 2 zone UA DAA 42 Installing the AMC335 st oa SS SE CS JS E Es ee 42 Removing the AMC335 csi 43 Connecting the Cable u os sn sk eed va 43 Chapter 4 System Monitoring and Alarms 45 OYENIEW 22 tada ras en NG a ANG NG he ee 45 MIMIC FUNCTIONS sco thse e BA LIA BANYO baa NAG naag Due a i ats ju UA EG 45 Contents Summary of Supported Commands 000 eee eee 46 Device Locator Record Likusius sa ss bejs e BB a ga Ps o ij 48 Device Da ga Gb hak eed d aaa L ee whee k a 8S hn 49 BENSON Ta ata kaima das Ba dat S na A a la a NA 50 Interpreting SensorBEventst ansehen en 50 Serial Interface Subsystem Sora ir nern Fa a a 51 Terminal Mode Messages and Commands ernennen 51 Terminal Mode Line Editing skust ra k He ann due 52 Supported PPS Extension Commands 0 000 c cece eee n nenn nn 53 Firmware Upgrade Process unir ott ae im ae ende ben 59 FHEM 1 B60oYE6 d6 urea aa 59 HPM 1 Firmware Upgrade cos aaa eo re ie 60 parade Ulsa a e Sk dd a o S DS NSS DY 60 Detailed HPM 1 Upgrade Procedure nennen nen 60 IPMI Communication Utility ipmitool o oooococccoccco nenn 61 Chapter 5 Connectors 69 OUEN an ae ee seansi sa Wa Ben Nena en DA 69 AdvancedMC Card Edge Connector 2 222 nennen nennen nennen 70 Serial O Connector o ia aa Deo Ka De e Ue sd 73 RS232C Supported Signals Ks akis ns ri i i a Bh ee 74 RS422 RS449 Supported Signals
61. ble is plugged into the I O port The decode of these pins can be read by the software package supplied for the module in the Flash Sector Protect BUSY RDY and Cable Type register Table 5 3 Cable Type Indicator Pins describes the cable type mappings Table 5 3 Cable Type Indicator Pins PIN T51 Cabtyp3 PIN T52 Cabtyp2 PIN B51 Cabtyp1 PIN B52 Cabtyp0 Cable Type 1 1 1 1 Cable Unplugged 1 0 0 0 RS422 DTE 0 1 0 0 RS232C DTE 1 1 0 0 V 35 DTE 1 0 0 0 ElA530 73 Chapter 5 Connectors RS232C Supported Signals 74 This configuration supports the RS232C standard in a DTE format Table 5 4 RS232C Signals and Pins shows the supported signals and their positions on the dual VHDCI connector Note Some of the pins on the connector are not included in the table For each electrical standard the pins that are not included in the table for that standard MUST BE LEFT UNCONNECTED Table 5 4 RS232C Signals and Pins L ignal re ae mad Pin Signa Direction Termination Description Name B3 B6 B9 Signal B12 B15 Ground B16 B19 B20 B23 B26 B29 B32 B37 B40 B46 B49 B50 B53 B54 B60 B63 B66 T3 T6 T12 T15 T16 T19 T20 T26 T29 T32 T37 T40 T43 T46 T49 T50 T53 T54 T57 T60 T63 T66 B64 RXD1 Input 5K to RS232C Receive Data port 1 Ground RS232 BB B55 DTR1 Output NA RS232C Data Terminal Ready port 1 RS
62. bug or serial payload interfaces In this access method the ipmitoo1 utility uses a serial interface to directly access the MMC Accessing an MMC via a Shelf Manager To access the MMC using an Ethernet connection to a Shelf Manager the following parameters should be specified in the command line of the ipmitoo1 utility I lan This command line parameter instructs the ipmitoo1 utility to use Ethernet for communications with the MMC H lt Shelf Manager IP gt This command line parameter specifies the IP address of the Shelf Manager T lt carrier IPMC address gt This command line parameter specifies the remote transit address IPMB 0 address of the carrier IPMC to which requests should be bridged by the Shelf Manager B 0 This command line parameter specifies the remote transit channel with O designating IPMB 0 to which requests should be bridged by the Shelf Manager t lt MMC address gt This command line parameter specifies the remote target address IPMB L address of the MMC to which requests should be bridged by the carrier IPMC SB 7 This command line parameter specifies the remote target channel with 7 designating IPMB L to which requests should be bridged by the carrier IPMC A lt authtype gt This command line parameter forces the ipmitool to use a specific authentication type which must of course be supported by the Shelf Manager Firmware Upgrade Process For example to fetch and prin
63. cations ks 36 environmental requirements LL 108 cable ethernet alignment Rus pna ban i i 43 Interfaces ocacion NG GAGANA NAGANA neh 25 options a En NAGA 19 interrupts s vasar se sea oup E PNG RNGA DP BA eee 29 pinout European Telecommunications Standards Institute ETSI 112 E a O 91 European Union directives oooooooooooo 112 RS232C un ee ern 89 RS422 nn ann an ana s ja re 90 RS449 anne oa een 90 F NGO ass NA AS g da a a e i de ciacs 92 type indicator pins ooooooomommomrrnron 73 FACT JMPRF 3 aai ad ctra 40 WIN CONSOIE iii torca rr a i 19 FCC USA Class A notice LL 113 Without console Katia asa NA a a e a ss 19 ECLA 200 ta ern 36 102 Canada Class A notice LL 113 ula T 19 CE Certification La 112 firmware upgrade Ls 59 CFGSWO 4 264 ugo sie i i den 41 Mas MEMO ia iai ai ia o NPA A davai 25 GEGSWT Al a iai ias austin as S la as ausa a 41 front cover faceplate 0 0 cee eee eee 20 GEFGSW2 ana an KG NA ra iva A a a 41 front Panel 3 as s HH nn a er a 20 ClocKing oir rr een 30 functional block diagram 22222222 nennen 21 Comlink ss 33 configurations for AMC335 LL eee eee 18 G console cable pinout LL kak kaka 93 a genera oreu merle GOD mode anas 7 121 Index H J hard reset ruuteri 102 hazardous materials lt 37 heat sink ra Jean ak ale hate 36 hot swap handle lt lt 42 hot swap LED Aaa Ja a a is as a es ad ES 31 HPM 1 A ra 59 COMM
64. chassis Note An extraction tool such as that manufactured by XTECH can aid in module removal Connecting the Cable See AMC335 I O Configurations and Accessories on page 18 for a list of the cables available for use with the AMC335 The AMC335 ships with the appropriate four port hydra cable you have ordered See Serial Cable Connectors on page 88 for information about the various cable pinouts and connectors 1 After installing the AMC335 in the host chassis align the black jackscrew on the cable with the black jackpost on the front panel of the module see Figure 3 2 AMC335 Cable Alignment below 2 Insert the cable into the dual VHDCI connector on the module 3 Fasten the four jackscrews to secure the cable Figure 3 2 AMC335 Cable Alignment Black Jackpost Black Jackscrew Align the black jackscrew on the cable head with the black jackpost on the front panel of the module 43 Chapter 3 Getting Started 44 Chapter N AA m ATA Vs sm Xy NA UA System Monitoring and Alarms Overview This chapter provides information about the Module Management Controller MMC device and how it uses the Intelligent Platform Management Interface IPMI to monitor the system and warn of problems with the AMC335 Key topics in this chapter include MMC Functions on page 45 Summary of Supported Commands on page 46 Device Locator Record on page 48 Sensors
65. ckage supplied for the module in the General Purpose Switch and External Bus Reset Status Register The default setting for all switches in the SW2 bank is OFF See Figure 3 1 AMC335 Switch Locations on page 38 to see the location of the switch bank SW3 Switch Bank SW3 allows the user to configure the following AMC335 functions Reset Configuration e EEPROM Write Protect Break Detect Enable Application Code Enable See Figure 3 1 AMC335 Switch Locations on page 38 for the location of this switch bank The following topics describe the functionality of each switch in SW3 SW3 1 Reset Configuration SW3 1 RSTCONF selects the hard reset configuration settings for the MPC8270 See Table 3 1 for switch settings The default factory setting is ON Table 3 1 SW3 1 Settings SW3 1 Description Factory Setting OFF Open Sets the MPC8270 to the default HRESET configuration settings There will be no reset configuration cycles on the bus because the MPC8270 is set to be a reset slave ON Closed Sets the MPC8270 to use the HRESET configuration settings Default from the boot flash Sets the MPC8270 as the reset master 39 Chapter 3 Getting Started 40 SW3 2 EEPROM Write Protect SW3 2 EEWP selects the write protect configuration for the P17C9X110 PCI Express bridge s boot EEPROM device See Table 3 2 for switch settings The default factory setting is ON Table 3 2 S
66. column indicates where in the relevant specification a command is defined IPMI references are to v1 5 unless indicated otherwise The MMC Req column indicates if a particular command is required by the relevant specification AMC Specification or HPM 1 Specification or is optional See the various notes under the table for more information Table 4 1 IPMI PICMG Command Subset Supported by the MMC Firmware Command Spec Ref NetFn CMD MMC Req IPM Device Global Commands Get Device ID 17 1 App 01h Mandatory Cold Reset 17 2 App 02h Optional Warm Reset 17 3 App 03h Optional Broadcast Get Device ID 17 9 App 01h Mandatory Messaging Commands Set BMC Global Enables 18 1 App 2Eh Mandatory Get BMC Global Enables 18 2 App 2Fh Mandatory Clear Message Flags 18 3 App 30h Mandatory Get Message Flags 18 4 App 31h Mandatory Get Message 18 6 App 33h Mandatory Send Message 18 7 App 34h Mandatory BMC Watchdog Timer Reset Watchdog Timer 21 5 App 22h Mandatory Set Watchdog Timer 21 6 App 24h Mandatory Get Watchdog Timer 21 7 App 25h Mandatory Event Commands Set Event Receiver 23 1 S E 00h Mandatory Get Event Receiver 23 2 S E 01h Mandatory Platform Event a k a Event Message 23 3 S E 02h Mandatory Sensor Device Commands Summary of Supported Commands Table 4 1 IPMI PICMG Command Subset Supported by the MMC Firmware Continued
67. ctivity in an AdvancedTCA or MicroTCA based system This module is ideally suited for use in creating flexible and efficient radar gateways radar recorders protocol convertors serial gateways and front end I O elements as well as many other high speed communications devices that require RS232 RS422 RS449 EIA530 and V 35 connectivity Chapter 2 Introduction The architecture of the AMC335 capitalizes on the intelligence of the Freescale MPC8270 PowerQUICC II Quad Integrated Communications Processor referred to as the MPC8270 in this manual which enables it to act as a specialized communications controller and a Pericom PI7C9X110 PCI to PCI Express reversible bridge Serial line electrical interfacing is available providing voltage level adaptation to a recommended communication standard such as RS232C RS422 and to RS449 or ElA530 with correct cabling and ITU V 35 using a high density dual VHDCI 136 pin receptacle containing the signals for all four ports To provide an industry standard connection for each port hydra adapter cables are offered Ethernet connectivity is provided via two 1000Base X interfaces using the Broadcom BCM5704S PCI MAC PHY controller Code storage and data buffering are provided by a 128 MB SDRAM array which is available to both the MPC8270 and the PI7C9X110 PCI Express bridge devices Additional on board code space is available in the form of a 32 MB application flash device The AMC335 is capab
68. ctrical hazards heat shock and or fire hazara do not make connections to terminals outside the range specified for that terminal Refer to the product user manual for correct connections Caution To Avoid the Risk of Electric Shock When supplying power to the system always make connections to a grounded main Always use a power cable with a grounded plug third grounding pin Do not operate in wet damp or condensing conditions KN Caution System Airflow Requirements Platform components such as processor boards Ethernet switches etc are designed to operate with external airflow Components can be destroyed if they are operated without external airflow Chassis fans normally provide external airflow when components are installed in compatible chassis Filler panels must be installed over unused chassis slots so that airflow requirements are met Please refer to the product data sheet for airflow requirements if you are installing components in custom chassis AI Caution Do Not Operate Without Covers To avoid electric shock or fire hazard do not operate this product with any removed enclosure covers Or panels AN Caution To Avoid the Risk of Electric Shock Do not operate in wet damp or condensing conditions AN Caution Do Not Operate in an Explosive Atmosphere To avoid injury fire hazard or explosion do not operate this product in an explosive atmosphere Compliance with RoHS and WEEE Directives AN Cautio
69. d If the MMC receives such a command before the payload communication timeout time it sends the 0x00 completion code Success to the carrier controller Otherwise the OxC3 completion code Timeout is sent The Graceful Reset command has the following synopsis B8 xx 11 0A 40 00 Note that the MMC does not reset the payload on receiving the Graceful Reset command or timeout If the MMC participation is necessary the payload must request the MMC to perform a payload reset The Graceful Reset command is also used to notify the MMC about the completion of the payload shutdown sequence refer to Payload Shutdown Timeout on page 58 57 Chapter 4 System Monitoring and Alarms 58 Payload Diagnostic Interrupt The MMC supports the Issue Diagnostic Interrupt feature of the FRU Control command The payload is notified about a diagnostic interrupt over the SIPL as described in Get Status Command on page 54 The payload is expected to return diagnostic interrupt results before the payload communication timeout using the Diagnostic Interrupt Results command of the SIPL This command has the following synopsis B8 xx 12 0A 40 00 lt diagnostic interrupt return code gt If the payload responds before the payload communication timeout the diagnostic interrupt return code is forwarded to the carrier controller as the completion code of the FRU Control command response Otherwise the 0xC3 completion code Timeout is retur
70. d 98 GND First Logic Ground 74 TCLKA Third Sync Clock 1 97 TX9 Third Port 9 TX 75 TCLKA Third Sync Clock 1 96 TX9 Third Port 9 TX 76 GND First Logic Ground 95 GND First Logic Ground 77 TCLKB Third Sync Clock 2 94 RX9 Third Port 9 RX 78 TCLKB Third Sync Clock 2 93 RX9 Third Port 9 RX 79 GND First Logic Ground 92 GND First Logic Ground 80 FCLKA Third Sync Clock 3 91 TX8 Third Port 8 TX 81 FCLKA Third Sync Clock 3 90 TX8 Third Port 8 TX 82 GND First Logic Ground 89 GND First Logic Ground 83 PSO Carrier Last Presence 0 88 RX8 Third 84 PWR Carrier First Payload Pwr 87 RX8 Third Port 8 RX 85 GND First Logic Ground 86 GND First Port 8 RX 72 Note Shaded areas in table denote unused pins Serial I O Connector Serial I O Connector The dual VHDCI connector assumes different configurations depending on which communication standard is employed The following communications standards are supported on the AMC335 RS232C Supported Signals on page 74 RS422 RS449 Supported Signals on page 77 V 35 Supported Signals on page 83 See Chapter 6 MPC8270 Parallel I O Ports on page 95 for information about the two general purpose serial management controllers and the pin assignments for the four general purpose parallel I O ports on the MPC8270 Cable Type Indicator Pins There are four pins on the dual VHDCI connector that indicate what type of ca
71. d electrical signal at port 3 on DCD or TXCI lt does not indicate a mark or space This is typically used to indicate that a cable is plugged in and the transmitting element is active 27 Chapter 2 Introduction 28 Table 2 2 MPC8270 Interrupt Sources Continued IRQ Level Pin Controlled Device Note PC2 AE29 WAKE1 On the RS232C build of the AMC335 this bit indicates that there is a valid electrical signal at port 2 on DCD or TXCI It does not indicate a mark or space This is typically used to indicate that a cable is plugged in and the transmitting element is active PC3 AE27 WAKE1 On the RS232C build of the AMC335 this bit indicates that there is a valid electrical signal at port 1 on DCD or TXCI It does not indicate a mark or space This is typically used to indicate that a cable is plugged in and the transmitting element is active PCI Express Interrupts The PI7C9X110 PCI to PCI Express bridge chip can support both INT x emulation of the legacy INT x wires or the Message Signaled Interrupt MSI mode of interrupt passing on either side of the bridge The AMC335 is designed to support both modes of operation The selection of the mode of operation is up to the root complex software driver and is dependent on the hardware and software capabilities of the particular system in which the AMC335 is installed The PI7C9X110 also imposes a limitation on modes by only allowing the same typ
72. dard Intelligent Platform Management Interface v1 5 Specification functionality See Module Management Controller on page 118 for information about this specification Sensors The following sensors are monitored on the AMC335 MMC voltage monitoring 3 3 V management power and 12 V power to the AMC slot hir inlet temperature sensor Temperature sensor on the CPU which measures the board s high temperatures The sensor is located between the CPU and the voltage regulator MMC hot swap switch sensor Other on board voltages 3 3 V 2 5 V 1 8 V 1 5 V 1 2 V are also measured For more information on AMC335 sensors see Sensors on page 50 29 Chapter 2 Reset Introduction The AMC335 supports local power on hard and soft resets as well as resets caused by the external PCI Express bus and the MMC See Chapter 7 Reset on page 101 for more information Push Button Reset The front panel push button see Figure 2 1 AMC335 Front Panel on page 20 provides a hard reset if pressed See Push Button Reset Switch on page 42 for more information Board Clocks and Frequencies Clock 30 Table 2 3 Locally Generated Frequencies and Sources shows the on board generated frequencies and their sources on the AMC335 Table 2 3 Locally Generated Frequencies and Sources Frequency Source Use 1 250 GHz Internal Multiplying PLL in the PCI Ex
73. de Text Commands The SIPL does not support Terminal Mode ASCII text commands defined by the PMI Specification section 13 7 8 51 Chapter 4 System Monitoring and Alarms Pigeon Point Systems PPS Extension Commands The MMC firmware supports a set of PPS extension commands that are used to control and monitor the carrier Intelligent Platform Management Controller IPMC state over the serial debug interface These commands are used to read the MMC status implement graceful payload shutdown etc The PPS extension commands are implemented as OEM IPMI commands with network function codes 2Eh 2Fh and message body transferred in the same manner as for raw IPMI messages see Raw IPMI Messages on page 51 Figure 4 1 PPS Extension Command Request shows an example of aPPS extension command request Figure 4 1 PPS Extension Command Request B8 00 01 0A 40 00 12 Data PPS IANA Command Code rqSeq 00h Bridge 00b NetFn Code 2Eh LUN 00b Figure 4 2 PPS Extension Command Response shows an example of a PPS extension command response Figure 4 2 PPS Extension Command Response BC 00 01 00 0A 40 00 34 u Data PPS IANA Completion Code Command Code rqSeq 00h Bridge 00b NetFn Code 2Eh LUN 00b Terminal Mode Line Editing The MMC does not support input line editing functionality defined as optional in the PMI Specification section 13 8
74. e User may initiate deactivation by pulling out the module handle to open the hot swap switch sending a request via the MMC to the carrier for a hot swap extraction Module handle open Module is waiting to be deactivated Not safe to extract module Module is quiesced module payload power is disabled Safe to extract module System Management Bus SMB JTAG User Configurable Switches There are several user configurable switches that may need to be configured They may be used with the software package supplied for the module See Switches on page 37 for more 32 information Software Support Software Support NexusWare Software Support The NexusWare software suite offers a CGL registered and POSIX compliant operating system and development environment In addition the suite includes an extensive list of installable protocols that can be leveraged to build robust solutions such as media gateways lawful intercept platforms SS7 monitoring equipment for line usage billing applications radar gateways and converged serial gateways The NexusWare family of products supported on the AMC335 includes NexusWare Core At the very center of the NexusWare suite of software is NexusWare Core which provides a comprehensive highly integrated Linux OS development integration and management environment It is intended for system engineers who use Performance Technologies embedded products to build packet based s
75. e 5 8 V 3581gnalsand PINS vorpal PN es 83 Table 5 7 Console Serial Port Pinout a NAKAANGAT alu ae k bn ea 88 Table 5 8 RS232C Hydra Cable Connector Pinout lt 89 Table 5 9 RS449 RS422 Hydra Cable Connector Pinout LL 90 Table 5 10 EIA530 Hydra Cable Connector Pinout lt 91 Table 5 11 V 35 Hydra Cable Connector Pinout 00 0 ccc eee 92 Table 5 12 RS232C RS422 RS449 EIA530 V 35 Console Cable Option Pinout 93 Table 6 1 MPC8270 Port A Pin Assignments aka 97 Table 6 2 MPC8270 Port B Pin Assignments kaka 98 Table 6 3 MPC8270 Port C Pin AssignMentS o ooccccoccco ees 99 Table 6 4 MPC8270 Port D Pin Assignments li aaa 100 Table 8 1 Power Consumption with 266 MHz Processor 00 0c eee ee eee eee 108 Table 8 2 Reliability Data a ses a De a is 110 A AAA AN AAN Vs sm Xy DAA AS Figure 2 1 Figure 2 2 Figure 2 3 Figure 3 1 Figure 3 2 Figure 4 1 Figure 4 2 Figure 8 1 AMC335 Front Panel ua eats des res A es irre 20 AMC335 Functional Block Diagram aaa 21 AMC335 in the AMP507x MicroTCA Platform 22 AMC335 Switch Locations Ke wi adnaved Besserer le nG Loox 38 AMC335 Cable Alignment s gt 4 oss k si ee ai KANG j s ees 43 PPS Extension Command Request nennen ernennen nn 52 PPS Extension Command Response seen eee eee eee 52 AMC335 DIMENSIONS dues als 109 Figures 11 Figures 12 Chapter N AA AN NN
76. e 69 for complete connector descriptions and pinouts Switches The AMC335 includes several options that tailor the operation of the module Most of the options are selected through software However some options cannot be software controlled and are configured with DIP switches Closing or opening the desired switch selects each switch s options See Figure 3 1 AMC335 Switch Locations below Switch Locations The AMC335 includes the following user configurable switches e SW2 Switch Bank e SWS Switch Bank SW4 Switch Bank Push Button Reset Switch Hot Swap Handle Switch 37 Chapter 3 Getting Started Figure 3 1 AMC335 Switch Locations un un Na wa Push Button Reset Switch sw2 SW3 SW4 Hot Swap Handle Switch 38 Switches Switch Descriptions The following topics present the switches in numerical order and provide a description of each switch bank switch number and setting Multiple switch banks are identified in the form SWx N where x is the bank number and N is the switch number For example SW2 3 means bank number 2 switch number 3 Each switch is either ON closed or OFF open Each bank is labeled to indicate the switch number and the ON or OFF position Note The factory default switch settings are indicated below in bold SW2 Switch Bank There is a set of four general purpose switches at position SW2 that can be configured for any purpose They can be read by the software pa
77. e No IPMB Event Generator Yes IPMB Event Receiver No FRU Inventory Device Yes SEL Device No SDR Repository Device No Sensor Device Yes Table 4 2 IPMB Management Controller Device Locator Record Continued Device Locator Record Parameter Value FRU Entity ID 0xC1 Entity Instance slot dependent OEM specific 0 Device ID String Type Length 8 bit ASCII with size of Device ID String Note See Table 4 3 MMC Device ID below Device ID String AMC335 Device ID The MMC firmware provides the following device ID data in response to the Broadcast Get Device ID command as shown in Table 4 3 MMC Device ID below Table 4 3 MMC Device ID Parameter Value Device ID 0x00 Provides Device SDRs Yes Device Revision Number 0x00 Device Available Yes Firmware Revision Changes with each release IPMI Version 1 5 Additional Device Support Chassis Device No Bridge No IPMB Event Generator Yes IPMB Event Receiver No FRU Inventory Device Yes SEL Device No SDR Repository Device No Sensor Device Yes Manufacturer ID 0x000614 Product ID 0x000b Auxiliary Firmware Revision Information 0x00000000 49 Chapter 4 System Monitoring and Alarms Sensors Table 4 4 MMC Sensors lists the sensors and thresholds that are monitored by the MMC Note that the sensor IDs are local to the MMC The MMC s SDRs
78. e of operation on either side PCI or PCI Express of itself once one particular mode is chosen This forces a change on how the interrupts are handled in the hardware and software so that a consistent interrupt method is used in either mode The operating features are outlined in the following topics Outbound Interrupts The method for creating an outbound interrupt is the same whether INT x or MSI is chosen as the operating mode The outbound interrupt is generated by the MPC8270 by using PI7C9X110 s Primary IRQ register set to send an interrupt message to the host Access to the registers is by the local PCI bus After writing the Primary IRQ depending on the method chosen by the root complex OS and device driver the PI7C9X110 generates either a legacy INT x serial message to the host or an MSI message to the host The interrupt message is mapped to the AMC335 s root complex OS interrupt handler and the appropriate action can then be taken by the interrupt handler The PI7C9X110 Primary IRQ register set is used to signal a particular interrupt event and the PI7C9X110 scratchpad registers can be used for argument and message passing Inbound Interrupts The inbound interrupt is implemented by writing to the MPC8270 s PCI inbound doorbell register directly by the root complex host The register is exposed to the root complex through the PI7C9X110 s BAR3 Downstream Memory 2 BAR memory space The PI7C9X110 s BAR3 Downstream Memory 2 BAR is i
79. earance and related charges outside the United States Products containing batteries are warranted as above excluding batteries THIS WARRANTY IS IN LIEU OF ALL OTHER WARRANTIES WHETHER EXPRESS IMPLIED OR STATUTORY INCLUDING IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS IN NO EVENT SHALL PERFORMANCE TECHNOLOGIES BE LIABLE FOR ANY INCIDENTAL OR CONSEQUENTIAL DAMAGES DUE TO BREACH OF THIS WARRANTY OR ANY OTHER OBLIGATION UNDER THIS ORDER OR CONTRACT Chapter N PP LS AA AN NA sm Xy NA UA Introduction Overview This chapter provides an introduction to the AMC335 a multipurpose intelligent four port WAN communications module for AdvancedTCA or MicroTCATM based systems Included here is a product definition a list of product features an AMC335 Front Panel figure an AMC335 Functional Blocks figure a description of each functional block plus information about the software supported on the AMC335 Information about unpacking installing and other setup information for the AMC335 is provided in Chapter 3 Getting Started on page 35 Key topics in this chapter include Product Definition on page 17 AMG335 Features on page 19 AMC335 Front Panel on page 20 AMG335 Functional Blocks on page 21 Software Support on page 33 Product Definition The AMC335 Intelligent Synchronous WAN Communications Module provides four high performance synchronous serial channels for WAN conne
80. ee user programmable machines UPMs It supports a glueless interface to synchronous DRAM EPROM Flash EPROM burstable RAM regular DRAM devices extended data output DRAM devices and other peripherals This flexible memory controller allows the implementation of memory systems with very specific timing requirements SDRAM Machine The SDRAM machine provides an interface to synchronous DRAMS using SDRAM pipelining bank interleaving and back to back page mode to achieve the highest performance GPCM The GPCM provides interfacing for simpler lower performance memory resources and memory mapped devices The GPCM has inherently lower performance because it does not support bursting For this reason GPCM controlled banks are used primarily for boot loading and access to low performance memory mapped peripherals AMC335 Functional Blocks UPM The UPM supports address multiplexing of the external bus refresh timers and generation of programmable control signals for row address and column address strobes to allow for a glueless interface to DRAMs burstable SRAMs and almost any other kind of peripheral The refresh timers allow refresh cycles to be initiated The UPM can be used to generate different timing patterns for the control signals that govern a memory device These patterns define how the external control signals behave during a read write burst read or burst write access request Refresh timers are also available to periodical
81. es Table 5 8 RS232C Hydra Cable Connector Pinout on page 89 Table 5 9 RS449 RS422 Hydra Cable Connector Pinout on page 90 Table 5 10 ElA530 Hydra Cable Connector Pinout on page 91 Table 5 11 V 35 Hydra Cable Connector Pinout on page 92 Table 5 12 RS232C RS422 RS449 EIA530 V 35 Console Cable Option Pinout on page 93 88 RS232C Hydra Cable Connector A hydra cable providing four 25 pin D shell DB 25 DTE with male connectors pins is available for the AMC335 RS232C model The pin assignments for the RS232C hydra cable are shown in Table 5 8 RS232C Hydra Cable Connector Pinout below Duplicate each pin four times to create the hydra cable for ports 1 4 Table 5 8 RS232C Hydra Cable Connector Pinout Pin Signal Name Description 1 CGND Cable Shield 2 TXD Transmit Data 3 RXD Receive Data 4 RTS Request To Send 5 CTS Clear To Send 6 DSR Data Set Ready 7 GND Signal Ground 8 DCD Data Carrier Detect 9 No connection 10 No connection 11 No connection 12 No connection 13 No connection 14 No connection 15 TXCl Transmit Clock In 16 No connection 17 RXC Receive Clock 18 No connection 19 No connection 20 DTR Data Terminal Ready 21 No connection 22 No connection 23 No connection 24 TXC Transmit Clock 25 No connection Serial Cable Connectors 89 Chapter 5
82. fety Information on page 113 Compliance with RoHS and WEEE Directives on page 115 111 Chapter 9 Agency Approvals Network Equipment Building System NEBS and European Telecommunications Standards Institute ETSI The product described in this manual is designed to meet NEBS Level 3 and ETSI Environmental Criteria GR 63 CORE Network Equipment Building System Requirements Physical Protection GR 1089 CORE Electromagnetic Compatibility and Electrical Safety Generic Criteria for Network Telecommunications Equipment CE Certification The product described in this manual meets the intent of the following European Union Directives EU 89 336 EEC Electromagnetic Compatibility Directive amended by 92 31 EEC 93 68 EEC 98 13 EEC and 2004 108 EC EU 72 23 EEC Low Voltage Directive amended by 93 68 EEC and 2006 95 EC by meeting the applicable EU standards as outlined in the Declaration of Conformance The Declaration of Conformance is available from Performance Technologies or from your authorized distributor Compliance will be demonstrated to the following specifications as listed in the Official Journal of the European Communities EN55022 Radiated and Conducted Emissions EN300 386 Electromagnetic Compatibility EMC EN55024 Immunity EN61000 4 2 Electro Static Discharge ESD EN61000 4 3 Radiated Susceptibility EN61000 4 4 Electrical Fast Transient Burst EN61000 4 5 Surge Immunity EN61000 4 6 Frequency M
83. firmware on the IPMC about whether a rollback event has occurred ipmitool Example hpm rollbackstatus ipmitool I lan H 192 168 0 2 A none T 0x82 B 0 t 0x74 b 7 hpm rollbackstatus Rollback PICMG HPM 1 Upgrade Agent 1 0 occured on component mask 0x01 2 occured is misspelled in the ipmitool utility 67 Chapter 4 System Monitoring and Alarms 68 Chapter A AAA UA AAN Vs sm Xy NA Connectors Overview The AMC335 includes several connectors to interface with application specific devices The connectors discussed in this chapter are shown in Table 5 1 AMC335 Connector Assignments below Table 5 1 AMC335 Connector Assignments Connector Location AdvancedMC Card Edge Connector on page 70 Card Edge Serial I O Connector on page 73 Front Panel RS232C Supported Signals on page 74 RS422 RS449 Supported Signals on page 77 V 35 Supported Signals on page 83 Console Serial Port on page 88 Bottom Side Serial Cable Connectors on page 88 Cables e RS232C Hydra Cable Connector on page 89 RS449 RS422 Hydra Cable Connector on page 90 ElA530 Hydra Cable Connector on page 91 V 35 Hydra Cable Connector on page 92 Console Cable Option on page 93 A detailed description and pinout for each connector is given in the topics that follow 6
84. he PI7C9X110 PCI Express bridge or the PI7C9X110 in this manual to connect the AMC335 s MPC8270 communications processor to the host PCI Express root complex The PI7C9X110 PCI Express bridge is compliant with the following specifications e PCI Express Base Specification Revision 1 0a e PCI Express Card Electromechanical Specification Revision 1 0a e PCI Express to PCI PCI X Bridge Specification Revision 1 0 e PCI Local Bus Specification Revision 3 0 The PI7C9X110 PCI Express bridge supports transparent and nontransparent modes of operation as well as forward and reverse bridging The application on the AMC335 is a forward bridging implementation however if a PCI Express interface is not available or disabled the part needs to be configured in reverse mode and held in reset In forward bridging mode the PI7C9X110 has an x1 PCI Express upstream port and a 32 bit PCI PCI X downstream port running at 66 MHz The PI7C9X110 PCI Express bridge configuration registers are backward compatible with existing PCI bridge software and firmware The PI7C9X110 PCI Express bridge s PCI Express connection to the root complex is made via the AMC card edge connector per the AMC 1 and the PCI Express Card Electromechanical Specification Revision 1 0a The AMC335 utilizes an x1 lane configuration RX TX RXCLK and PERST are the supported PCI Express signals See PCI Express Bridge on page 118 for links to additional information and related docume
85. hing or work environment can damage the electronic equipment Environmental Specifications This section describes the environmental requirements for the AMC335 Operating Temperature The module operating range is O to 60 C 32 F to 140 F The maximum power dissipation by any part is the 3 W peak generated by the MPC8270 and the linear regulator creating its core voltage In a normal environment where the ambient temperature doesn t exceed the thermal operating range a heatsink is not required for any of the module level components However one may be employed to give the assembly a thermal margin beyond its normal operating range Contact Performance Technologies Customer Support and Services for more information if additional thermal margin is desired AN Caution External airflow must be provided at all times during operation to avoid damaging the CPU 108 Mechanical Specifications Temperature Monitoring Because reliable long term operation of the AMC335 depends on maintaining proper temperature Performance Technologies strongly recommends that you verify the operating temperature of the CPU The MMC monitors the temperature of the device and reports any temperature violations that may occur via the IPMB interface Mechanical Specifications The AMC335 is compliant with the PICMG AMC 0 R 2 0 specification for all mechanical parameters Mechanical dimensions are outlined below and shown in Figure 8 1 AMC335 Dimen
86. ication controlled LED controlled by application software not the MMC used to indicate the health of the module The APP LED is a green yellow off LED that has the following states Off no power or booting Green module is healthy Yellow module has had an error Flashing module is currently running possible for both green and yellow colors Hot Swap LED The blue Hot Swap LED indicates the module s state as it deactivates in preparation for extraction or reactivate after insertion See Hot Swap Handle Switch on page 42 Refer also to the PICMG Advanced Mezzanine Card AMC O Specification R2 0 for more information see PICMG Specifications on page 118 31 Chapter 2 Introduction Insertion Sequence Off Blue on Blue long blink Off Module handle open Management power is not enabled Module is fully seated in carrier Module s management power is enabled User may initiate activation by pushing in the handle on the module s front panel to close the hot swap switch Module handle is closed module is being activated Module handle is closed Module is in normal operational state Extraction Sequence Off Blue short blink Blue on Rear Panel I O The AMC335 transitions the following l O signals through the AMC card edge connector to the carrier board or MicroTCA system 2x 1Gb 1000BASE X Ethernet PCI Express x1 Reset Power and Ground Module is in normal operational stat
87. ifferential V 35 104 M 34 T 125 Ohms to ground T14 DTR3 Output NA V 35 Data Terminal Ready port 3 V 35 108 M 34 H T11 TXD A 3 Output NA V 35 Transmit Data port 3 V 35 103 M 34 P T10 TXD B 3 Output NA V 35 Transmit Data port 3 V 35 103 M 34 S T45 RTS3 Output NA V 35 Request To Send port 3 V 35 105 M 34 C T9 GND3 NA V 35 port 3 Signal Ground V 35 102 M 34 B T48 TXC A 3 Output NA V 35 Transmit Clock port 3 V 35 113 M 34 U T47 TXC B 3 Output NA V 35 Transmit Clock port 3 V 35 113 M 34 W 85 Chapter 5 Connectors 86 Table 5 6 V 35 Signals and Pins Continued L ignal s Baka At Pin Signa Direction Termination Description Name T42 TXCI A 3 Input 100 Ohms V 35 Transmit Clock In port 3 differential V 35 114 M 34 Y 125 Ohms to ground T41 TXCI B 3 Input 100 Ohms V 35 Transmit Clock In port 3 differential V 35 114 M 34 AA 125 Ohms to ground T39 DCD3 Input 5K Ohms to V 35 Data Carrier Detect port 3 ground V 35 109 M 34 F T38 RI3 Input 5K Ohms to V 35 Ring Indicator port 3 ground V 35 125 M 34 J T2 DSR3 Input 5K Ohms to V 35 Data Set Ready port 3 ground V 35 107 M 34 E T13 LT3 Output NA V 35 Line Test port 3 V 35 M 34 K T8 CTS3 Input 5K Ohms to V 35 Clear To Send port 3 ground V 35 106 M 34 D T36 RXC A 3 Input 100 Ohms V 35 Receive Clock port 3 differential V 35 115 M 34 V 125 Ohms to ground T35 RXC B 3 Input 100
88. ions conforming to the V 35 electrical standards for TXD and TXC Each input is terminated with 100 Ohms differentially and has a 125 Ohm T connection to ground per the V 35 specification Tri state capable RS232C single ended output connections conforming to the V 28 electrical characteristics for DTR RTS and LT Signal Ground See V 35 Supported Signals on page 83 for supported signals and pinouts 23 Chapter 2 Introduction Console Serial Port The console serial port can be used with NexusWare to configure and control the module level application software It is implemented as a 9 pin D sub female connector on each I O cable The port is an asynchronous RS232C serial I O port that supports the following signals RS232C single ended input connection conforming to the V 28 electrical characteristics for RXD with built in 5K pulldown RS232C single ended output connection conforming to the V 28 electrical characteristics for TXD Signal Ground See Console Serial Port on page 88 in for more information on the signals and pinouts for the serial console port See also Console Cable Option on page 93 Note A three pin right angle header can be mounted on the bottom side of the card and used for debugging Contact Performance Technologies Customer Support and Services for more information PCI Express Interface 24 The AMC335 uses a Pericom PI7C9X110 PCI to PCI Express bridge referred to as t
89. is performed using the upgrade agent utility implementing the HPM 1 Upgrade Protocol and capable of programming custom firmware images into the flash memory of the MMC over a serial interface or IPMB L Any HPM 1 compatible Upgrade Agent can be used to upgrade the MMC firmware It is recommended to use the ipmitool utility for these purposes The ipmitoo1 utility is available from Performance Technologies Contact Performance Technologies Customer Support and Services for contact information The firmware image is supplied to the ipmitoo1 utility in a single file called an HPM 1 upgrade image for information about the format of HPM 1 upgrade images refer to the HPM 1 specification Detailed HPM 1 Upgrade Procedure 60 The following images are available from Performance Technologies hpmlfw img this image contains the MMC firmware hpmlboot img this image contains the boot loader hpmlall img this image contains both the firmware and the boot loader These images can be used to upgrade corresponding components of the IPMC the firmware the boot loader or both The following snapshot samples a command performing firmware upgrade from a Linux host over LAN IPMB Firmware Upgrade Process ipmitool I lan H 192 168 0 2 A none T 0x82 B 0 t 0x7c b 7 hpm upgrade hpmlfw img activate PICMG HPM 1 Upgrade Agent 1 0 Validating firmware image integrity OK Performing preparation stage Services may be affected during upgrade
90. itool utility is used as upgrade agent for upgrading the MMC firmware The upgrade agent communicates with the MMC firmware via serial interface or IPMB L and uses the ATCA commands that are described in the HPM 1 Specification for upgrading the firmware Updated firmware is packed into a special image that has a format described in the HPM 1 Specification That image is used by the upgrade agent to prepare and upgrade the MMC firmware The HPM 1 upgrade procedure includes the following steps 1 Preparation step This step erases the region in the flash memory where a component will be written 2 Component upload step This step is designed to upload the component image via IPMB or a serial interface and write it into the flash memory 3 Component activation step This step is designed to activate the previously upgraded component for the firmware component this step can be deferred until a later time The MMC firmware supports two upgradeable components the firmware itself and the boot loader In case of an unsuccessful firmware upgrade it is possible to roll back to the old firmware This is not true for the boot loader Note Extreme caution should be exercised when upgrading the boot loader There is no backup copy of the boot loader and if for any reason the boot loader upgrade procedure fails the firmware becomes non functional after reboot and must be reprogrammed over JTAG Upgrade Utilities The firmware upgrade procedure
91. le of handling much of the low level communications that typically burden the host processor so most of the serial I O communication related processing can be relegated to the AMC335 In addition the SDRAM eliminates the start up delays associated with application download wait times by enabling the code to be executed directly onboard The AMC335 supports the use of PCI Express or Ethernet for interconnecting to other subsystems used in an AdvancedTCA or MicroTCA based environment The on board Module Management Controller MMC monitors controls and performs remote diagnostics for many on and off board functions through the IPMI Intelligent Platform Management Interface compliant system management bus interface AMC335 I O Configurations and Accessories Three models ofthe AMC335 are available to support RS232 RS422 and V 35 standards Other standards are supported through appropriate cabling See Cable Options on page 19 All four ports of connectivity are accessible through the high density dual stacked VHDCI connector on the front panel of the AMC335 Model PT AMC335 12289 RS232C Model PT AMC335 12258 RS422 Model PT AMC335 12287 V 35 Note The instructions and information provided in this manual apply to all models When values and options differ for any model they are noted AMC335 Features Cable Options Optional hydra cables allow the choice of RS232C RS449 ElA530 or V 35 connections depending on
92. lic font Italic font represents Notes that supply useful advice Supplemental information Referenced documents Customer Support and Services Customer Support and Services Performance Technologies offers a variety of standard and custom support packages to ensure customers have access to the critical resources that they need to protect and maximize hardware and software investments throughout the development integration and deployment phases of the product life cycle If you encounter difficulty in using this Performance Technologies Inc product you may contact our support personnel by 1 EMAIL Preferred Method Email us at the addresses listed below or use our online email support form Outline your problem in detail Please include your return email address and a telephone number 2 TELEPHONE Contact us via telephone at the number listed below and request Technical Support Our offices are open Monday to Friday 8 00 a m to 8 00 p m Eastern Time Performance Technologies Support Contact Information Embedded Systems and Software SS7 Systems Includes Platforms Blades and Servers Includes SEGway Email support pt com ss7support pt com 1 585 256 0248 1 585 256 0248 Phone Monday to Friday 8 a m to 8 p m Monday to Friday 8 a m to 8 p m Eastern Time Eastern Time If you are located outside North America we encourage you to contact the local Performance
93. load communication timeout occurred and acts accordingly The SIPL timeout value also limits the period of time given to the payload to prepare for a payload reset Get Payload Communication Timeout Command on page 57 Set Payload Communication Timeout Command on page 57 Get Payload Communication Timeout Command The MMC supports reading of the payload communication timeout using the Get Payload Communication Timeout command This command has the following synopsis B8 xx 09 OA 40 00 The MMC responds to the Get Payload Communication Timeout command with the following reply BC xx 09 00 OA 40 00 lt payload timeout gt The lt payload timeout gt parameter is the payload communication timeout measured in hundreds of milliseconds Thus the payload communication timeout may vary from 0 1 to 25 5 seconds The default value of the payload communication timeout is specified by the CFG_APP_SIPL_PAYLOAD_TIMEOUT Configuration Parameter Set Payload Communication Timeout Command To change the payload communication timeout the Set Payload Communication Timeout command is used B8 xx OA OA 40 00 lt payload timeout gt Graceful Payload Reset The MMC supports the Graceful Reboot option of the FRU Control command On receiving such a command the MMC sets the Graceful Reboot Request bit of the MMC status sends a status update notification to the payload and waits for the Graceful Reset command from the payloa
94. lows the user to configure the following functions PCI Express Configuration JTAG Enable See Figure 3 1 AMC335 Switch Locations on page 38 for the location of this switch bank The following topics describe the functionality of each switch in SWA SW4 1 PCI Express Configuration SW4 1 CFGSWO is used to enable or disable the PCI Express interface on the module See Table 3 5 for switch settings The default factory setting is OFF Table 3 5 SW4 1 Settings SW4 1 Description Factory Setting OFF Open Enables the PCI Express link on the AMC335 Default ON Closed Disables PCI Express connectivity SW4 2 SW4 2 CFGSW1 is not used at this time The default factory setting is OFF SWA 3 SW4 3 CFGSW2 is not used at this time The default factory setting is OFF SWA 4 JTAG Enable SWA4 4 JTAG_EN_N is used to enable the full JTAG scan chain See Table 3 6 for switch settings The default factory setting is OFF Table 3 6 SW4 4 Settings SW4 4 Description Factory Setting OFF Open Disables JTAG mode on the module This switch is reserved for Default use by the factory and should not be modified ON Closed Grounds the JTAG_EN signal enabling the full JTAG scan chain This switch is reserved for use by the factory and should not be modified 41 Chapter 3 Getting Started Push Button Reset Switch The AMC335 provides a recessed push button reset swi
95. ly generate user defined refresh cycles The primary control of the devices served by the memory controller machines is through the MPC8270 s external chip select lines Interrupt Sources MPC8270 Interrupts Several multifunction pins are used to supply the MPC8270 with the direct connect interrupts from the various board peripherals The IRQO to IRQ7 lines are used along with some of the 16 interrupt capable pins on Port C of the MPC8270 see I O Ports on page 95 The interrupt sources for the most part have multiple interrupt conditions Refer to the component s user manual for the complete breakdown of interrupt causes Table 2 2 MPC8270 Interrupt Sources shows the connections from these devices to the MPC8270 Table 2 2 MPC8270 Interrupt Sources IRQ Level Pin Controlled Device Note IRQO T1 NMI Interrupt IRG1 A22 Not Used IRG2 E21 Not Used IRG3 D21 Not Used IRQ4 C21 Not Used P17C9X110 general interrupt for INTA inbound interrupts to the MPC8270 IRG5 B21 Not Used IRG6 A21 Dual MAC PHY Port 2 IRG7 E20 Dual MAC PHY Port 1 PCO AB26 WAKE4 On the RS232C build of the AMC335 this bit indicates that there is a valid electrical signal at port 4 on DCD or TXCI It does not indicate a mark or space This is typically used to indicate that a cable is plugged in and the transmitting element is active PC1 AD29 WAKE3 On the RS232C build of the AMC335 this bit indicates that there is a vali
96. mitool_package_name gt bash cd ipmitool 2 Run the configure script to prepare for the build The prefix lt dir gt option can be used to specify the directory where the resulting files are installed If not specified usr local is used in this case the installation requires root privileges bash configure prefix home user ipmitool 3 Run the make install command to build and install the ipmitoo1 utility bash make install 61 Chapter 4 System Monitoring and Alarms 62 Accessing an MMC with ipmitool The available access methods that can be used to communicate with the MMC depend on the MMC firmware configuration and overall system setup The most frequently used access methods are the following Via an Ethernet connection to a Shelf Manager that is able to access via IPMB 0 the carrier IPMC managing the MMC See Accessing an MMC via a Shelf Manager on page 62 This access method can be used from any Linux or Windows host that has an Ethernet connection to the Shelf Manager of the shelf in which the MMC is installed In this access method the ipmitool utility uses an Ethernet connection to the Shelf Manager to double bridge IPMI requests to the MMC over IPMB 0 and IPMB L Via the serial debug or serial payload interface of the MMC See Accessing an MMC via a Serial Interface on page 63 This access method can be used from any Linux or Windows host that has a serial connection with the MMC s serial de
97. n If Your System Has Multiple Power Supply Sources Disconnect all external power connections before servicing AN Warning System power supplies must be replaced by qualified service personnel only Compliance with RoHS and WEEE Directives In February 2003 the European Union issued Directive 2002 95 EC regarding the Restriction of the use of certain Hazardous Substances in electrical and electronic equipment RoHS and Directive 2002 96 EC on Waste Electrical and Electronic Equipment WEEE This product is compliant with Directive 2002 95 EC lt may also fall under the Directive 2002 96 EC Performance Technologies complete position statements on the RoHS and WEEE Directives can be viewed on the Web at http pt com page about us ehsms 115 Chapter 9 Agency Approvals 116 ee Chapter KI AAA AN IAN A w Data Sheet Reference Overview This chapter provides information on data sheets devices standards specifications and documentation for the technology designed into the AMC335 Key topics in this chapter include Freescale MPC8270 PowerQUICC II Processor on page 117 PCI Express Bridge on page 118 Ethernet Interfaces on page 118 Module Management Controller on page 118 PICMG Specifications on page 118 PCI Express Specifications on page 119 Electronic Industries Alliance Specifications on page 119 User Documentation on page 119 F
98. n this chapter include Power On Reset on page 102 Hard Reset on page 102 Soft Reset on page 104 PCI Express Interface Resets on page 104 Reset Types and Sources The AMC335 supports the following reset types that affect the entire module Power On Reset Hard Reset Soft Reset Limited resets that do not affect the entire module are also supported 101 Chapter 7 Reset Power On Reset An on board reset controller initiates the power on reset sequence for the AMC335 The controller provides a 20 ms reset pulse after the 3 3 V power returns from an intolerance condition or a brownout condition This signal excludes the MMC block and the PI7C9X110 PCI Express interface The control logic PLD on the module receives this signal and issues a PORESET to the MPC8270 resets internal logic and then supplies resets to the module peripheral devices The power on reset signal PORESET is also asserted by the control logic PLD in response to a PCI Express reset PCE_PERST The control logic PLD logic pulses the PORESET signal once upon detecting the PCI Express reset assertion when PCI Express is enabled in the system MMC Reset The MMC has the ability to remove power from the module by turning off the 12 V to 3 3 V regulator The MMC also has the ability to reset the module which includes a reset to the PI7C9X110 PCI Express bridge FCLKA The AMC335 requires the carrier to source
99. nce with the AMC Type 4 Specification The AMC335 AMC card edge connector supports the following PICMG subsidiary specifications AMC 1 PCle Type 1 Port 4 x1 PCI Express at 2 5 Gbps AMC 2 1GbE Types E1 and E2 Port O and Port 1 1Gb Ethernet channels 1 8 2 The PRESENT1 and PRESENT2 signals are connected together on the module for system presence detection Primary module power is drawn through the AMC card edge connector as well Connector locations and pinouts are documented in AdvancedMC Card Edge Connector on page 70 See PICMG Specifications on page 118 which contains a link to the PICMG Web site where the AMC specification may be obtained Figure 2 3 AMC335 in the AMP507x MicroTCA Platform B20 QC O ROA AMC335 Functional Blocks User I O The user I O on the AMC335 consists of the serial I O connector and a console port Each is described below Serial I O Connector The serial I O connection on the AMC335 is made through a dual VHDCI connector with 136 pins Each port is configured to be a Data Terminal Equipment DTE connection and each port supports one set of the following signals RS232C EIA RS232C single ended input connections conforming to the V 28 electrical characteristics for RXD TXCI RXC DCD DSR CTS with built in 5K pulldowns Tri state capable single ended output connections conforming to the V 28 electrical characteristics for TXD DTR RTS TXC Signal Grou
100. nd See RS232C Supported Signals on page 74 for supported signals and pinouts RS422 Note Supports RS449 and ElA530 with the correct breakout cable Differential input connections conforming to the V 35 electrical standards for RXD TXCI RXC The RS422 configuration provides for an adjustable termination architecture Four Single Inline Package SIP resistor pack connections are included to allow the user to remove or adjust the serial port termination if necessary By default the AMC335 is populated with four 120 Ohm SIPs One SIP is allocated for each port of the AMC335 so termination can be modified on a port by port basis if desired Each input is terminated with 100 Ohms differentially 120 Ohm SIP and 1K Ohm pullup and pulldown to ensure idle port condition if no external cable is present Tri state capable differential output connections conforming to the V 11 electrical standards for TXD DTR RTS and TXC Signal Ground See RS422 RS449 Supported Signals on page 77 for supported signals and pinouts V 35 Differential input connections conforming to the V 35 electrical standards for RXD TXCI and RXC Each input is terminated with 100 Ohms differentially and has a 125 Ohm T connection to ground per the V 35 specification RS232C single ended input connections conforming to the V 28 electrical characteristics for DCD DSR CTS and RI with built in 5K pulldowns Tri state capable differential output connect
101. ned Payload Shutdown Timeout When the carrier controller commands the MMC to shut down the payload i e sends the FRU Control Quiesce command the MMC notifies the payload about it by asserting appropriate alert and sending an alert notification to the payload refer to Get Status Command on page 54 Upon receiving this notification the payload software is expected to initiate the payload shutdown sequence After performing this sequence the payload should send the Graceful Reset command refer to Graceful Payload Reset on page 57 to the MMC over the payload interface to notify the MMC that the payload shutdown is complete To avoid deadlocks that may occur if the payload software does not respond the MMC provides a special timeout for the payload shutdown sequence If the payload does not send the Graceful Reset command within a definite period of time the MMC assumes that the payload shutdown sequence is finished and sends a Module Quiesced hot swap event to the carrier controller Get Payload Shutdown Timeout Command on page 58 Set Payload Shutdown Timeout Command on page 58 Get Payload Shutdown Timeout Command The MMC supports reading of the payload shutdown timeout using the Get Payload Shutdown Timeout command This command has the following synopsis B8 xx 15 OA 40 00 The MMC responas to the Get Payload Shutdown Timeout command with the following reply BC xx 15 00 OA 40 00 lt LS
102. ng within vendor specified tolerances See Critical Events below IPMI non recoverable PICMG 3 0 critical telco critical unit no longer operating within vendor specified tolerances See Non Recoverable Events below Non Critical Events Non critical events are informative only They do not indicate that the module is outside of its operating limits In general no action is required However in certain contexts system or shelf management software may decide that preventive action should be taken For example if several modules in a shelf report upper non critical temperature events the shelf manager might decide to increase fan speed Critical Events Critical events indicate that the module is still within its operating limits but it is close to exceeding one of those limits Possible action in this case is to closely monitor the alarming sensor and take more aggressive action if it approaches the non recoverable threshold Serial Interface Subsystem Non Recoverable Events Non recoverable events indicate that the module may no longer be functioning because it is now outside of its operating limits It is likely that action is required or has already been taken by the local hardware firmware For example a processor may have shut itself down because its maximum die temperature was exceeded or a shelf manager may decide to deactivate the module because the processor is too hot Serial Interface Subsystem The M
103. nitially mapped to 0xF0010000 with a size of 4 KB The MPC8270 s Inbound PCI doorbell is mapped to offset 0x468 from the initial BAR3 AMC335 Functional Blocks Downstream Memory 2 BAR base address The initial secondary side mapping is not in the EEPROM for the PI7C9X110 but can be programmed by the MPC8270 Another value for this offset may be stored in the MPC8270 s NVRAM Care must be taken by the driver code not to alter registers outside of this PCI register set as they will change the operation of the MPC8270 Since this setup works in either mode INT x or MSI it will be used for both modes Inbound messages and arguments are still going to be implemented in the PI7C9X110 s scratchpad registers if their use is desired Ethernet Interrupts The BCM5704S Ethernet controller provides an interrupt to indicate a change in status for each MAC PHY This interrupt is routed to the PLD which adds a mask ability and status through a series of registers Module Management Controller The AMC335 includes a Module Management Controller MMC based on the Atmel ATMEGA128L 8MU which interfaces to the local Intelligent Platform Management bus IPMB L The MMC monitors and controls the module s payload per the PICMG AMC 0 specification See Chapter 4 System Monitoring and Alarms on page 45 for more information on MMC functionality supported commands AMC335 sensors and the firmware upgrade process The AMC335 is compliant with stan
104. nput 5K to RS232C Receive Data Clock port 2 Ground RS232 DD T5 RXD3 Input 5K to RS232C Receive Data port 3 Ground RS232 BB T14 DTR3 Output NA RS232C Data Terminal Ready port 3 RS232 CD T11 TXD3 Output NA RS232C Transmit Data port 3 RS232 BA T45 RTS3 Output NA RS232C Request to Send port 3 RS232 CA T48 TXC3 Output NA RS232C Transmit Data Clock port 3 RS232 DA T42 TXCI3 Input 5K to RS232C Transmit Signal Element Timing 3 Ground RS232 DB T39 DCD3 Input 5K to RS232C Data Carrier Detect port 31 Ground RS232 CF T2 DSR3 Input 5K to RS232C Data Set Ready port 3 Ground RS232 CC T8 CTS3 Input 5K to RS232C Clear to Send port 3 Ground RS232 CB T9 GND Signal Ground for I O connector RS232AB T36 RXC3 Input 5K to RS232C Receive Data Clock port 3 Ground RS232 DD T30 RXD4 Input 5K to RS232C Receive Data port 4 Ground RS232 BB 75 Chapter 5 Connectors 76 Table 5 4 RS232C Signals and Pins Continued ignal mo TEE ae Pin Signa Direction Termination Description Name T21 DTR4 Output NA RS232C Data Terminal Ready port 4 RS232 CD T24 TXD4 Output NA RS232C Transmit Data port 4 RS232 BA T58 RTS4 Output NA RS232C Request to Send port 4 RS232CA T55 TXC4 Output NA RS232C Transmit Data Clock port 4 RS232 DA T61 TXCI4 Input 5K to RS232C Transmit Signal Element Timing 4 Ground RS232 DB T64 DCD4 Input 5K to RS232C Data Carrier Detect port 4 Ground RS232 CF T33 DSR4 Input 5K to RS232C Data Set Ready port
105. nts for this device AMC335 Functional Blocks Ethernet Interfaces Two 1000Base X interfaces for AMC 2 support are included on the AMC335 These ports use the Broadcom BCM5704S Dual MAC PHY IC to connect the MPC8270 PCI bus to the host via the AMC 2 interface The BCM5704S supports the 1000BASE X interface through an integrated SerDes PHY whose control registers are specified in the MAC registers An MDC and MDIO serial control interface is implemented inside the MAC PHY via a bit banged register an auto mode Refer to the MDI register access section of the BCM57XX Programmer s Reference Guide for additional information The Ethernet port address mapping is defined in Table 2 1 Ethernet Port Mapping below Table 2 1 Ethernet Port Mapping Physical Port AMC Port Dual MAC Port PHY MDIO Address internal 1 0 0 1 2 1 1 1 See Ethernet Interfaces on page 118 for a link to additional information for this device Memory Memory on the AMC335 consists of the following components SDRAM Flash Memory EEPROM The memory address map is discussed in Memory Map on page 26 SDRAM Code storage and data buffering on the AMC335 are provided by a 128 MB Synchronous DRAM SDRAM array which is available to both the MPC8270 and the PI7C9X110 PCI Express bridge The SDRAM memory bank is comprised of individual chips mounted on both sides of the base board The SDRAM architecture provides
106. o handle the module 35 Chapter 3 Getting Started A Caution Avoid touching areas of integrated circuitry Static discharge can damage these circuits System Requirements The following topics provide information about the system requirements Compatibility Electrical and Environmental Requirements Compatibility The AMC335 is offered with either a mid size or full size front panel See AMC335 Front Panel on page 20 for example of a mid size front panel The AMC335 is compliant with the PICMG Advanced Mezzanine Card AMC O Specification R2 0 It is designed to be hot swappable into a mid size or full size bay in an AdvancedTCA or MicroTCA platform The AMC335 also supports the following PICMG subsidiary specifications AMC 1 PCI Express Type 1 for x1 AMC 2 1GbE Types E1 and E2 FCLKA The AMC335 requires the carrier to source FCLKA to the module The AMC 1 R2 0 specification requires that FCLKA is e keyed The AMC335 is shipped from the factory configured for AMC 1 R2 0 e keying of FCLKA AMC 1 R1 0 carriers do not e key FCLKA If the AMC335 does not come out of reset when powered on it is likely that FCLKA is not configured properly for the specific carrier For more information about configuring FCLKA on this AMC335 please contact Performance Technologies Customer Support and Services Electrical and Environmental Requirements 36 Electrical specifications are presented in detail in Electrical
107. ologies shall at its option refund the purchase price repair or replace the product provided proof of purchase and written notice of nonconformance are received by Performance Technologies within 12 months of shipment or in the case of software and integrated circuits within ninety 90 days of shipment and provided said nonconforming products are returned F O B to Performance Technologies s facility no later than thirty days after the warranty period expires Products returned under warranty claims must be accompanied by an approved Return Material Authorization number issued by Performance Technologies and a statement of the reason for the return Please contact Performance Technologies or its agent with the product serial number to obtain an RMA number lf Performance Technologies determines that the products are not defective Buyer shall pay Performance Technologies all costs of handling and transportation This warranty shall not apply to any products Performance Technologies determines to have been subject to testing for other than specified electrical characteristics or to operating and or environmental conditions in excess of the maximum values established in applicable specifications or have been subject to mishandling misuse static discharge neglect improper testing repair alteration parts removal damage assembly or processing that alters the physical or electrical properties This warranty excludes all cost of shipping customs cl
108. on the different models of the AMC335 may be useful EIA RS232C Specification EIA RS422 Specification EIA ElA530 Specification ITU V 35 Specification Consult the following Web sites for more information http Avww eia org e http Avww tiaonline org index cfm http Avww itu int net home index aspx User Documentation The latest product information and user manuals are available at the Performance Technologies Web site http www pt com Information specific to the AMC335 is available at this Web page http go pt com amc335 119 Chapter 10 Data Sheet Reference 120 A AER P _ Index dl yp A D absolute maximum ratings 0 000 000 ee eee 107 device Dur tat ture ea ee oe area Paces 49 ACCESSOr ES coco 18 dual VHDCI I O connector 2 04 18 20 23 ambient temperature 2 AA 36 PINOUT sea seen an rer ee 88 AMC connector pinout lt LL 70 application code enable SW3 4 Ls 40 E B EEPROM devices si carro ria NAN 26 EEPROM write protect SW3 2 a 40 block diagram ks a a is ka ete an 21 EEWP in na ne ne KS een 40 board status APP LED a 31 EIA530 JA ae a E 59 hydra cable options LL 19 break detect enable SW3 3 oooooooooonoooo 40 hydra cable pinout a 91 BRK DET ENF cotorra ii 40 Model amain hk npa T 18 PINOUT au ma ted aan NA GANAN en 77 C signals on dual VHDCI connector 77 electrical specifi
109. onnector Pinout Continued AdvancedMC Card Edge Connector Pin Signal Driven Mating Pin Function Pin Signal Driven Mating Pin Function on By on Module By Module 31 GND First Logic Ground 140 GND First Logic Ground 32 RX2 Third Port 2 RX 139 TCLKD Third Port 16 TX 33 RX2 Third Port 2 RX 138 TCLKD Third Port 16 TX 34 GND First Logic Ground 137 GND First Logic Ground 35 TX3 Third Port 3 TX 136 TCLKC Third Port 16 RX 36 TX3 Third Port 3 TX 135 TCLKC Third Port 16 RX 37 GND First Logic Ground 134 GND First Logic Ground 38 RX3 Third Port 3 RX 133 TX15 Third Port 15 TX 39 RX3 Third Port 3 RX 132 TX15 Third Port 15 TX 40 GND First Logic Ground 131 GND First Logic Ground 41 ENABLE Carrier Second AMC Enable 130 RX15 Third Port 15 RX 42 PWR Carrier First Payload Pwr 129 RX15 Third Port 15 RX 43 GND First Logic Ground 128 GND First Logic Ground 44 TX4 Third Port 4 TX 127 TX14 Third Port 14 TX 45 TX4 Third Port 4 TX 126 TX14 Third Port 14 TX 46 GND First Logic Ground 125 GND First Logic Ground 47 RX4 Third Port 4 RX 124 RX14 Third Port 14 RX 48 RX4 Third Port 4 RX 123 RX14 Third Port 14 RX 49 GND First Logic Ground 122 GND First Logic Ground 50 TX5 Third Port 5 TX 121 TX13 Third Port 13 TX 51 TX5 Third Port 5 TX 120 TX13
110. orts A B C and D The following topics describe the I O ports the Serial Management Controllers SMCs and the pinouts for the four parallel I O ports Key topics in this chapter include I O Ports on page 95 Serial Management Controllers on page 96 MPC8270 Parallel Port Pin Assignments on page 96 I O Ports Each pin in the I O ports can be configured as a general purpose I O signal or as a dedicated peripheral interface signal Port C is unique in that 16 of its pins can generate interrupts to the internal interrupt controller See Table 2 2 MPC8270 Interrupt Sources on page 27 for more information Each pin can be configured as an input or an output and has a latch for data output read or written at any time and configured as general purpose l O or a dedicated peripheral pin Some of the pins can be configured as open drain the pin can be configured in a wired OR configuration on the module The pin drives a zero voltage but three states when driving a high voltage Note that port pins do not have internal pull up resistors Due to the MPC8270 s 95 Chapter 6 MPC8270 Parallel I O Ports significant flexibility many dedicated peripheral functions are multiplexed onto the ports The functions are grouped to maximize the pin s usefulness in the greatest number of MPC8270 applications Refer to the MPC8270 PowerQUICC II User s Manual for more information on the various peripheral setups See Freesc
111. port 3 differential RS449 ST A EIA530 DB A T41 TXCI B 3 Input 100 Ohms RS422 SCTE port 3 differential RS449 ST B ElA530 DB B T39 DCD A 3 Input 100 Ohms RS422 DCD port 3 differential RS449 RR A EIA530 CF A T38 DCD B 3 Input 100 Ohms RS422 DCD port 3 differential RS449 RR B EIA530 CF B Table 5 5 RS422 RS449 EIA530 Signals and Pins Continued Serial I O Connector Pin Signal Direction Termination Description Name T2 DSR A 3 Input 100 Ohms RS422 DSR port 3 differential RS449 DM A EIA530 CC A T1 DSR B 3 Input 100 Ohms RS422 DSR port 3 differential RS449 DM B EIA530 CC B T8 CTS A 3 Input 100 Ohms RS422 CTS port 3 differential RS449 CS A ElA530 CB A T7 CTS B 3 Input 100 Ohms RS422 CTS port 3 differential RS449 CS B ElA530 CB B T36 RXC A 3 Input 100 Ohms RS422 RXC port 3 differential RS449 RT A ElA530 DD A T35 RXC B 3 Input 100 Ohms RS422 RXC port 3 differential RS449 RT B ElA530 DD B T23 GND Signal Ground for I O connector T30 RXD A 4 Input 100 Ohms RS422 Receive Data port 4 differential RS449 RD A EIA530 BB A T31 RXD B 4 Input 100 Ohms RS422 Receive Data port 4 differential RS449 RD B EIA530 BB B T21 DTR A 4 Output NA RS422 DTR port 4 RS449 TR A ElA530 CD A T22 DTR B 4 Output NA RS422 DTR port 4 RS449 TR B ElA530 CD B T24 TXD A 4 Output NA RS422 Transmit Data port 4 RS449 SD A ElA530 BA A T25 TXD B
112. press Serial Bit Rate PI7C9X110 PCI Express bridge 264 MHz MPC8270 Internal Multiplying PLL MPC8270 CPU Internal Use 198 MHz MPC8270 Internal Multiplying PLL MPC8270 CPM Internal Use 100 MHz PCI Express Reference Clock PI7C9X110 PCI Express Bridge Reference Clock Input 66 MHz Crystal Controlled Clock Oscillator CPU SDRAM and logic 66 MHz MPC8270 Internal PLL Local PCI Bus 25 MHz BCM5704S Ethernet Clock Dual PCI MAC PHY 1000Base X Ethernet 7 372 MHz MMC CPU Clock ATmega CPU Clock Communications MPC8270 Internal PLL Various baud rates generated by the SCC Baud Rate Baud Rate Generator typically lt 2 0 MHz 500 KHz TPS5450 Switching Power Supply Internal Clock Source Oscillator Steering The AMC335 supports an optional crystal oscillator to provide custom synchronous clock speeds For synchronous serial applications receive and transmit data signals may be accompanied by external receive and or transmit clock signals To manage the options for each clock line source and destination a clock multiplexor is provided The source and direction of the clocks are set up in a series of custom registers and controlled by local logic The Receive Clock of any serial channel can be sourced from the serial port receive clock signals RXCLK n or can be sourced from an optional external clock contact Performance Technologies Customer Support and Services for external oscillator OPTCLK support AMC335 Functional Blocks The Transmit Clock pin on the MP
113. programmable flash For more information refer to the Atmel Web site http www atmel com dyn resources prod documents doc2467 pdf Refer to the Intel IPMI home page for information concerning the Intelligent Platform Management Interface including the Intelligent Platform Management Interface v1 5 Specification and the Intelligent Platform Management Interface Implementer s Guide http developer intel com design servers ipmi spec htm PICMG Specifications The AMC335 is compliant with the following PICMG specifications e PICMG AMC 0 R 2 0 Specification IPMI v1 5 Specification These specifications can be purchased from PICMG PCI Industrial Computers Manufacturers Group A short form specification is also available at PICMG s Web site https www picmg org 118 PCI Express Specifications PCI Express Specifications The following PCI Express specifications can be purchased from the PCI SIG Short form specifications in Adobe Acrobat format PDF are also available at the PCI SIG Web site http www pcisig com specifications e PCI Local Bus Specification Revision 2 2 1998 PCI Special Interest Group PCI Express Base Specification Revision 1 0 PCI Special Interest Group PCI Express Card Electromechanical Specification Revision 1 0 PCI Special Interest Group Electronic Industries Alliance Specifications The following Electronic Industries Alliance ElA specifications for the communication standards provided
114. ption pinout and cabling information for the AMC335 Chapter 6 MPC8270 Parallel I O Ports on page 95 provides information about the two general purpose serial management controllers and the four general purpose parallel I O ports on the AMC335 Chapter 1 About This Guide Chapter 7 Reset on page 101 describes the AMC335 reset types with their respective sources Chapter 8 Specifications on page 107 contains electrical environmental and mechanical specifications as well as reliability data Chapter 9 Agency Approvals on page 111 presents agency approvals and certification information Chapter 10 Data Sheet Reference on page 117 provides information on data sheets devices standards specifications and documentation for the technology designed into the AMC335 An Index on page 121 is also provided The AMC335 assembly should be used in conjunction with the Performance Technologies software package that you have chosen for example NexusWare Core The most current documentation to support the additional components that you purchased from Performance Technologies is available at http www pt com under the product you are inquiring about Text Conventions This guide uses the following text conventions Convention Used For Monospace font Monospace font represents sample code Bold font Bold font represents Paths File names UNIX commands User input Ita
115. r ports 1 4 Table 5 11 V 35 Hydra Cable Connector Pinout Pin Signal Name Description R RXD Receive Data T RXD Receive Data H DTR Data Terminal Ready P TXD Transmit Data S TXD Transmit Data C RTS Request To Send B GND Signal Ground U TXC Transmit Clock W TXC Transmit Clock Y TXCI Transmit Clock In AA TXCI Transmit Clock In F DCD Data Carrier Detect J RI Ring Indicator E DSR Data Set Ready K LT Local Test D CTS Clear To Send V RXC Receive Clock X RXC Receive Clock A CGND Chassis Ground 92 Serial Cable Connectors Console Cable Option A console cable providing an RD Series DSUB nine position female connector is available for each communication standard The pin assignments for the console cable which are identical for each standard are shown in Table 5 12 RS232C RS422 RS449 EIA530 V 35 Console Cable Option Pinout below Table 5 12 RS232C RS422 RS449 EIA530 V 35 Console Cable Option Pinout Pin Signal Name Connected to Pins 4 and 6 TXD RXD Connected to Pins 1 and 6 GND Connected to Pins 1 and 4 Connected to Pin 8 Connected to Pin 7 G OO LO O AJ wo N 93 Chapter 5 Connectors 94 Chapter ye EEE AEE Vs sm Xy NA MPC8270 Parallel I O Ports Overview The Communications Processor Module CPM on the MPC8270 supports four general purpose parallel I O p
116. rature Monitoring 2 paa gt s ne er aa 109 Mechanical Specifications aaa paa han DAGDAG ee 109 KA AA AA 110 Chapter 9 Agency Approvals 111 OVEWIEWS 4 608 Sie ee S L DEN i wees she Seeds ps 111 Network Equipment Building System NEBS and European Telecommunications Standards Institute ETSI a 112 Contents AA O a a A 112 EN55022 Radiated and Conducted Emissions 0c e eee nennen 112 EN300 386 Electromagnetic Compatibility EMC ka 112 EN55024 lmm nlty iia teen pasu riai A AA ER ehe 112 SAT ern ans ee a ee 113 PUG USA Glass A NOTCE He Bean E Det 113 Industry Canada Class A Notice 2444 rau Bads Di a ka Er En ER A A 113 Product Safety Information ss sast 20 s aa id Boa eee anaes a E db 113 Safety Preca tions iu I ra ias bass eee a 113 Compliance with RoHS and WEEE Directives LLP 115 Chapter 10 Data Sheet Reference 117 VV6NIEW dang ia dd aid pia ott a A aa Bind na dea e aid 117 Freescale MPC8270 PowerQUICC II Processor LL 117 POLEXPFESS BIIdGE 514 K bn bike ik ea een 118 Ethernet Intertaces L Ls mar He tt RN ts I ae ee ee wae NATA 118 Module Management Controller 0 0 00 cece te eee 118 PICMG Specifications gt ae u en u BANAAG Pe ee Pee ae SE 118 PCI Express Specifications 2 12 ee noe ee nd oe ek nee 119 Electronic Industries Alliance Specifications a 119 User Documentation cer ageless Hiway aa S 119 Index 121 Contents Tables AA AAA AN AAN Vs sm Xy DAA AS Table 2 1
117. reescale MPC8270 PowerQUICC Il Processor The AMC335 uses a Freescale MPC8270 PowerQUICC II CPU which is discussed in the documentation for the MPC8280 family For more information about the Freescale MPC8270 PowerQUICC II integrated communications processor refer to the following documents at the Freescale Web site http www freescale com e Freescale MPC603e RISC Microprocessor User s Manual Freescale MPC8280 PowerQUICC II Family User s Manual e Freescale MPC8280 PowerQUICC II Family Reference Manual 117 Chapter 10 Data Sheet Reference Freescale MPC8280 PowerQUICC II Family Hardware Specifications e Freescale MPC8280 PowerQUICC II Family Device Errata e Freescale MPC8280 PowerQUICC II Family Technical Summary PCI Express Bridge The AMC335 incorporates a PCI to PCI Express bridge PI7C9X110 to connect the CPU to the host PCI Express root complex For more information refer to the Pericom PI7C9X110 PCI Express to PCI Reversible Bridge Data Sheet at the Pericom Web site http www pericom com products pci P17C9X110 Ethernet Interfaces Ethernet is implemented on the AMC335 via the Broadcom BCM5704S 1000BaseX Dual MAC PHY Ethernet controller For more information about this device refer to the Broadcom Web site http www broadcom com products Enterprise Networking Gigabit Ethernet Controllers BCM5704S Module Management Controller The MMC is implemented with Atmel s 8 bit microcontroller with 128 KB in system
118. riate AMC slot in the chassis and slide the AMC into the slot aligning the module with the guides near the top of the slot The module audibly snaps into place when properly inserted When the AMC card edge connector makes proper contact with the backplane AMC connector the blue hot swap LED turns ON and the hardware connection process begins 3 Press the handle toward the front panel to lock the module in the chassis When the module is operational the blue hot swap LED turns OFF 4 Connect any cables from peripheral devices Connecting the Cable Removing the AMC335 With a grounding strap connected to your wrist or ankle perform the following steps to remove the module 1 Disconnect any peripheral device cables from the module 2 Gently press your thumb against the front panel of the module while pulling the handle away from the front panel to unlock the module The blue hot swap LED blinks to indicate that the handle is open and the module is waiting to be deactivated It is not yet safe to extract the module in this state 3 Wait until the blue hot swap LED stops blinking and remains illuminated to indicate that the module is ready for extraction 4 When the blue hot swap LED stops blinking and remains illuminated the module is quiesced and module payload power is disabled It is now safe to extract the module Gently pull on the handle to remove the module from the system 5 Carefully slide the module straight out of the
119. roper connection options should be specified in the ipmitoo1 command line See Accessing an MMC with ipmitool on page 62 for the list of available ipmitool command line connection options HPM 1 Commands The ipmitoo1 utility supports the following HPM 1 commands which are described on the following pages targetcap on page 64 compprop on page 65 upgrade on page 66 activate on page 67 rollback on page 67 rollbackstatus on page 67 63 Chapter 4 System Monitoring and Alarms 64 targetcap Get the target upgrade capabilities This command can be used to find out the upgrade capabilities of an MMC ipmitool Example ipmitool I targetcap PICMG HPM 1 hpm targetcap lan H 192 168 0 2 Upgrade Agent 1 0 TARGET UPGRADE CAPABILITI ES HPM 1 Vers TOM es Component 0 presence Component 1 presence Component 2 presence Component 3 presence Component 4 presence Component 5 presence Component 6 presence Component 7 presence Upgrade undesirable Aut rollback override IPMC degraded Defered activation Service affected Manual rollback Self test Upgrade timeout Self test Inaccessibility 1 Defered is misspelled in the ipmitoo1 utility
120. sh storage Full RS232C RS422 RS449 ElA530 or V 35 physical interface support on all four ports Two 1000Base X Ethernet ports AMC 2 type E1 and E2 PCI Express x1 lane support at 2 5 Gbps AMC 1 On board RS232C debug port Full board AMC card edge accessible JTAG scan chain System management bus On board power regulation and control Power on reset generator and push button reset switch Application Status APP Out of Service OOS In Service IS and Hot Swap LED indicators Supports NexusWare Core CGL OS and development environment Supports NexusWare WAN Protocol communications software including Radar Receiver SBSI TADIL B HDLC X 25 Frame Relay ASYNC Supports Solaris 9 10 Windows XP and Linux 64 bit operating systems RoHS compliant For a full size option contact the Performance Technologies Sales team sales pt com for more information Chapter 2 Introduction AMC335 Front Panel The front panel of the AMC335 shown in Figure 2 1 AMC335 Front Panel contains the following elements A dual VHDCI connector carrying four independent serial I O ports See Serial I O Connector on page 73 for more information about this connector One black jackpost and three silver jackposts To properly connect the cable to the AMC335 align the black jackscrew on the cable with the black jackpost on the front panel See Connecting the Cable on page 43 for more information about connecting the cable
121. sions below Length 180 6 mm 7 11 in Width 73 5 mm 2 89 in Height 19 05 mm 0 75 in mid sized front panel Weight 0 11 kg 0 25 Ibs Front Panel Bracket Mid and full size AMC O bracket with opening for a dual VHDCI I O comnector Figure 8 1 AMC335 Dimensions gt 180 6 mr gt p 73 5 mm 109 Chapter 8 Specifications Reliability Table 8 2 Reliability Data shows reliability data for the models of the AMC335 Table 8 2 Reliability Data AMC335 Model MTBF MTTR PT AMC335 12289 RS232C 383 371 hours 3 minutes PT AMC335 12258 RS422 383 371 hours 3 minutes PT AMC335 12287 V 35 383 371 hours 3 minutes 110 MTBF calculated using Bellcore SR 332 Issue 2 Chapter rm og AA AA EE ee Xy ie Agency Approvals Overview This chapter presents agency approval and certification information for the AMC335 Four Port WAN Communications AMC module Key topics in this chapter include Network Equipment Building System NEBS and European Telecommunications Standards Institute ETSI on page 112 CE Certification on page 112 EN55022 Radiated and Conducted Emissions on page 112 EN300 386 Electromagnetic Compatibility EMC on page 112 EN55024 Immunity on page 112 Safety on page 113 FCC USA Class A Notice on page 113 Industry Canada Class A Notice on page 113 Product Sa
122. supports the V 35 standard in a DTE format The V 35 standard is also supported through a hydra cabling option Table 5 6 V 35 Signals and Pins shows the supported signals and their positions on the dual VHDCI connector Serial I O Connector Note Some of the pins on the connector may not be included in the table For each electrical standard the pins that are not included in the table for that standard MUST BE LEFT UNCONNECTED Table 5 6 V 35 Signals and Pins 2 ignal bo aa RIA ME Pin Signa Direction Termination Description Name B3 B6 B9 B12 Signal B15 B16 B19 Ground B20 B23 B26 B29 B32 B37 B40 B46 B49 B50 B53 B54 B60 B63 B66 T3 T6 T12 T15 T16 T19 T20 T26 T29 T32 T37 T40 T43 T46 T49 T50 T53 T54 T57 T60 T63 T66 B64 RXD A 1 Input 100 Ohms V 35 Receive Data port 1 differential V 35 104 M 34 R 125 Ohms to ground B65 RXD B 1 Input 100 Ohms V 35 Receive Data port 1 differential V 35 104 M 34 T 125 Ohms to ground B55 DTR1 Output NA V 35 Data Terminal Ready port 1 V 35 108 M 34 H B58 TXD A 1 Output NA V 35 Transmit Data port 1 V 35 103 M 34 P B59 TXD B 1 Output NA V 35 Transmit Data port 1 V 35 103 M 34 S B24 RTS1 Output NA V 35 Request To Send port 1 V 35 105 M 34 C B57 GND1 NA V 35 port 1 Signal Ground V 35 102 M 34 B B21 TXC A 1 Output NA V 35 Transmit Clock port 1 V 35 113 M 34 U B22 TXC B 1 Output NA
123. t PDIRA 0 In PA31 Default Unassigned PA30 Default Unassigned PA29 Default Unassigned PA28 Default Unassigned PA27 Default Unassigned PA26 Default Unassigned PA25 Default Unassigned PA24 Default Unassigned PA23 Default Unassigned PA22 Default Unassigned PA21 Default Unassigned PA20 Default Unassigned PA19 Default Unassigned PA18 Default Unassigned PA17 Default Unassigned PA16 Default Unassigned PA15 Default Unassigned PA14 Default Unassigned PA13 Default Unassigned PA12 Default Unassigned PA11 Default Unassigned PA10 Default Unassigned PA9 SMTXD2 PA8 SMRXD2 PA7 Default Unassigned PA6 MACPHY_SMB_CLK PAS MACPHY_SMB_DAT PA4 PA3 EE_CS PA2 EE_SCL PA1 EE_DI PAO EE_DO 97 Chapter 6 MPC8270 Parallel I O Ports MPC8270 Port B Pin Assignments Table 6 2 MPC8270 Port B Pin Assignments Pin Function PPARB 1 Pin PPARB 0 PSORB 0 PSORB 1 PDIRB 1 Out PDIRB 0 In PDIRB 1 Out PDIRB 0 In PDIRB 1Out PDIRB 0 In PB31 Default Unassigned PB30 Default Unassigned PB29 Default Unassigned PB28 Default Unassigned PB27 Default Unassigned PB26 Default Unassigned PB25 Default Unassigned PB24 Default Unassigned PB23 Default Unassigned PB22 Default Unassigned PB21 Default Unassigned PB20 Default
124. t Sensor Device Records of an MMC at IPMB L address 0x72 via a Shelf Manager with the IP address 192 168 0 2 and a carrier IPMC at IPMB 0 address 0x82 the following command line should be used ipmitool I lan H 192 168 0 2 T 0x82 B 0 t 0x72 b 7 A none sdr Accessing an MMC via a Serial Interface The following ipmitool command line parameters are used for communicating with the MMC via a serial interface I serial terminal This command line parameter instructs the ipmitoo1 utility to use the serial interface for communications with the MMC D lt dev baudrate gt This command line parameter specifies the serial device and baud rate settings to use For Linux hosts the serial device is the system path to the device node e g dev ttyS0 For the Cygwin flavor of the ipmitool utility Windows serial device names are translated as follows the COM1 device name is mapped to dev ttyS0 COM2 is mapped to dev ttyS1 and so on The supported baud rates are 2400 9600 19200 38400 57600 and 115200 For example to fetch and print Sensor Device Records of an MMC via a serial interface connection with a baud rate of 9600 the following command line should be used ipmitool I serial terminal D dev ttyS0 9600 sdr Using ipmitool for HPM 1 Upgrades The ipmitool utility has built in HPM 1 upgrade functionality and can be used as an upgrade agent To be able to send HPM 1 commands to the MMC the p
125. ta port 2 V 35 103 M 34 S B11 RTS2 Output NA V 35 Request To Send port 2 V 35 105 M 34 C B43 GND2 NA V 35 port 2 Signal Ground V 35 102 M 34 B B14 TXC A 2 Output NA V 35 Transmit Clock port 2 V 35 113 M 34 U B13 TXC B 2 Output NA V 35 Transmit Clock port 2 V 35 113 M 34 W Table 5 6 V 35 Signals and Pins Continued Serial I O Connector 4 ignal ey Baka At Pin Signa Direction Termination Description Name B8 TXCI A 2 Input 100 Ohms V 35 Transmit Clock In port 2 differential V 35 114 M 34 Y 125 Ohms to ground B7 TXCI B 2 Input 100 Ohms V 35 Transmit Clock In port 2 differential V 35 114 M 34 AA 125 Ohms to ground B5 DCD2 Input 5K Ohms to V 35 Data Carrier Detect port 2 ground V 35 109 M 34 F B4 RI2 Input 5K Ohms to V 35 Ring Indicator port 2 ground V 35 125 M 34 J B36 DSR2 Input 5K Ohms to V 35 Data Set Ready port 2 ground V 35 107 M 34 E B47 LT2 Output NA V 35 Line Test port 2 V 35 M 34 K B42 CTS2 Input 5K Ohms to V 35 Clear To Send port 2 ground V 35 106 M 34 D B2 RXC A 2 Input 100 Ohms V 35 Receive Clock port 2 differential V 35 115 M 34 V 125 Ohms to ground B1 RXC B 2 Input 100 Ohms V 35 Receive Clock port 2 differential V 35 115 M 34 X 125 Ohms to ground T5 RXD A 3 Input 100 Ohms V 35 Receive Data port 3 differential V 35 104 M 34 R 125 Ohms to ground T4 RXD B 3 Input 100 Ohms V 35 Receive Data port 3 d
126. tch on its front panel When the system reset button is pressed the AMC335 resets itself Since the switch is recessed a tool is necessary to reach through the front panel to reset the AMC335 An unfolded paper clip works well for this application See AMC335 Front Panel on page 20 for the location of this button Hot Swap Handle Switch The AMC335 provides a hot swap handle on its front panel see Figure 2 1 AMC335 Front Panel on page 20 This handle is attached to a mechanical latching mechanism and to the hot swap switch When this switch opens or closes it sends a request via the MMC to the carrier for a hot swap extraction or insertion Its function and behavior is defined by the PICMG Advanced Mezzanine Card AMC O Specification R2 0 The hot swap LED indicates the state of the module during extraction and insertion See LED Indicators on page 31 for more information Physical Installation Before installing the AMC335 make sure the module is correctly configured for your application Installing the AMC335 42 The following instructions assume that chassis power is on and that the system supports hot swap insertion If the system does not support hot swap power must be turned off prior to installation With a grounding strap connected to your wrist or ankle perform the following steps to install the module 1 Unlock the ejector handle by gently pulling it away from the front panel 2 Select an approp
127. te WAN connectivity solutions for MTP 2 Frame Relay HDLC LAPD X 25 and Radar OS support includes all OS that support TCP IP such as Solaris Linux and Windows For the Solaris environment Performance Technologies ComLink Communications Software provides both a transparent link to all SunLink protocols as well as a documented set of driver primitives for developing applications 33 Chapter 2 Introduction 34 Chapter A AAA AN AN N A eer ie Getting Started Overview This chapter provides information about installing and configuring the AMC335 Key topics in this chapter include Unpacking on page 35 System Requirements on page 36 Connectivity on page 37 Switches on page 37 Physical Installation on page 42 Connecting the Cable on page 43 Unpacking Inspect the packing container for any damage If the container appears damaged immediately contact the company responsible for the shipping and report the damage before opening and unpacking the container lt is recommended that you also notify Performance Technologies see Customer Support and Services on page 15 for assistance information Caution To reduce the risk of damage to the AMC335 the module must be protected from electrostatic discharge and physical shock Never remove any of the socketed parts except in a static free environment Use the anti static bag shipped with the product t
128. the ability to Synchronously burst data at a high data rate with automatic column address generation Interleave between internal banks in order to hide PRECHARGE time e Randomly change column addresses on each clock cycle during a burst access The total SDRAM memory is 128 MB supported at 66 MHz bus speed The data port size is 64 bits The MPC8270 internal SDRAM controller takes care of all low level SDRAM operations including row and column multiplexing precharge times and refresh Flash Memory An on board non volatile programmable Flash memory 32 MB x 8 device is provided for startup code and application storage The device is accessed by the MPC8270 through the buffered data bus The application Flash is a non volatile memory that has the following general characteristics 25 Chapter 2 Introduction 26 Read accesses to the device are the same as any EPROM The data appears on DQ0 DQ7 on the buffered data bus For writing purposes the device has 256 blocks of byte wide data storage The storage blocks have 128 KB of storage each Selecting writing and erasing the blocks are done by using a Common Flash Interface CFI and a Scalable Command Set SCS All read erase and program operations are accomplished using only a single power supply Internally generated and regulated voltages are provided for the program and erase operations EEPROM Three small Electrically Erasable Programmable Read only Memory
129. the model of AMC335 The following four position 6ft hydra cables which must be ordered separately are available for use with the AMC335 PT ACC335 12233 Cable with Console RS232C male DB 25 connector PT ACC335 12234 Cable without Console RS232C male DB 25 connector PT ACC335 12203 Cable with Console RS449 male DB 37 connector PT ACC335 12205 Cable without Console RS449 male DB 37 connector PT ACC335 12256 Cable with Console ElA530 male DB 25 connector PT ACC335 12257 Cable without Console ElA530 male DB 25 connector PT ACC335 12290 Cable with Console V 35 male M34 connector PT ACC335 12291 Cable without Console V 35 male M34 connector The AMC335 ships with the appropriate hydra cable for the module model ordered See Serial Cable Connectors on page 88 for information about the various connectors and cable pinouts AMC335 Features The AMC335 includes the following features 4 Single mid size PICMG AMC 0 processor module full size option is available PICMG AMC 0 R2 0 AMC 1 R1 0 and AMC 2 R1 0 compliant IPMI v1 5 specification compliant Four high speed synchronous serial ports capable of sustaining 2 Mbps bi directional per port Simultaneously sustained 8 Mbps maximum line speed Freescale MPC8270 PowerQUICC II Integrated Communications Processor 266 MHz 128 MB dedicated processor SDRAM memory handles extensive on board traffic and protocol requirements 32 MB of on board application fla
130. ystems including next generation wireless and IP based systems NexusWare WAN Performance Technologies suite of NexusWare WAN protocols include but are not limited to HDLC X 25 Frame Relay and Radar Receiver When combined with Performance Technologies embedded products these enhance the ability to create flexible and efficient product platforms such as radar gateways converged serial gateways and front end I O systems The WAN software products are offered as installable software packages for NexusWare Core or as turnkey packages for those developers interested in the protocol package by itself Whether the installable or the turnkey solution is chosen developers are provided with a well documented and powerful API to assist in the development process Operating Systems The AMC335 is enabled with the Linux based NexusWare development environment Due to the wide acceptance and extensive number of publicly available applications and protocols system developers can bring sophisticated systems to market in a much shorter time With a well defined API the integrated protocol suite from Performance Technologies reduces time to market by eliminating unnecessary development time at the hardware protocol level The protocols for our standard WAN hardware products enable development engineers to proceed directly to integration and application development Performance Technologies suite of WAN communications protocols provides comple
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