aTCA-9300 Dual Intel® Xeon® E3 1275V2/1225V2 AdvancedTCA Processor Blade User’s Manual Manual Revision: Revision Date: Part No.: 1.02 Preliminary April 15, 2013 50- 1G022-1000 Advance Technologies; Automate the World.
Revision History Revision 1.00 1.01 1.02 Release Date January 4 , 2013 April 1, 2013 April 15, 2013 Description of Change(s) Preliminary release Correct 3.3.6.1 switch table Update Base and Fabric Channel LED indicators Copyright 2013 ADLINK Technology, Inc. All Rights Reserved. The information in this document is subject to change without prior notice in order to improve reliability, design, and function and does not represent a commitment on the part of the manufacturer.
Table Of Contents Revision History ......................................................................................................................2 1 Overview .............................................................................................................................5 1.1 Introduction .....................................................................................................................5 1.2 Block Diagram .................................................................
5.2.1 Installing the Blade .......................................................................................................36 5.2.2 Removing the Blade .....................................................................................................40 5.3 Firmware Update Procedure.........................................................................................43 5.3.1 Update Over Serial Interface ........................................................................................43 5.
1 Overview 1.1 Introduction The ADLINK aTCA-9300 is a high performance AdvancedTCA® (ATCA) processor blade featuring dual 4-core Intel® Xeon® processor E3 1275V2 /1225V2, Intel® C216 Chipset, four channel memory up to 32 GB of DDR3 memory and 300 W power supply subsystem. Versatile connectivity includes dual 10GbE Fabric Interfaces, dual GbE Base Interfaces, quad front panel GbE egress ports, front panel dual COM and USB 2.0 ports and front panel VGA connector.
1.
1.3 Package Contents Before opening, please check the shipping carton for any damage. If the shipping carton and contents are damaged, notify the dealer for a replacement. Retain the shipping carton and packing material for inspection by the dealer. Obtain authorization before returning any product to ADLINK. Check that the following items are included in the package.
2 Specifications 2.1 aTCA-9300 Specifications 2.1.1 CPU/ Chipset/ Memory CPU Single 4-core Intel® Xeon® processor E3 1275V2(2.1/1.8GHz QPI 8.0GT/s, 20MB L2 cache, LGA1155 socket) Chipset Memory Intel® C216 Chipset (Intel® BD82C216 Chipset) Registered ECC DDR3-1333/1600 VLP UDIMM Four UDIMM sockets Up to 32GB 2.1.2 Standards Networking Display USB Serial Storage Front Panel I/O Rear I/O on aTCA-R6270 Rear I/O on aTCA-R6280 Standard and Interface PICMG 3.0 R2.0 AdvancedTCA PICMG 3.
2.1.3 Software BIOS Supported OS 2.1.4 AMI BIOS with 8Mbit flash memory Microsoft Windows Server 2008 Microsoft Windows Server 2008 R2 Red Hat Enterprise Linux 6.2/6.3 Contact ADLINK for other OS availability Mechanical & Environmental Dimensions Operating Temperature Storage Temperature Humidity Shock Vibration Compliance 322.25mm x 280mm x 30.
2.2 Power Consumption This section provides information on the power consumption of the aTCA-9300. System configuration (1) Memory: TS1GLK72W6HL 8GB DDR3-1600 ECC UDIMM (2) Graphics: Intel HD Graphics P4000 (3) Power Supply: Chroma DC Power supply 62012P-80-60 (4) CPU: Single 4-core Intel® Xeon® processor E3-1275V2 The following table lists power consumption under different operating systems and applications with a 48V power rail. OS and Application Power Consumption DOS 35.
2.3 Board Layout 2.3.
1 4 7 10 13 16 19 22 25 28 31 34 37 40 43 46 49 52 CN2 (RJ-45) CN5 (RJ-45) CX3 (SFP) U57 (GigaLan) U29 (GigaLan) U51 (GigaLan) U20 (Smart Fusion) BATTERY SW3 BIOS switch SW6 com/ IPMC function JP1 Clear CMOS J3 ZON3 AMC1 AP2 aTCA Key(B) J1E2 XDP (CPU) PSU2 DIMM3 CN0 (RJ-45) 2 5 8 11 14 17 20 23 26 29 32 35 38 41 44 47 50 53 CN3 (RJ-45) CX1 (SFP) CX4 (SFP) U38 (GigaLan) U23 (GigaLan) CPU Socket (1155) U25 (Clock Buffer) SPI Socket SW4 JTAG switch SW2 RTM Reset switch AP1 aTCA Key(RTM) J4 ZON3 BUZZER1 J5 Z
OOS LED HDD LED USER LED GbE (RJ-45) Reset Button RS-232 Serial Port VGA Hotswap LED USB Base and Fabric Channel LEDs 13
2.3.2 Status LED Definitions The following sections describe the front panel Status LEDs: Hot-swap LED, OOS LED, BIOS/OS Boot OK LED, IPMC Payload Power Authorized LED and IPMC Chassis Identify Command LED. 2.3.2.
Base and Fabric Channel LED Base Channel and Fabric Channel LED Fabric 2 Speed and Link BCH2 Speed and Link 1Gbps – OFF 100 Mbps: Green 10Gbps – Orange 1Gbps: Orange Fabric 2 ACT (Green) BCH2 ACT (Green) Blink when accessing Blink when accessing Ethernet I/O Ethernet I/O Fabric 1 Speed and Link BCH1 Speed and Link 1Gbps - OFF 100 Mbps: Green 10Gbps – Orange 1Gbps: Orange Fabric 1 ACT (Green) BCH1 ACT (Green) Blink when accessing Blink when accessing Ethernet I/O Ethernet I/O 15
2.3.2.2 GbE LED LEFT LED: Speed and Link 1Gbps: Amber, 100Mbps: Orange RIGHT LED: ACT Blinking while data exchanging Color: Amber 2.4 Compliance The aTCA-9300 conforms to the following specifications: PICMG 3.0 R2.0 ECN0002 AdvancedTCA PICMG 3.
3 Functional Description 3.1 CPU, Memory and Chipset 3.1.1 CPU The Intel® Xeon® processor E3 1275V2/E3 1225V2/Core i3 implements several key technologies: Two channels of DDR3 Unbuffered Dual In-Line Memory Modules (UDIMM) with a maximum of two DIMMs per channel Integrated I/O with up to 16 lanes for PCI Express Generation 3.
3.1.2 Memory The aTCA-9300 adopts the Intel® Xeon® processor E3 (or Core™ i3) providing two memory channels supporting DDR3 800, 1066, 1333, and 1600 MT/s DIMMs. The maximum memory capacity is 32GB with memory interleaving support. The 400/533/667/800 MHz differential memory clocks are driven by the Intel® Xeon® processor E3 CPU with length-matching and impedance controlled through all the DIMM slots. The DDR3 DIMMs support the I2C interface.
—Supports up to two SPI devices —Supports 20 MHz, 33 MHz, and 50 MHz SPI devices Firmware Hub I/F supports BIOS Memory size up to 8 MB Low Pin Count (LPC) I/F Analog Display (VGA) 3.2 Peripherals The following peripherals are available on the aTCA-9300 blade 3.2.1 Reset The aTCA-9300 is automatically reset by a precision voltage monitoring circuit that detects a drop in voltage below the acceptable operating limit of 4.85V for the 5V line and below 3.2V for the 3.3V line.
3.2.2 SMBus Devices The aTCA-9300 provides a System Management Bus (SMBus) hosted by the Intel® C216. The topology is shown in the diagram below. PECI 1.
3.2.3 GPIO List The following table summarizes GPIO usage on the Intel® C216 Chipset Name GPIO0 GPIO1 GPIO2 GPIO3 GPIO4 GPIO5 GPIO6 GPIO7 GPIO8 GPIO9 GPIO10 GPIO11 GPIO12 GPIO13 GPIO14 GPIO15 GPIO16 GPIO17 GPIO18 GPIO19 GPIO20 GPIO21 GPIO22 GPIO23 GPIO24 GPIO25 GPIO26 GPIO27 GPIO28 GPIO29 GPIO30 GPIO31 GPIO32 GPIO33 GPIO34 GPIO35 GPIO36 GPIO37 Power Well Default 3.3V 3.3V 5 V 5 V 5 V 5 V 3.3V 3.3V 3.3V 3.3V_SB 3.3V_SB 3.3V_SB 3.3V_SB 3.3V_SB 3.3V_SB 3.3V_SB 3.3V 3.
3.3 I/O Interfaces 3.3.1 USB The aTCA-9300 supports four USB 2.0 ports: Two Type-A ports on front panel Two ports routed to RTM On the USB 2.0 front panel port, a USB cable up to 5 meters in length can be used. On the USB 2.0 Rear I/O ports, it is strongly recommended to use a cable less than 3 meters in length for USB 2.0 devices. The USB 2.0 ports are high-speed, full-speed, and low-speed capable. Hi-speed USB 2.
3.3.2 VGA Interface A DB-15 female connector on the front panel provides analog display output. Front Panel VGA Pin Definition (DB-15) Pin 1 2 3 4 5 6 7 8 3.3.3 Name RED GREEN BLUE NC GND GND GND GND Pin 9 10 11 12 13 14 15 Name +5v GND NC DDC_DATA HSYNC VSYNC DDC_CLK Ethernet Connection The aTCA-9300 is equipped with one quad-port Intel® I350 AM4 Gigabit Ethernet Controller and one dual-port Intel® 82576EB Gigabit Ethernet Controller which provide six GbE ports in total.
3.3.4 Serial Port Two serial ports are output to USB Mini-B connectors on the front panel for use as service terminals . The port labeled IPMI is an "IPMC" debug port and the port labeled CPU" is connected to COM 1 of the Super IO chip. Serial Port Pin Definition (USB Mini-B) 3.3.
3.3.6 Switch And Jumper Settings 3.3.6.1 Set Blade Operation Mode Use switch SW3 to set the Blade Operation Mode. Normal operation requires a shelf manager for the blade to boot. Standalone mode allows the blade to boot without a shelf manager. SW3 Blade Operation Normal Mode (default) Standalone Mode 3.3.6.2 Pin 1 OFF OFF Pin 2 OFF OFF Pin 3 OFF ON Pin 4 OFF OFF IPMC JTAG Signal The switch SW4 is designed for hardware debug purposes. Do not change the default settings.
4 Intelligent Platform Management System The purpose of the intelligent platform management system is to monitor, control, and assure proper operation of AdvancedTCA® Boards and other Shelf components. The intelligent platform management system watches over the basic health of the system, reports anomalies, and takes corrective action when needed.
Item Sensor Name Sensor Address (0x9) (10) +3.3V MG (11) +12V (0xA) (12) PCH Temp (0xB) (13) PSU1 Temp (0xC) (14) CPU Thermal Temp (0xD) (15) CPU Inner Temp (0xE) Description Voltage Sensor. Upper Non-Recoverable Threshold = 3.63 Volts Upper Critical Threshold = 3.564 Volts Upper Non-Critical Threshold = 3.498 Volts Lower Non-Critical Threshold = 3.102 Volts Lower Critical Threshold = 3.036 Volts Lower Non-Recoverable Threshold = 2.97 Volts Voltage Sensor.
4.1.1 Sensor Reading (FRU Hotswap Sensor) Request data Response data Byte 1 1 2 3 4 (5) 4.1.2 Data field Sensor Number (FFh = reserved) Completion Code Sensor Reading. [7:0] - Not used. Write as 00h. Standard IPMI byte (See “Get Sensor Reading” in IPMI specification): [7] - 0b = All Event Messages disabled from this sensor [6] - 0b = sensor scanning disabled [5] - 1b = initial update in progress.
Byte 3 4 (5) Data field 0h = No failure. Bus enabled if no override in effect. 1h = Unable to drive clock HI 2h = Unable to drive data HI 3h = Unable to drive clock LO 4h = Unable to drive data LO 5h = Clock low timeout 6h = Under test (the IPM Controller is attempting to determine if it is causing a bus hang).
4.1.3 Sensor Type Watchdog 2 Watchdog Timer Sensor Sensor Type Code 23h Sensor Specific Offset 00h 01h 02h 03h 04h-07h 08h Event This sensor is recommended for new IPMI v1.0 and later implementations.
4.1.4 Sensor Type Version Change Version Change Sensor Sensor Type Code 2Bh Sensor Specific Offset 00h 01h 02h 03h 04h 05h 06h 07h Event 00h Intelligent change detected with associated Entity. Informational. This offset does not imply whether the intelligent change was successful or not. Only that a change occurred. 01h Firmware or software change detected with associated Entity.Informational. Success or failure not implied. 02h Intelligent incompatibility detected with associated Entity.
4.1.5 Request data Response data Get Sensor Reading Command Byte 1 1 2 3 4 (5) Data field Sensor Number (FFh = reserved) Completion Code Sensor reading Byte 1: byte of reading. Ignore on read if sensor does not return an numeric (analog) reading. [7] - 0b = All Event Messages disabled from this sensor [6] - 0b = sensor scanning disabled [5] - 1b = reading/state unavailable (formerly “initial update in progress”).
4.2 IPMI Commands The following table presents all the commands which are supported by the aTCA-9300 in different interfaces and compatible with IPMI v1.5 and PICMG 3.0 R2.0 ECN001. There are two interfaces implemented with IPMI command support.
HPM.1 Upgrade Commands (HPM.
5 Getting Started The aTCA-9300 has been designed for easy installation. However, the following standard precautions, installation procedures, and general information must be observed to ensure proper installation and to preclude damage to the board, other system components, or injury to personnel. 5.1 Safety Requirements The following safety precautions must be observed when installing or operating the aTCA9300.
5.2Installing and Removing the aTCA-9300 5.2.1 Installing the Blade Follow these steps to install the aTCA-9300 blade to the chassis. Step 1 Carefully align the board edges with the chassis guide rails and push the blade inwards.
Step 2 Check if the catch hooks and alignment pins at both ends of the module are correctly inserted into the proper openings. Push inwards on the handles until the blade is firmly seated in the chassis. (Do not force the handles if there is any abnormal resistance or it could damage the connectors and/or backplane.
Step 3 Push the ejector handles inwards until it is locked.
Step 4 Lock both ends of the captive screws.
5.2.2 Removing the Blade Follow these steps to remove the aTCA-9300 blade from the chassis. Step 1 Unlock both ends of the captive screws.
Step 2 Pinch the lever and latch together then pull outwards to release the ejector handles at both ends.
Step 3 Pull the blade outwards from the chassis until it is removed.
5.3 Firmware Update Procedure The aTCA-9300 supports firmware update (IPMC FW, BIOS, FRU) over various interfaces (LAN, KCS, serial interface or IPMB). Please follow the procedures listed below to update the IPMC firmware. Note: IPMB-0 will be disabled during the process of upgrading IPMC firmware. This is a limitation of the IPMC controller (SmartFusion A2F500) 5.3.
To update other images (BIOS, FRU, etc), just replace the target image and the file name while typing command. Item IPMC firmware BIOS File name hpm1fw.img hpm1bios.img Note: 1. The hpm1bios.img always updates the backup BIOS image. 2. Make sure the payload power is off (M1 state) before updating the IPMC firmware 5.3.2 Update over KCS Step1: Prepare an aTCA-9300 with Linux system.
Step3: Select “y” and wait until the string of “firmware update procedure successful” is displayed. To update other images (BIOS, FRU, etc), just replace the target image and the file name while typing command. Item IPMC firmware BIOS 5.3.3 File name hpm1fw.img hpm1bios.img Update over LAN The following IPMItool command line parameters are used for communicating with the carrier IPMC via LAN: -I lan The parameter instructs the IPMItool utility to use the RMCP protocol for communicating with the IPMC.
Step1: Prepare an external x86 PC and connect the target aTCA-9300 via BASE Interface. Put IPMItool and “target image” on the x86 PC with Linux system. Enter the following command: At the password prompt, just press "Enter" key Step2: Select “y” and wait until the string of “firmware update procedure successful” is displayed. To update other images (BIOS, FRU, etc), just replace the target image and the file name while typing command. Item IPMC firmware BIOS File name hpm1fw.img hpm1bios.
6 BIOS 6.1 Starting the BIOS To enter the setup screen, follow these steps: 1. Power on the motherboard 2.Press the < Delete > key on your keyboard when you see the following text prompt: < Press DEL to run Setup > 3. After you press the < Delete > key, the main BIOS setup menu displays. You can access the other setup screens from the main BIOS setup menu, such as Chipset and Power menus. In most cases, the < Delete > key is used to invoke the setup screen.
6.1.2 Navigation The BIOS setup/utility uses a key-based navigation system called hot keys. Most of the BIOS setup utility hot keys can be used at any time during the setup navigation process. These keys include < F1 >, < F10 >, < Enter >, < ESC >, < Arrow > keys, and so on.
There is a hot key legend located in the right frame on most setup screens. →← ↑↓ +Tab Hot Key Left/Right. The Left and Right < Arrow > keys allow you to select a setup screen. For example: Main screen, Advanced screen, Chipset screen, and so on. Up/Down The Up and Down < Arrow > keys allow you to select a setup item or sub-screen. Plus/Minus The Plus and Minus < Arrow > keys allow you to change the field value of a particular setup item. For example: Date and Time.
settings of the BIOS, press the < F3 > key on your keyboard. It is located on the upper row of a standard 101 keyboard. The optimized defaults settings allow the motherboard to boot up with the optimized defaults of options set. This can lessen the probability of conflicting settings. F4 ESC Press the < Enter > key to load optimized defaults. You can also use the < Arrow > key to select Cancel and then press the < Enter > key to abort this function and return to the previous screen.
6.2 Main Setup When you first enter the Setup Utility, you will enter the Main setup screen. You can always return to the Main setup screen by selecting the Main tab. There are two Main Setup options. They are described in this section. The Main BIOS Setup screen is shown below. 6.2.1 System & Board Info The Main BIOS setup screen reports processor, memory and board information. BIOS Vendor Display the BIOS vendor. Core Version Display the BIOS core version.
6.2.2 System Date/System Time Use this option to change the system time and date. Highlight System Time or System Date using the < Arrow > keys. Enter new values using the keyboard. Press the < Tab > key or the < Arrow > keys to move between fields. The date must be entered in MM/DD/YY format. The time is entered in HH:MM:SS format. 6.3 Advanced BIOS Setup Select the Advanced tab from the setup screen to enter the Advanced BIOS Setup screen.
Active Processor Core Number of cores to enable in each processor package. Set this value to All / 1 / 2 / 3. Limit CPUID Maximum When the computer is boots, the operating system executes its CPUID instruction to identify the processor and its capabilities. Before it can do so, it must first query the processor to find out the highest input value the CPUID recognizes. This determines the kind of basic information CPUID can provide the operating system.
6.3.2 SATA Configuration You can use this screen to select options for the SATA Configuration Settings. An example of the SATA Configuration screen is shown below. SATA Controller(s) Enable or disable SATA device. SATA Mode Selection The SATA can be configured as a legacy IDE , RAID and AHCI mode. SATA Controller Speed Indicates the maximum speed the SATA controller can support. SATA Port 0~5 Display SATA device name string.
6.3.3 USB Configuration You can use this screen to select options for the USB Configuration Settings. Use the up and down < Arrow > keys to select an item. Use the < + > and < - > keys to change the value of the selected option. A description of the selected item appears on the right side of the screen. The settings are described on the following pages. An example of the USB Configuration screen is shown below. Legacy USB Support Enables legacy USB support.
6.3.5 Super IO Configuration You can use this screen to select options for the Super IO settings. Use the up and down < Arrow > keys to select an item. Use the < + > and < - > keys to change the value of the selected option. The settings are described on the following pages. The screen is shown below. Serial Port 1,2,3 Configuration Set Parameters of Serial Port 1,2,3 (COM A,B,C). Set this value to Enable/Disable. The screen is shown below.
6.3.6 Serial Port Console Redirection You can use this screen to select options for the serial port console redirection settings. Use the up and down < Arrow > keys to select an item. Use the < + > and < - > keys to change the value of the selected option. A description of the selected item appears on the right side of the screen. The settings are described on the following pages. An example of the Serial Port Console Redirection screen is shown below.
Console Redirection Settings The settings specify how the host computer and the remote computer (which the user is using) will exchange data. Both computers should have the same or compatible settings. The screen is shown below. Terminal Typ VT100+ is the preferred terminal type for out-of-band management. Configuration options: VT100, VT100+, VT-UTF8 , ANSI. Bits per second Select the bits per second you want the serial port to use for console redirection.
Flow Control Set this option to select Flow Control for console redirection. The settings for this value are None, Hardware RTS/CTS. VT-UTF8 Combo Key Support Enabled VT-UTF8 combination key support for ANSI/VT100 terminals.. Set this value to Enable/Disable. Recorder Mode Enabled this mode, only text will be sent. This is to capture terminal data. Set this value to Enable/Disable. Resolution 100x31 Set this option to extended terminal resolution. Set this value to Enable/Disable.
Terminal Type VT-UTF8 is the preferred terminal type for out-of-band management. The next best choice is VT100+ and then VT100. See above, in Console Redirection Settings page, for more Help with Terminal Type/Emulation. Configuration options: VT100, VT100+, VTUTF8 , ASNI. Bits per second Select the bits per second you want the serial port to use for console redirection. The options are 115200 ,57600 ,38400, 19200, 9600. Flow Control Set this option to select Flow Control for console redirection.
Network Stack This option is used for enabling or disabling UEFI network stack for onboard Ethernet. Ipv4 PXE Support This option is used for enable Ipv4 PXE boot support. If disabled IPV4 PXE boot option will not be created. Ipv6 PXE Support This option is used for enable Ipv6 PXE boot support. If disabled IPV4 PXE boot option will not be created. 6.3.8 CPU PPM Configuration Ivybridge PPM configuration parameters. An example screen is shown below. EIST Enable or disable Intel SpeedStep.
Enable/Disable. CPU C6 Report Enable or disable CPU C6 (ACPI C3) report to OS. Set this value to Enable/Disable. CPU C7 Report Enable or disable CPU C7 (ACPI C3) report to OS. Set this value to Enable/Disable. 6.4 Chipset Setup Select the Chipset tab from the setup screen to enter the Chipset BIOS Setup screen. You can select any of Chipset BIOS Setup options by highlighting it using the < Arrow > keys. The Chipset BIOS Setup screen is shown below.
6.4.1 PCH-IO Configuration SB CRID It is for setting the support for PCH Compatibility Revision ID (CRID) functionality High Precision Timer The High Precision Event Timer is a hardware timer used in personal computers. A High Precision Event Timer chip consists of a 64-bit main counter counting at least at 10MHz and a set of up to 256 comparators. HPET is programmed via a memory mapped I/O window that is discoverable via ACPI. The HPET circuit in modern PCs is integrated into the southbridge.
6.4.2 System Agent (SA) Configuration VT-d The Intel Virtualization Technology for Directed I/O. Set this value to Enable/Disable. 6.4.2.2 Memory Configuration Memory Remap Enable or disable memory remap above 4G. Set this value to Enable / Disable.
6.5 Boot Setup Select the Boot tab from the setup screen to enter the Boot BIOS Setup screen. You can select any of the items in the left frame of the screen, such as Boot Device Priority, to go to the sub menu for that item. You can display an Boot BIOS Setup option by highlighting it using the < Arrow > keys. The Boot Settings screen is shown below: Quiet Boot Disabled - Set this value to allow the computer system to display the POST messages.
Option ROM Messages Set this option to enable for allowing system to display PCI devices’ option ROMs during system boot up. INT19 Trap Response Interrupt 19 is the software interrupt that handles the boot disk function. When set to Enabled, this item allows the option ROMs to trap interrupt 19. Set Boot Priority Set Boot Option #1 ~2 boot priority. Hard Disk Drive BBS Priorities Specifies the boot device priority sequence from available hard drives.
Launch PXE OpROM policy This option controls the execution of UEFI and Legacy PXE OpROM. Set this value to Do not launch / Legacy only. Launch Storage OpROM policy This option controls the execution of UEFI and Legacy Storage OpROM. Set this value to Do not launch / UEFI only / Legacy only. Launch Video OpROM policy This option controls the execution of UEFI and Legacy Video OpROM. Set this value to Do not launch / UEFI only / Legacy only.
6.7 Save & Exit Menu Select the Exit tab from the setup screen to enter the Exit BIOS Setup screen. You can display an Exit BIOS Setup option by highlighting it using the < Arrow > keys. The Exit BIOS Setup screen is shown below. Save Changes and Reset Reset the system after saving the changes. Discard Changes and Reset Reset system setup without saving any changes. Save Changes Save changes done so far to any of the setup options.
Discard Changes Discard Changes done so far to any of the setup options. Restore Defaults Restore/Load Defaults values for all the setup options. Save as User Defaults Save the changes done so far as user defaults. Restore User Defaults Restore the user defaults to all the setup options.
6.8 Server Mgmt Setup Screen You can use this screen to specify options for the Server Management settings. Use the up and down keys to select an item. Use <+> and <-> keys to change the value of the selected option. The settings are described in the following pages. The screen is shown as below. BMC Support It is for enabling or disabling the interface to communicate with BMC. FRB-2 Timer timeout It can select the value between 1 to 4 min for FRB-2 timer expiration value.
7 Serial Over LAN Serial Over LAN (SOL) is a remote management feature that allows the IPMC (Smart Fusion A2F500) to redirect the serial console from the blade via an IPMI session over the network with RMCP+ protocol. The aTCA-9300 supports SOL on the Base Interface which is powered by the Intel I210 Ethernet Controller.
Build the source code and install IPMItool: make make install Now your remote client is ready to connect to the target the aTCA-9300. Note: The install must be run with root permissions to overlay the existing IPMItool utility in /usr/local/bin. 7.3 Configure The Target aTCA-9300 7.3.1 BIOS Configuration You can refer to section 6.3.8/6.3.9 to enable Serial Port Console Redirection on COM2 Note: The aTCA-9300 supports SOL on COM2 only 7.3.
7.3.3 Linux System Setting Linux needs to be told to listen for logins on the serial port. This is done by adding the following line to /etc/inittab. Add the following line to the init configuration file /etc/inittab. s1:12345:respawn:/sbin/agetty –L ttyS1 115200 vt100 Now the target aTCA-9300 is ready for SOL connection. 7.
The default values of the aTCA-9300 SOL parameters are listed in the table below Parameter Channel 5 IP Address User ID User Name Password Default Value 172.17.172.134 2 adlinkuser adlinkuser Below are 2 samples to establish the SOL session via channel 5 with default user name and password: Sample: Establish a non-encrypted RMCP+ SOL session ./ipmitool -I lanplus -H 172.17.172.134 -C 0 -U "adlinkuser" -P "adlinkuser" sol activate Establish an encrypted RMCP+ SOL session ./ipmitool -I lanplus -H 172.17.
8 Drivers The drivers for aTCA-9300 are available on the ADLINK website. Please visit the aTCA-9300 product web site for more details: http://www.adlinktech.com/PD/web/PD_detail.php?cKind=&pid=1111 We recommend using all the drivers provided on the ADLINK website to ensure driver compatibility. Contact ADLINK to get support for other operating system..
Safety Instructions 1. Please read these safety instructions carefully. 2. Please keep this User‘s Manual for later reference. 3. One AC Inlets provided and service as Disconnect Devices, disconnect the equipment from both AC outlets use these AC Inlets before servicing or clearing. Use moisture sheet or cloth for cleaning. 4. For pluggable equipment, that the socket-outlet shall be installed near the equipment and shall be easily accessible. 5. Please keep this equipment from humidity. 6.
Getting Service Contact us should you require any service or assistance. ADLINK Technology, Inc. Address: 9F, No.166 Jian Yi Road, Zhonghe District New Taipei City 235, Taiwan 新北市中和區建一路 166 號 9 樓 Tel: +886-2-8226-5877 Fax: +886-2-8226-5717 Email: service@adlinktech.com Ampro ADLINK Technology, Inc. Address: 5215 Hellyer Avenue, #110, San Jose, CA 95138, USA Tel: +1-408-360-0200 Toll Free: +1-800-966-5200 (USA only) Fax: +1-408-360-0222 Email: info@adlinktech.com ADLINK Technology (China) Co., Ltd.
ADLINK Technology, Inc. (French Liaison Office) Address: 15 rue Emile Baudot, 91300 Massy CEDEX, France Tel: +33 (0) 1 60 12 35 66 Fax: +33 (0) 1 60 12 35 66 Email: france@adlinktech.com ADLINK Technology Japan Corporation Address: 〒101-0045 東京都千代田区神田鍛冶町 3-7-4 神田 374 ビル 4F KANDA374 Bldg. 4F, 3-7-4 Kanda Kajicho, Chiyoda-ku, Tokyo 101-0045, Japan Tel: +81-3-4455-3722 Fax: +81-3-5209-6013 Email: japan@adlinktech.com ADLINK Technology, Inc.