Embedded Computing for Business-Critical ContinuityTM AXP 1410 Installation and Use P/N: 6806800H70D October 2010
© 2009 Emerson All rights reserved. Trademarks Emerson, Business-Critical Continuity, Emerson Network Power and the Emerson Network Power logo are trademarks and service marks of Emerson Electric Co. © 2009 Emerson Electric Co. All other product or service names are the property of their respective owners. Intel® is a trademark or registered trademark of Intel Corporation or its subsidiaries in the United States and other countries.
Contents About this Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 1 System Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 1.1 1.2 1.3 1.4 2 Site Preparation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents Contents 3.3 3.4 3.5 4 FRU Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 4.1 4.2 4.3 4.4 4.5 5 Installing and Removing Node Blades and RTMs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 Installing and Removing the Shelf Manager Board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 4.2.1 Installing the Board. . . . .
Contents 5.3 5.4 5.5 5.6 5.7 5.8 5.2.3.1 Setting the Shelf Geographical Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 5.2.3.2 Shelf Manager Replacement Scenarios . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 5.2.4 IP Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 5.2.4.1 Out-of-Band Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents Contents 6 Supported IPMI Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 6.1 6.2 6.3 7 FRU Information and Sensor Data Records . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123 7.1 7.2 7.3 6 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents 8 Shelf Management Alarm Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 A Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents Contents Safety Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193 Sicherheitshinweise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 205 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables Table 1-1 Table 1-2 Table 2-1 Table 2-2 Table 2-3 Table 5-1 Table 5-2 Table 5-3 Table 5-4 Table 5-5 Table 5-6 Table 6-1 Table 6-2 Table 6-3 Table 6-4 Table 6-5 Table 7-1 Table 7-2 Table 7-3 Table 7-4 Table 7-5 Table 7-6 Table 7-7 Table 7-8 Table 7-9 Table 7-10 Table 7-11 Table 7-12 Table 7-13 Table 7-14 Table 7-15 Table 7-16 Table 7-17 Table 7-18 Table 7-19 Table 7-20 Standard Compliances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables Table 7-21 Table 7-22 Table 7-23 Table 7-24 Table 7-25 Table 7-26 Table 7-27 Table 7-28 Table 7-29 Table 7-30 Table 7-31 Table 7-32 Table 7-33 Table 7-34 Table 7-35 Table 7-36 Table 7-37 Table 7-38 Table 7-39 Table 7-40 Table 7-41 Table 7-42 Table 7-43 Table 7-44 Table 7-45 Table 7-46 Table 7-47 Table 7-48 Table 7-49 Table 7-50 Table 7-51 Table 7-52 Table 7-53 Table 7-54 Table 7-55 Table 8-1 10 Sensor No. 16 Fan 3 Outlet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables Table 8-2 Table 8-3 Table 8-4 Table 8-5 Table 8-6 Table 8-7 Table 8-8 Table A-1 Table A-2 Alarm Display Panel (ADP) Serial Port Connector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177 SAM LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178 Hot Swap LED States . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
List of Tables 12 AXP 1410 Installation and Use (6806800H70D)
List of Figures Figure 1-1 Figure 1-2 Figure 1-3 Figure 1-4 Figure 1-5 Figure 1-6 Figure 1-7 Figure 2-1 Figure 2-2 Figure 3-1 Figure 3-2 Figure 3-3 Figure 4-1 Figure 4-2 Figure 4-3 Figure 4-4 Figure 5-1 Figure 5-2 Figure 5-3 Figure 5-4 Figure 5-5 Figure 5-6 Figure 5-7 Figure 5-8 Figure 5-9 Figure 8-1 Figure 8-2 Figure 8-3 Figure 8-4 System Front View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 System Rear View . . . . . . . . . . . . . . .
List of Figures 14 AXP 1410 Installation and Use (6806800H70D)
About this Manual Overview of Contents This manual is divided into the following chapters and appendix. z Chapter 1, System Overview, on page 23, provides a brief introduction to the AXP 1410. z Chapter 2, Site Preparation, on page 35, provides general information such as unpacking the system, requirements, dimensions and weight. z Chapter 3, System Installation, on page 45 describes how to install, power up and power down the system.
About this Manual About this Manual Abbreviations This document uses the following abbreviations: 16 Abbreviation Definition ACO Alarm Cut-Off ADP Alarm Display Panel AMC Alarm Management Controller ANSI American National Standards Institute ARP Address Resolution Protocol AWG American Wire Gauge BBS Basic Blade Services CISPR Comité Internationale Spécial des Perturbations Radioelectrotechnique CLI Command Line Interface CO Central Office CSA Canadian Standards Association DHCP
About this Manual Abbreviation Definition FTM Fan Tray Module FUMI Firmware Update Management Instrument GA General Availability GPIO General Purpose Input/Output GND Ground HPI Hardware Platform Interface HRI Hardware Redundancy Interface 2 I C Inter-integrated Circuit I/O Input/Output ID Identifier IEC International Electrotechnical Commission IEEE Institute of Electrical and Electronics Engineers IP Internet Protocol IPM Intelligent Platform Management IPMB Intelligent Pl
About this Manual About this Manual 18 Abbreviation Definition PN Part Number RFI Radio Frequency Interference RFS Root File System RMCP Remote Management Control Protocol ROM Read Only Memory RTM Rear Transition Module RoHS Directive on the restriction of the use of certain hazardous substances in electrical and electronic equipment S/N Serial Number SA Shelf Address SAM Shelf Management Alarm Module SDR Sensor Data Record SELV Safety Extra Low Voltage SGA Shelf Geographical Ad
About this Manual Conventions The following table describes the conventions used throughout this manual.
About this Manual About this Manual Notation Description Indicates a hazardous situation which, if not avoided, could result in death or serious injury Indicates a hazardous situation which, if not avoided, may result in minor or moderate injury Indicates a property damage message No danger encountered. Pay attention to important information Summary of Changes This manual has been revised and replaces all prior editions.
About this Manual Comments and Suggestions We welcome and appreciate your comments on our documentation. We want to know what you think about our manuals and how we can make them better. Mail comments to us by filling out the following online form: http://www.emersonnetworkpowerembeddedcomputing.com/ > Contact Us > Online Form In "Area of Interest" select "Technical Documentation". Be sure to include the title, part number, and revision of the manual and tell us how you used it.
About this Manual About this Manual 22 AXP 1410 Installation and Use (6806800H70D)
Chapter 1 System Overview 1.1 Description The AXP 1410 system is a high availability AdvancedTCA (Advanced Telecom Computing Architecture) system. The PICMG 3.X AdvancedTCA Specifications define components for highperformance services solutions. It is an architecture for highly-available and scalable highspeed interconnect technologies. A high-availability system consists of software and redundant hardware to ensure five-nines (99,999%) uptime. This means that a system is unavailable for no more than 5.
System Overview z Air filter z ESD wrist strap sockets and grounding studs Figure 1-1 System Front View Alarm Display Panel ACT A COM A COM B ACT B PWR MIN MAJ CRT ACO ACT A COM A COM B ACT B PWR MIN MAJ CRT ACO Cable Management Tray FanTray 24 AXP 1410 Installation and Use (6806800H70D)
System Overview Figure 1-2 System Rear View AXP 1410 Installation and Use (6806800H70D) 25
System Overview 1.1.1 Shelf The AXP 1410 shelf consists of a formed 13U sheet metal card cage with structure and support for the backplane, PEMs, FTMs, SAMs, and 14 card slots. Figure 1-1 on page 24 provides a front view of the shelf, Figure 1-2 on page 25 provides a rear view of the shelf. The enclosure mounts in a 19" rack or optional EIA 23" rack. Mounting holes for bezel brackets are provided, which allows the use of power supply or card cage (customer designed) bezels. 1.1.
System Overview For a detailed description refer to the SAM1410 Installation and Use and the System Management Interface Based on HPI-B (Centellis CO 31kX/4100/2000/4410). 1.1.4 Blades The backplane in a AXP 1410 system provides 12 node slots. They are located to the left and to the right of the two hub slots in the middle.
System Overview 1.1.5 Hub Slots The hub slots are configured as option 9 dual star PICMG 3.0 base interface and PICMG 3.1 10Gb fabric interface. 1.1.6 Rear Transition Modules The AdvancedTCA blades can be connected to Rear Transition Modules (RTM) to provide easy access to I/O signals through the zone 3 connector defined by the AdvancedTCA specification.
System Overview 1.1.9 Fan Filter The fan filter is installed in the lower fan tray. 1.2 Standard Compliances The product meets the following standards: Table 1-1 Standard Compliances Standard Description PICMG3.0 R2.0, Defines mechanics, board dimensions, power distribution, power and data connectors, and system management. UL 60950-1 Safety Requirements (legal) EN 60950-1 IEC 60950-1 CAN/CSA C22.
System Overview WEEE Compliance 4363 0205 To satisfy the requirements for marking electrical and electronic equipment in accordance with article 11 (2) of Directive 2002/96/EC, Waste from Electrical and Electronic Equipment (WEEE), Emerson includes a crossed-out bin symbol on all standard and noncustom chassis product.
System Overview As of the printing date of this manual, the AXP 1410 Installation and Use supports the system models listed below. Consult your local sales representative for ordering information on spare parts not listed.
System Overview 1.4 Product Identification You can find the system label at the back of the system on the left.
System Overview The following figure shows a sample label. The actual label on your product may vary in content. Figure 1-5 System Label Example TYPE: Centellis 4410 Platform Core MODEL: 44XX-C VOLTAGE: - 40 to - 60 VDC (SELV) - 60 to - 72 VDC (TNV-2) CURRENT: 2 X 50A (Total 100A) MAX 3500 WATTS This device complies with Part 15 of the FCC Rules.
System Overview The label with the serial number is located at the back of the system on the right. Figure 1-6 Serial Number Location Label The following figure shows a sample serial number label.
Chapter 2 Site Preparation 2.1 Overview The following sections help you to prepare system installation: 2.2 Section Gives Information On Site Planning Considerations This section includes information on unpacking and inspecting the system, requirements, technical data, and other information you need to know before you start system installation. Site Planning Checklists This section provides checklists for site preparation.
Site Preparation 3. Check the rails for proper alignment. 4. Check that the air filter is properly installed. 5. Check that the cable connections are secure and properly fitted. 6. Check the EMI gaskets for damage. 7. Check the items listed above for damage and report any damage or differences to the customer service at www.emersonnetworkpower.com/embeddedcomputing. 8. Tighten loose screws before proceeding. 9.
Site Preparation 2.3 Requirements Before and during system installation and operation, you always have to ensure that the requirements listed in the following sections are met. 2.3.1 Environmental Requirements To ensure proper function of the system, make sure that the environment in which the system is to be used fulfills the environmental requirements.
Site Preparation Table 2-1 Environmental Conditions (continued) Feature Shock Operating Half-sine, 11 ms, 30 m/s Non-Operating (packed state) 2 Blade level packaging Half-sine, 6 ms at 180 m/s2 Vibration (tested in target platform) 0.1g from 5 Hz to 100 Hz and back to 5 Hz at a rate of 0.1 octave/minute Free fall - 5-20 Hz at 0.01 g2/Hz 20-200 Hz at -3.0 dB/octave Random 5-20 Hz at 1m2/s3 Random 20-200 Hz at -3 dB/octave 300mm (11.
Site Preparation 2.3.2 Power Requirements Make sure that a suitable -40.0 to -72 VDC power source is within reach of the system. Two power entry modules (PEMs) can be installed in the system. Personal Injury or System Damage The system is supplied by a TNV-2 voltage. This voltage is considered hazardous. Make sure that the external power supply meets the relevant safety standards. Ensure that TNV-2 is separated from dangerous voltages (mains) through double or reinforced insulation.
Site Preparation 2.4 Dimensions and Weight The table below lists the dimensions and weight of the shelf and system components. The maximum weight of the system must not exceed 80 kg. Table 2-3 Dimensions and Weight of System and Components Dimensions 40 Component w x h x d in mm Weight in kg Shelf, including two fan trays, two PEMs, and an air filter 497 x 573 x 544 39.6 PEM 164 x 73 x 155 1.5 Upper fan tray module 491 x 87 x 227 4 Lower fan tray module 491 x 119 x 331 6.
Site Preparation 2.5 Mounting Options You can simply operate the system on your desk or you can install it in a EIA 23" rack, or mount it in a 600mmx600mm ETSI frame relay.. Personal Injury or System Damage The system is heavy and if you carry it on your own you can hurt your back. To prevent injury, keep your back straight and have two people lift the system or use additional lifting equipment. Personal or System Damage Unstable system installation in a rack can cause the rack to topple over.
Site Preparation You have to keep the following conditions when installing the system into a 600 mm (23.62 inch) deep rack. The physical dimensions in the figure below are in millimeters. Figure 2-1 Rack Mounting Dimensions Cabinet Door Air Outlet 3.5mm to Door at Back Side of Rear Door 25mm Thick Door, 2X 13U Shelf Side View 3mm to Door Air Inlet 75mm 42mm 550mm Inside, Door to Door 600mm Deep Cabinet 2.
Site Preparation Fan trays are mounted in the shelf top. The figure below shows the general airflow for the system. Figure 2-2 Shelf Airflow Upper FTM Chassis Exhaust Air Flow Outlet Plenum RTM Chassis Front Chassis Rear Room Ambient Air Flow PEM Exhaust Lower Front Air Intake Lower FTMs The Cooling subsystem is compliant to CP-TA B.4. The cooling system provides for greater than 40 CFM for the front blade and 5.0 CFM for the RTM.
Site Preparation 2.7 Acoustic Noise Control The system can generate a lot of acoustic noise. This system has a built-in noise control due to the fan speed control. If the system is installed in an environment where the noise may be harmful to personnel being exposed to the noise during extended time periods, additional protective measures should be considered.
Chapter 3 System Installation 3.1 Overview The following sections help you to start up and maintain the system: 3.2 Step Description Before installation This section provides information about the requirements, unpacking and inspecting the delivery and the type label location. Installation This section provides information about how to mount the system into a rack and how to ground the system. Removal This section provides information on how to power down the system and remove it from a rack.
System Installation 3.2.2 Tools You will Need Before you start the installation, make sure that you have all the necessary equipment at hand. Usage Equipment General Philipps head screwdriver #1 Torque Wrenches (7, 8, 10 mm or 0.28, 0.31, 0.
System Installation Observe the following general safety notes when installing your system: z Restricted access area - The system is only to be installed in a restricted access area. z Installation codes - This unit must be installed in accordance with the National Electrical Code, Articles 110.16, 110.17, and 110.18 and the Canadian Electrical Code, Section 12.
System Installation 3.3.1 Installing the System in a Rack The following procedure describes how to install the system in a rack. Use power input cables with a cross section (minimum) of 21mm2, AWG 4. Personal or System Damage The system is heavy and if you carry it on your own you can hurt your back. To prevent injury, keep your back straight and have two people to lift the system or use additional lifting equipment.
System Installation System Damage During the course of handling, shipping, and assembly, pins, shrouds and mounting screws, fans and other items can become loose or damaged. Do not operate a damaged shelf, this can cause damage to devices that interfere with it. Grounding To ensure the system is properly grounded, each of the system's parts contact the EMI gasket. The system contains gaskets at the shelf and module level. The shelf is also fitted with ESD contacts.
System Installation You have to keep the following conditions when installing the system into an at least 600 mm (23.62 inch) deep rack. The physical dimensions in the figure below are in millimeters. Please ensure that 60% of the rack's rear is open.
System Installation 3. Be sure to mount the shelf with metal screws or bolts that give a good electrical connection between the screws or bolts and the mounting surface. 4. Tighten all screws using a torque setting of 35.5 to 38.5 inch-pounds. Failure to observe proper grounding practices may cause a variety of noise, electrostatic discharge, and RFI (Radio Frequency Interference) problems.
System Installation 3.3.2.1 DC Power Cable Power is introduced to the shelf via redundant DC PEMs. The recommended power cable is an 4 AWG gauge that meets the specifications for this shelf. There are four lugs for each PEM. Two are straight and the other two are custom offset lugs. The end that connects to the external DC power source should be equipped with an 8mm terminal. Always check with your local building authorities for wire sizing requirements for your environment.
System Installation Figure 3-2 DC Power Connection Detail ON F OF N C RT VD C ON -48 VD F OF N C -48 RT VD C -48 VD AXP 1410 Installation and Use (6806800H70D) 53
System Installation 3.3.2.2 Power Cable Termination Custom lugs are used with large gauge wires for up to 80 AMPs DC (4 AWG) when connecting to the PEM. These are shipped with the product.The lugs are angled to allow the cables to be dressed below the cable management tray, thus protecting the circuit breakers from accidental tripping. Terminating this lug is identical to terminating standard lugs. To minimize shorting of the terminals, the lugs must be insulated according to the following illustration.
System Installation Procedure Have the following tools on hand before you begin these steps: standard Phillips screwdriver, nut driver, torque wrench, multimeter, and lug kit. 1. Locate the target power input cable’s terminals at the branch circuit or power distribution unit. Open the external circuit breakers that provide DC feed power to the PEM. 2. Lock and tagout the circuit breakers on the branch circuit or power distribution unit.
System Installation 9. Break the tagout or lockout seals on the branch circuit or power distribution unit. 10.Apply power by closing the branch circuit or power distribution unit. The OOS indicator LED will glow solid red and the other LEDs will go dark. The OOS will not go dark and the IS indicator LED will not illuminate until the external power circuit breakers are closed. 11.Verify that all FRU LEDs illuminate and the PEM’s IS LED is green, and the OOS LED is dark. 3.3.
System Installation The AXP 1410 shelf was tested in the default configuration of logic ground and shelf ground connected and does not connect -48VDC Return with Shelf Ground. The system has been tested in the default configuration and complies with safety and regulatory standards.
System Installation 3.4 Powering Down the System Procedure Follow these steps to shut down your AXP 1410. 1. Shut down all software operations and the operating system. For shelves with independently running segments, each segment must be shut down. 2. Turn each circuit breaker on the front of PEM A and PEM B to the OFF position. Step 2 removes the input power from the slots in the AXP 1410 shelf only. It does not remove power to the PEMs. To remove power to these components, refer to the next step. 3.
System Installation 1. Turn each circuit breaker on the front of PEM A and PEM B to the OFF position. 2. Disable the DC power at the external sources (branch circuit or power distribution unit) for PEM A and PEM B).
System Installation 60 AXP 1410 Installation and Use (6806800H70D)
Chapter 4 FRU Installation 4.1 Installing and Removing Node Blades and RTMs Refer to the respective blade or RTM documentation for installation and removal procedures.
FRU Installation 4.2 Installing and Removing the Shelf Manager Board The following figure shows the SAM1410 shelf manager board. Figure 4-1 SAM1410 Overview Damage of Circuits Electrostatic discharge and incorrect blade installation and removal can damage circuits or shorten their life. Before touching the blade or electronic components, make sure that you are working in an ESD-safe environment.
FRU Installation If the shelf contains only one shelf manager board you have to power down the shelf before exchanging the board. 4.2.1 Installing the Board To install the board into an AdvancedTCA shelf, proceed as follows. Installation Procedure The following procedure describes the installation of the board. It assumes that your system is powered. If your system is unpowered, you can disregard the blue LED and thus skip the respective step. In this case it is a purely mechanical installation. 1.
FRU Installation 4.2.2 Removing the Board This section describes how to remove the board from an AdvancedTCA system. Removal Procedure The following procedure describes how to remove the board from a system. It assumes that the system is powered. If the system is unpowered, you can disregards the blue LED and thus skip the respective step. In that case it is a purely mechanical procedure. 1. Put on an ESD wrist strap. 2. Connect the strap to the shelf by attaching the front or rear ESD jack. 3.
FRU Installation 4.3 Replacing Power Entry Modules The AXP 1410 supports two Power Entry Modules (PEMs). Since the shelf is equipped with a redundant power distribution system, the removal of a single PEM does not interrupt system operation. PEMs are accessible from the rear of the shelf. Each PEM has EMI gaskets on all sides of the module that provide EMI shielding. The following instructions describe how to replace a power entry module.
FRU Installation Replacing one PEM is done while the other PEM is in operation. Having the PEM located in the shelf is critical to maintaining proper airflow and cooling of the shelf. Steps in which a PEM is removed from a slot and reinserted should be completed within 3 minutes to maintain the shelf within safe operating temperatures. Read all cautions and warnings, and ensure the equipment is properly grounded by reviewing the procedure in Grounding the System on page 56, and follow these steps.
FRU Installation 3. Using the appropriate tool, loosen the chassis retention screws on each side of the PEM. 4. Open the ejector latches. This will signal the switch to deactivate the hot swap signal. Watch for the Blue LED to go solid and steady, signalling that it is ready to remove. 5. Open the ejector handles completely. You will feel the PEM disconnect from the backplane. 6. Pull the module straight out from the rail guides, about 3 inches. 7.
FRU Installation 10.Remove the DC power cable from the dual lug bolts on the PEM you are replacing, being careful to place the two cables so they cannot short to each other or to other conductors. 11.Loosen the standoff/lockout screw extensions and remove the PEM from the slot by pulling straight out of the rail guides. 12.Remove the standoff/lockout screw extensions and put them aside to use when installing the new PEM. 4.3.
FRU Installation Installation Procedure To install a PEM, proceed as follows: 1. Screw a standoff/lockout screw extension onto the retaining screws located on each side of the replacement PEM. 2. Align the back end of the replacement PEM with the rail guides in the empty PEM slot and slide the PEM into the slot. System Damage Insufficient cooling can damage the system. Lock the replacement PEM into the slot within 3 minutes to maintain the proper cooling properties of the shelf.
FRU Installation 3. Align the threaded end of the standoff/lockout screw extension with the screw holes on each side of the shelf and securely tighten to lock the PEM approximately 2 inches out of the shelf. PEM ES D BO PO ND IN T M PE O Standoff O S IS H /S 25 C B5 Standoff Retaining Screw Retaining Screw 4435 070 4434 0706 Lock the replacement PEM into the slot within 3 minutes to maintain the proper cooling properties of the shelf. 4.
FRU Installation 7. Attach the DC power cable to the dual lug bolts on the PEM (power -48VDC input and Return) and tighten the nuts with a recommended torque setting of 35.5 to 38.5 inch-pounds. Make sure all DC leads are fastened securely. 8. Replace the plastic cover over the terminal blocks. 9. Remove the standoff/lockout screw extensions. 10.Gently press the PEM into the slot until the ejector handle engages and then press the ejector handle to the closed position to seat the PEM into the backplane.
FRU Installation 4.4 Installing Fan Tray Modules To prevent system damage, the operator must replace the fans within the recommended service interval shown in the following table to prevent a decline in shelf operability. Make sure the replacement FTM is available for exchange and ready to install.
FRU Installation 4.4.1 Removing the Upper FTM Removal Procedure Follow these steps and refer to the figures to remove the upper fan tray module from the shelf. 1. Loosen the retention screw to the chassis Figure 4-2 Upper Rear FTM Ejector Handles and LEDs 2. Pull the ejector handle outward to a slightly open position to disengage the hot swap switch. Watch for the blue LED to blink. When the blinking stops and the LED remains a solid blue, the FTM is ready to be removed. 3.
FRU Installation 4.4.2 Installing the Upper FTM Installation Procedure Have the correct FTM available and follow these steps to install the upper fan tray module. 1. While supporting the FTM, align the FTM carefully into the fan slot in the shelf and slowly slide the FTM until the ejector handles engage; fully close the handles. The FTM is connected when the assembly is firmly seated in the upper backplane connector and the hot swap handle moves to the closed position. 2.
FRU Installation 3. Open the ejector handle to a full open position. 4. Using the ejector handle on the front of the FTM, slowly pull the FTM out of the shelf, while supporting the bottom of the module with the palm of your hand. The module is heavy; hold it securely. 4.4.4 Installing the Lower FTM Installation Procedure Have the correct FTM available and follow these steps to install the upper fan tray module. 1.
FRU Installation Replacement Procedure To replace the fan filter for a lower FTM, refer to Removing the Lower FTM and follow these steps to replace a fan filter. Please have your replacement fan filter available before starting this procedure. 1. With the FTM removed and placed on a solid surface, position the FTM with the front facing you. 2. Using your fingers, rotate the filter frame away from the housing using the two tabs on the right and left sides of the filter frame. 3.
FRU Installation Figure 4-4 Position of the Fan Filter Velcro 5. Lower the vane assembly and rotate the filter bracket into place. 6. Reinstall the lower FTM using the procedure described in Installing the Lower FTM.
FRU Installation 78 AXP 1410 Installation and Use (6806800H70D)
Chapter 5 Configuring and Operating the System 5.1 Overview The following sections provide information that you need after you have successfully installed the hardware. Section Description Network Management on page 79 This section contains information on VLAN configuration, slot numbering, IPMB and hardware addresses, and IP addresses of SAM1410.
Configuring and Operating the System 5.2.1 Default VLAN Configuration The AXP 1410 system provides four network planes. They are, base network a and b and fabric network a and b. The following figures show the VLAN configuration.
Configuring and Operating the System Figure 5-2 Switch Management Base Interface Bridge Configuration AXP 1410 Installation and Use (6806800H70D) 81
Configuring and Operating the System 5.2.2 Slot Numbers and Slot Addresses The system provides a dual star network topology, that means each AdvancedTCA blade is connected to the SAM1410-1 and to the SAM1410-2 with one base interface channel.
Configuring and Operating the System The physical address describes the physical location of an FRU in the shelf. This location is required when an operator has to handle an FRU, for example, exchange the AdvancedTCA blade #2. The physical address and the physical slot number are identical for AdvancedTCA blades. The physical addresses of other FRUs like PEMs and fans identify the type of the FRU and a particular FRU of that type.
Configuring and Operating the System Table 5-1 Slot Numbering and Slot Addresses (continued) Device# Hardware Address IPMB Address Logical Slot Number Physical Slot Number - 49 92 9 3 - 4A 94 10 12 - 4B 96 11 2 - 4C 98 12 13 - 4D 9A 13 1 - 4E 9C 14 14 5.2.3 Shelf Geographical Address The shelf geographical address (SGA) is used to calculate the shelf manager IP addresses on the out-of-band interface, refer Out-of-Band Interface on page 88.
Configuring and Operating the System Example: Changing the shelf geographical address to 7: # hpishaddr -b "07" 3. Reboot the shelf (switch the power off and on again). The SAM1410 boards will come up with changed IP addresses. 5.2.3.2 Shelf Manager Replacement Scenarios This subsection describes different scenarios of replacing the shelf manager and determining the shelf FRU information.
Configuring and Operating the System 5.2.4 IP Addresses The following subsections describe the IP addresses of the shelf manager. There are no predefined IP addresses for the node blades. The shelf manager has three network interfaces: One on the front panel, one to its own hub and one to the hub of the other SAM1410. The shelf manager sets up these interfaces based on the information found in the shelf manager IP connection record of the shelf FRU information.
Configuring and Operating the System The figure below shows an example of the shelf manager IP addresses with Shelf IP Connectivity Record #2. Orange color shows BASE1 and green shows BASE2. The IP addresses are described in more detail in the subsections that follow. Figure 5-4 IP Addresses eth0: 192.168.0.181 eth0: 192.168.0.9 eth0: 192.168.0.171 eth0: 192.168.0.8 SAM1410-1 MF105-1 Active ShMC SAM1410-2 MF105-2 Ch#2 eth2: 172.18.0.8 Backup ShMC Ch#1 eth1: 172.17.0.9 Ch#1 eth1: 172.17.0.
Configuring and Operating the System Abbreviations used are as follows: 5.2.4.1 Abbreviation Description IP n-th shelf manager IP connection record IP_ m-th octet of the IP address of the n-th shelf manager IP connection record SGA shelf geographical address, i.e.
Configuring and Operating the System Virtual Standby IP Address on Out-of-Band Interface Netmask of IP1 Virtual Standby IP Address Default Value 255.0.0.0 ...181 192.168.0.181 255.255.0.0 255.255.255.0 To avoid an address conflict between out-of-band and backplane interfaces, 100 is added to the third octet of all out-of-band interface IP addresses, if any of them would be equal to one of the backplane addresses otherwise.
Configuring and Operating the System Example #1: Print current IP address settings and change out-of-band address: *Print current IP address settings shm9s8:~ # hpiship 29 {ADVANCEDTCA_CHASSIS,9} Shelf Resource 4097 Shelf Manager IP Address 0 IP : 192.168.9.171 Gateway: 192.168.9.0 Submask: 255.255.255.0 8449 Shelf Manager IP Address 1 IP : 172.16.9.171 Gateway: 172.16.0.170 Submask: 255.255.0.0 *Change out-of-band-address: shm9s8:~ # hpiship -n 4097 -i 200.200.0.
Configuring and Operating the System *change Shelf Address and Shelf Entity Path setting: shm9s8:~ # hpishaddr -b "0700000000000000000000000000000000000000" 07 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 -shelf address: 7 shelf entity-path: {ADVANCEDTCA_CHASSIS,7} 5.2.4.2 Backplane Interfaces The IP address of the shelf manager backplane interfaces are created from the information in the second IP connection record.
Configuring and Operating the System Physical IP Address on Backplane Interface 2 Netmask of IP2 Physical IP Address Default Value 255.0.0.0 ... 255.255.0.0 ... 172.18.0.8, 172.18.0.9 255.255.255.0 ... The following virtual IP addresses are assigned to shelf manager slot 8 / backplane interface 1 and shelf manager slot 9 / backplane interface 2.
Configuring and Operating the System Refer to Setting the Shelf Geographical Address on page 84 to see how you can change the shelf address. 1. Change the first two octets of the IP address using the hpiship tool located on the shelf manager. Use the option -h for help. 2. Change the third octet of the IP address by changing the shelf address. If the third octet of the IP address is changed using hpiship, it is temporary and will be changed automatically on the next reboot to match the shelf address. 3.
Configuring and Operating the System shm9s8:~ # hpiship -n 8449 -i 200.200.0.0 5.2.4.3 Configuration File By default, the shelf manager automatically reads the shelf IP connectivity record and calculates IP addresses based on the described scheme. Alternatively the shelf configuration for SGA and IP may be configured using the network configuration file. The network configuration of the SAM1410 can be modified by settings available in /etc/network.conf. The /etc/network.
Configuring and Operating the System auto - Automatic configuration of the interface dhcp - Use DHCP to obtain an IP address static - Use OOB_IPADDR and OOB_NETMASK to configure the interface OOB_MODE=auto — Static Configuration of the Out-of-band Network Interface If using the static parameter to configure the out-of-band interface, specify the desired IP address and netmask using the following variables: OOB_IPADDR= OOB_NETMASK= z Backplane Network Configuration The backplane ethernet interfaces can b
Configuring and Operating the System The backplane virtual application interface can be configured automatically using the Shelf Address (default) or by specifying a static IP address. Use the following parameters to the BP_APPL_MODE variable to define the configurations for backplane virtual interface.
Configuring and Operating the System BP_B_DHCP_SERVER= z Backplane Bonding Mode The backplane interfaces can be a part of a bonding interface if the BP_BOND_MODE variable is set to either dhcp or static. The bonding interface is named bond0. Use the following parameters to the BP_BOND_MODE variable to define the configuration for backplane bonding mode.
Configuring and Operating the System GATEWAY= z Heartbeat Addresses The ppp0 and ppp1 serial links are used for the heartbeat interfaces between Shelf Managers. The addresses can be modified by changing the values associated with HB1_BASE and HB2_BASE. HB1_BASE=192.168.101.0 HB2_BASE=192.168.102.0 The last octet is obtained from the SLOT value, so only the first three octets are configurable. z Switch Slot IP Addresses The C2000 shelf does not use the SWITCH_SLOT_IPADDR variable. 5.2.
Configuring and Operating the System 5.3 Accessing System Components All system components are delivered with the software installed. If you want to upgrade or need to reinstall the software on these system components, you can use the interfaces of the SAM1410 to access the consoles and command line interfaces of the different system components. The SAM1410 can be reached through telnet and through SSH.
Configuring and Operating the System Access via base interface channel 2: SAM1410 IP Address Left SAM1410 172.18..8 Right SAM1410 172.18..9 Active SAM1410 172.16..171 Standby SAM1410 172.16..181 For further information on the IP addresses of the SAM1410, refer IP Addresses on page 86. 5.4 Software System components are delivered with the software installed.
Configuring and Operating the System 5.4.2 Upgrade The procedures and tools for software upgrades differ depending on what component needs to be upgraded. Available tools for firmware upgrades are: z FUMI: part of HPI-B included in BBS z fw_tool: integrated in the SAM1410 root file system z swupgrade: integrated in the SAM1410 root file system The following table shows which tools you can use and where you can find a description of how to do it. Emerson recommends to always use FUMI if available.
Configuring and Operating the System Table 5-3 Available Software Upgrade Tools (continued) Procedure Tool Document/Chapter Fan tray firmware upgrade FUMI System Management Interface Based on HPI-B (Centellis 31kX/4100/2000/4410) User’s Guide Chapter: Using the Firmware Update Management Instrument PEM IPMI firmware upgrade fw_tool SAM1410 Installation and Use Chapter: Software Upgrade FUMI System Management Interface Based on HPI-B (Centellis 31kX /4100/2000/4410) User’s Guide Chapter: Using the
Configuring and Operating the System Power conversion for the SAMs and PEMs consists of two 66 watt, +48VDC to +12VDC converters which distribute dual power busses of +12VDC to separate parts of the system. The +12VDC outputs are provided on the backplane connector to the rest of the shelf. Power is redundant via the secondary PEM. Removing power to these components cannot be accomplished by turning the PEM's circuit breakers to the OFF position.
Configuring and Operating the System voltage sensors to detect backplane voltages, current sensors to detect current to the backplane, and on-board circuitry to detect failures on the PEM. The PEMs are managed by the Sentry Shelf Management software. Refer to Chapter 7, FRU Information and Sensor Data Records, on page 123.
Configuring and Operating the System The FTMs have variable speed fan control, which is dependent on the temperature readings in the shelf. Airflow rates can vary depending on the fan speed and payload. Fan speed levels are controlled from the SAM via the IPM shelf management software. The fan speed levels change automatically based on temperature sensors. If any FRU exceeds the upper non-recoverable threshold, it is powered down.
Configuring and Operating the System 5.6.3 IPMC Circuitry Preprogrammed FRU and SDR information reside on the FTMs and is accessible from the SAM via the I2C bus. FRU information can be found in the Chapter 7, FRU Information and Sensor Data Records, on page 123. 5.7 Redundancy The following sections outline the interaction between redundant shelf managers and redundant hub blades. This interaction is not described within the AdvancedTCA Specification PICMG 3.0.
Configuring and Operating the System 5.7.1.1 Heartbeat The shelf managers use two private interfaces to heartbeat each other. The heartbeat interval is configured to 400 ms and the partner is considered inactive when no responses are received after five retries within 2 seconds. 5.7.1.
Configuring and Operating the System 5.7.2 System Start-Up Behavior and Dependencies Once the system is powered on, the shelf manager and the hub blade need to connect and communicate which blades are active. The following section describes the start-up of a shelf manager, a hub blade and a system manager. A system manager is not part of a AXP 1410 system and has to be developed by the user. 5.7.2.
Configuring and Operating the System 5.7.2.2 Hub Blade Hub blades are associated with a shelf manager. Hub 1 with SAM-A and hub 2 with SAM-B. 5.7.2.3 System Manager If the system manager accesses the active shelf manager via the backplane Ethernet interfaces it may use virtual IP Plane and active virtual IP address 192.168.20.171 of the shelf manager.
Configuring and Operating the System The figure below assumes that the shelf address is 0. Green color shows BASE1 and orange shows BASE2. The arrows show the packet routing. Figure 5-5 System Start-Up eth0: 192.168.0.171 eth0: 192.168.0.8 Active Shelf Manager eth0: 192.168.0.181 eth0: 192.168.0.9 Active ShMC Backup ShMC ShM Board #1 ShM Board #2 Ch#2 Ch#1 eth1: 192.168.21.28 eth1: 192.168.20.171 192.168.21.1 eth2: 192.168.22.28 Ch#2 Ch#1 eth1: 192.168.21.29 eth2: 192.168.22.29 eth2: 192.168.20.
Configuring and Operating the System 5.7.3 Redundancy Operations This section describes what happens during shelf manager switchover, takeover, failover, and when a shelf manager is inserted or extracted. 5.7.3.1 Shelf Manager Switchover During a switchover, the active and the standby shelf manager change their roles. The system manager initiates and controls this process on the active shelf manager. A switchover is, for example, necessary when the active shelf manager needs to be extracted.
Configuring and Operating the System The figure below assumes that the shelf address is 0. Green color shows BASE1 and orange shows BASE2. The arrows show the packet routing. Figure 5-6 Shelf Manager Switchover eth0: 192.168.0.181 eth0: 192.168.0.8 eth0: 192.168.0.171 eth0: 192.168.0.9 Backup ShMC Active ShMC ShM Board #1 ShM Board #2 Ch#2 Ch#1 eth1: 192.168.22.28 eth1: 192.168.20.181 192.168.22.1 eth2: 192.168.22.28 Ch#1 eth1: 192.168.21.
Configuring and Operating the System 4. If necessary, moves its own active virtual IP address to another interface 5. Reestablishes the HPI session to the active shelf manager with saHpiSessionOpen 6. Waits in saHpiResourcesDiscover until the active shelf manager discovers all resources 5.7.3.2 Shelf Manager Takeover Takeover is a process to switch the active and the standby roles of the shelf manager boards. The system manager initiates and controls this process on the standby shelf manager.
Configuring and Operating the System The system manager performs the following steps: 1. Closes the HPI session 2. Moves its own active virtual IP address to the other interface 3. Reestablishes the HPI session to the active shelf manager with saHpiSessionOpen 4. Waits in saHpiResourcesDiscover until the active shelf manager discovers all resources.
Configuring and Operating the System The figure below assumes that the shelf address is 0. Green color shows BASE1 and orange shows BASE2. The arrows show the packet routing. Figure 5-7 Link Failover after Active Shelf Manager Failover eth0: 192.168.0.181 eth0: 192.168.0.8 eth0: 192.168.0.171 eth0: 192.168.0.9 Backup ShMC Active ShMC ShM Board #1 ShM Board #2 Ch#2 Ch#1 eth1: 192.168.22.28 eth1: 192.168.20.181 192.168.22.1 eth2: 192.168.22.28 Ch#1 eth1: 192.168.21.
Configuring and Operating the System The active shelf manager synchronizes the shelf FRU information with the shelf FRU information of the newly inserted shelf manager board. The active shelf manager sends HPI events from the redundancy sensor (redundancy regains). The system manager detects a shelf manager board insertion while receiving hot swap events and later HPI redundancy event sensor. The system manager reads the HPI redundancy sensor to retrieve the shelf manager redundancy status. 5.7.3.
Configuring and Operating the System 5.8.1 Power-On After Blade Insertion The default for each slot is that when a blade is inserted it is automatically switched on by the shelf manager. To change this, you need to change the shelf FRU information. The default for the Auto Insert Timer in HPI is 60 s.
Configuring and Operating the System 5.8.2 Power-Down Before Blade Extraction When a blade is supposed to be extracted, it needs to be powered down first. As soon as the blade has reached M6, an IPMI command is sent that tells the payload that the blade will be powered down. The payload then has time to carry out all necessary steps. The blade is powered down afterwards. It may take a long time before the payload has finished carrying out all necessary steps and the blade can be powered down.
Chapter 6 Supported IPMI Commands 6.1 Introduction This chapter describes the different commands supported by the AXP 1410 series platforms. Command categories are as follows: 6.2 z Standard IPMI Commands z PICMG 3.0 Commands Standard IPMI Commands The IPMC is fully compliant to the Intelligent Platform Management Interface v.1.5. This section provides information on which IPMI commands are supported on PEMs and fans. Table entries marked with an “X” indicate which FRU supports a listed command.
Supported IPMI Commands 6.2.3 Sensor Device Commands The IPMC supports the following sensor device commands. Table 6-3 Supported Sensor Device Commands 6.2.
Supported IPMI Commands 6.3 PICMG 3.0 Commands The Emerson IPMC is a fully compliant AdvancedTCA Intelligent Platform Management Controller. For example, it supports all required and mandatory AdvancedTCA commands as defined in the PICMG 3.0 specification. Table 6-5 Supported PICMG 3.
Supported IPMI Commands 122 AXP 1410 Installation and Use (6806800H70D)
Chapter 7 FRU Information and Sensor Data Records 7.1 Introduction This chapter introduces FRU information, e-keying, sensor overviews, and power configuration data for PEMs and upper and lower fan tray module of the AXP 1410 system. Information in this chapter includes: 7.2 z Fan Tray Module Sensor Data Records z Power Entry Module Sensor Data Records Fan Tray Module Sensor Data Records This section describes in detail all available IPMI sensors of the Fan Tray Module. 7.2.
FRU Information and Sensor Data Records Table 7-1 IPMI Sensors on the Fan Tray Module (continued) 124 Sensor No.
FRU Information and Sensor Data Records Table 7-1 IPMI Sensors on the Fan Tray Module (continued) 7.2.2 Sensor No.
FRU Information and Sensor Data Records Table 7-2 Sensor No.
FRU Information and Sensor Data Records Table 7-3 Sensor No. 4 +12V B_MON (continued) Feature Raw Value/Description Interpreted Value Readable threshold mask, Settable threshold mask (bytes 19, 20) 0x3F3F Upper and Lower Non-Critical, Critical and Non-Recoverable Thresholds are Readable and Settable Reading Type Unsigned Lower Non-Critical, Critical and Non-Recoverable thresholds 0xDB, 0xDA, 0xD9 (11.8260, 11.7720, 11.
FRU Information and Sensor Data Records Table 7-5 Sensor No.
FRU Information and Sensor Data Records Table 7-6 Sensor No. 7 +5V B_MON (continued) Feature Raw Value/Description Entity Instance 0x60 Rearm mode Auto Hysteresis support Readable/Settable Threshold access support Readable/Settable Event message control Entire Sensor only Readable threshold mask, Settable threshold mask (bytes 19, 20) 0x3F3F Reading Type 7.2.2.
FRU Information and Sensor Data Records Table 7-7 Sensor No. 30 FTM Temp 1 (continued) Feature Raw Value/Description Interpreted Value Threshold access support Readable/Settable Event message control Entire Sensor only Readable threshold mask, Settable threshold mask (bytes 19, 20) 0x3838 Critical and Non-Recoverable Thresholds are Readable and Settable Reading Type Critical and Non-Recoverable thresholds Unsigned 0x2D, 0x35, 0x3F (57, 67) Degrees C Table 7-8 Sensor No.
FRU Information and Sensor Data Records Table 7-9 Sensor No.
FRU Information and Sensor Data Records Table 7-10 Sensor No.
FRU Information and Sensor Data Records Table 7-12 Sensor No.
FRU Information and Sensor Data Records Table 7-13 Sensor No.
FRU Information and Sensor Data Records Table 7-14 Sensor No.
FRU Information and Sensor Data Records Table 7-16 Sensor No.
FRU Information and Sensor Data Records Table 7-17 Sensor No.
FRU Information and Sensor Data Records Table 7-18 Sensor No.
FRU Information and Sensor Data Records Table 7-20 Sensor No.
FRU Information and Sensor Data Records Table 7-21 Sensor No.
FRU Information and Sensor Data Records Table 7-22 Sensor No.
FRU Information and Sensor Data Records Table 7-24 Sensor No. 19 Fan 6 Outlet Feature Raw Value/Description Sensor Name Fan 6 Outlet Interpreted Value Device Sensor Type 0x04 Fan Class 0x01 Threshold Sensor Owner LUN 0x00 Entity ID 0x1D Entity Instance 0x63 Rearm mode Auto Hysteresis support Readable/Settable Threshold access support Readable/Settable Event message control Entire Sensor only Readable threshold mask, Settable threshold mask (bytes 19, 20) 0x3F3F Reading Type 7.2.
FRU Information and Sensor Data Records 7.2.3.1 Hot Swap Sensor The following table describes the discrete hot swap sensor available on the FTM. Table 7-25 Sensor No.
FRU Information and Sensor Data Records Table 7-26 Sensor No. 2, IPMB Physical (continued) Feature Raw Value/Description Interpreted Value Sensor Type 0xF1 IPMB Link Sensor Owner LUN 0x00 Entity ID 0x1E Entity Instance 0x60 Rearm Mode Auto Hysteresis support Threshold access support Event Message Control Entire Sensor Only Readable threshold mask, Settable threshold mask (bytes 19, 20) Reading Type 7.2.3.3 According to PICMG 3.
FRU Information and Sensor Data Records Table 7-27 Sensor No. 1 Version change (continued) Feature Raw Value/Description Assertion Event Mask (bytes 15,16) 0x00FF Deassertion Event Mask (bytes 17,18) 0x0000 Discrete Reading Mask (bytes 19, 20) 0x00FF Reading Definition 7.2.3.4 Interpreted Value Supports 2 States According to Pigeon Point OEM-Reserved Sensors The following table describes the OEM-reserved sensors available on the FTM.
FRU Information and Sensor Data Records Table 7-28 Sensor No. 20 FanFault Z1F1 (continued) Feature Raw Value/Description Assertion Event Mask (bytes 15,16) 0x02, 0x00 Deassertion Event Mask (bytes 17,18) 0x02, 0x00 Discrete Reading Mask (bytes 19, 20) 0x03, 0x00 Interpreted Value Supports 2 States Reading Definition Assertion signals a fan controller fault Table 7-29 Sensor No.
FRU Information and Sensor Data Records Table 7-30 Sensor No.
FRU Information and Sensor Data Records Table 7-31 Sensor No. 23 FanFault Z2F1 (continued) Feature Raw Value/Description Assertion Event Mask (bytes 15,16) 0x02, 0x00 Deassertion Event Mask (bytes 17,18) 0x02, 0x00 Discrete Reading Mask (bytes 19, 20) 0x03, 0x00 Interpreted Value Supports 2 States Reading Definition Assertion signals a fan controller fault Table 7-32 Sensor No.
FRU Information and Sensor Data Records Table 7-33 Sensor No.
FRU Information and Sensor Data Records Table 7-34 Sensor No. 26 FuseFail 48VA1 (continued) Feature Raw Value/Description Assertion Event Mask (bytes 15,16) 0x02, 0x00 Deassertion Event Mask (bytes 17,18) 0x02, 0x00 Discrete Reading Mask (bytes 19, 20) 0x03, 0x00 Interpreted Value Supports 2 States Reading Definition Assertion signals a fuse failure Table 7-35 Sensor No.
FRU Information and Sensor Data Records Table 7-36 Sensor No.
FRU Information and Sensor Data Records Table 7-37 Sensor No. 29 FuseFail 48VB2 (continued) Feature Raw Value/Description Assertion Event Mask (bytes 15,16) 0x02, 0x00 Deassertion Event Mask (bytes 17,18) 0x02, 0x00 Discrete Reading Mask (bytes 19, 20) 0x03, 0x00 Supports 2 States Reading Definition 7.3 Interpreted Value Assertion signals a fuse failure Power Entry Module Sensor Data Records This section describes in detail all available IPMI sensors of the Power Entry Module. 7.3.
FRU Information and Sensor Data Records Board Product Name = Centellis 4000 Power Entry Module Board Serial Number = XXXXXXX 7 digit Board S/N) Board Part Number = 0106831D01C FRU Programmer File ID = CENT4000_PEM.inf Product Info Area: Version 7.3.2 = 1 Language Code = 25 Manufacturer Name = Emerson Network Power, Embedded Coputing Product Name = PEM4000 Product Part / Model# = 0106823D01C Product Version = Rev. 1.
FRU Information and Sensor Data Records 7.3.3 Power Configuration The next table describes the power configuration for the PEMs. Table 7-38 Power Configuration for PEMs 7.3.
FRU Information and Sensor Data Records Table 7-39 IPMI Sensors on the PEM (continued) 7.3.5 Sensor No.
FRU Information and Sensor Data Records 7.3.5.1 Voltage Sensors The following sensors measure voltages of the PEM. Table 7-40 Sensor No. 2 +3.3V Feature Raw Value/Description Sensor Name +3.
FRU Information and Sensor Data Records Table 7-41 Sensor No.
FRU Information and Sensor Data Records Table 7-42 Sensor No.
FRU Information and Sensor Data Records Table 7-43 Sensor No. 5 +12V CC (continued) Feature Raw Value/Description Interpreted Value Readable threshold mask, Settable threshold mask (bytes 19, 20) 0x3F3F Upper and Lower Non-Critical, Critical and Non-Recoverable Thresholds are Readable and Settable Reading Type Unsigned Lower Non-Critical, Critical and Non-Recoverable thresholds 0xD4, 0xCA, 0xC1 (11.024, 10.504, 10.
FRU Information and Sensor Data Records Table 7-45 Sensor No. 14, 48.0V FEED_2 Feature Raw Value/Description Sensor Name 48.
FRU Information and Sensor Data Records 7.3.5.2 Current Sensors The following table describes the sensors that measures the +12V current on the PEM. Table 7-46 Sensor No.
FRU Information and Sensor Data Records Table 7-47 Sensor No.
FRU Information and Sensor Data Records Table 7-48 Sensor No. 12 LM73 Temp (continued) Feature Raw Value/Description Event message control Readable threshold mask, Settable threshold mask (bytes 19, 20) Entire Sensor only 0x3838 Reading Type Upper Non-Critical, Critical and Non-Recoverable thresholds 7.3.6 Interpreted Value Upper Non-Critical, Critical and NonRecoverable Thresholds are Readable and Settable Unsigned 0x17, 0x23, 0x2E (40.48, 61.60, 80.
FRU Information and Sensor Data Records Table 7-49 Sensor No. 0, Hot Swap (continued) Feature Raw Value/Description Interpreted Value Hysteresis support Threshold access support Event Message Control Entire Sensor Only Readable threshold mask, Settable threshold mask (bytes 19, 20) Reading Type 7.3.6.2 According to PICMG 3.0 Lower Non-Critical, Critical and Non-Recoverable thresholds 0x84, 0x77, 0x71 (42.24, 38.08, 36.
FRU Information and Sensor Data Records Table 7-50 Sensor No. 1, IPMB Physical (continued) Feature Raw Value/Description Interpreted Value Threshold access support Event Message Control Entire Sensor Only Readable threshold mask, Settable threshold mask (bytes 19, 20) Reading Type 7.3.6.3 According to PICMG 3.0 Circuit Breaker State Sensors The following tables describe the OEM circuit breaker state sensors available on the PEM. Table 7-51 Sensor No.
FRU Information and Sensor Data Records Table 7-51 Sensor No. 5, CB 1 (continued) Feature Raw Value/Description Assertion Event Mask (byte 15, 16) 0x02, 0x00 Deassertion Event Mask (byte 17, 18) 0x02, 0x00 Discrete Reading Mask (byte 19, 20) 0x03, 0x00 Interpreted Value Supports 2 States Reading Definition According to Pigeon Point Table 7-52 Sensor No.
FRU Information and Sensor Data Records Table 7-53 Sensor No. 7 CB 3 Feature Raw Value/Description Sensor Name CB 3 Interpreted Value Type of Measurement Monitors if the Circuit Breaker has been opened.
FRU Information and Sensor Data Records Table 7-54 Sensor No. 8 CB 4 (continued) Feature Raw Value/Description Interpreted Value Entity ID 0x0A Power Supply Entity Instance 0x60 Rearm mode Auto Event message control Entire Sensor only Assertion Event Mask (bytes 15,16) 0x02, 0x00 Deassertion Event Mask (bytes 17,18) 0x02, 0x00 Discrete Reading Mask (bytes 19, 20) 0x03, 0x00 Supports 2 States Reading Definition According to Pigeon Point Table 7-55 Sensor No.
FRU Information and Sensor Data Records Table 7-55 Sensor No.
FRU Information and Sensor Data Records 170 AXP 1410 Installation and Use (6806800H70D)
Chapter 8 Shelf Management Alarm Module 8.1 Overview This chapter describes the AdvancedTCA Shelf Management Alarm Module, hereafter known as the SAM, which consists of the Shelf Management Controller (ShMC) and the Shelf Management Mezzanine Module (ShMM) which installs on the carrier blade. Two SAMs are installed into two dedicated shelf manager slots located at the bottom-rear of the AXP1410 16-Slot Shelf. The SAM is hot swappable and the connectors are accessible through the face plate.
Shelf Management Alarm Module z z 8.2 Support for the Command Line Interface (CLI) to access shelf information for: — Shelf blade population — List of sensors and sensor values — Sensor threshold settings — System events — Shelf health Control of chassis cooling management (fan levels) Features The SAM is based on the Pigeon Point Systems ShMM-1500R and Freescale MPC8343 System On a Chip (SOC). The following lists the features of the SAM. z High density, small (92 mm x 50.
Shelf Management Alarm Module interfaces for hardware redundancy, hot swap and carrier ID, plus the ATCA Watchdog and a high-speed serial interface for an alternate software redundancy interface between peer ShMM-1500Rs.
Shelf Management Alarm Module 8.3 SAM Diagram and Face Plate Layout Figure 8-1 shows a block diagram of the overall SAM architecture and Figure 8-2 on page 175 shows the face plate layout.
Shelf Management Alarm Module The SAM has these interfaces: z Four 10/100Base-T Ethernet links — One link to each system controller and switching blade (2) — One link to the redundant SAM — One link to the face plate z One Ethernet link, failover management status signals, and one IPMB branch or segment to the other SAM z Radial IPMB links for up to 20 modules (16 blades, 2 fan trays, and 2 PEMs) z Face plate interfaces that include 10/100Base-T Ethernet, RS232 serial console, and Telco alarm i
Shelf Management Alarm Module 8.4 Functional Description The SAM has a high-density 220 pin socket for the shelf management mezzanine (ShMM) device and front-panel connectors for the serial console, Ethernet, and Telco alarm signals of the mezzanine. The dual-IPMB interface from the mezzanine is connected to the dual IPMBs in the backplane. The SAM includes several on-board devices that enable different aspects of shelf management based on the shelf management mezzanine.
Shelf Management Alarm Module Table 8-2 Alarm Display Panel (ADP) Serial Port Connector 8.4.3 Pin Signal Direction 1 No Connect 2 RXD Input 3 TXD Output 4 No Connect 5 SigGnd 6 No Connect 7 No Connect 8 No Connect 9 No Connect Master-Only I2C Bus The SAM provides a number of I2C devices using the master-only I2C bus of the shelf manager mezzanine. The master-only I2C bus is used internally on the mezzanine for the real-time clock and EEPROM devices.
Shelf Management Alarm Module 8.4.5 SAM LEDs The SAM provides the LEDs listed in the following table. More detail on the LEDs is provided in the following sections. Also refer to Figure 8-2 on page 175 for SAM face plate LED locations and to Figure 1-1 on page 24 for the ADP teleco LED locations. Table 8-3 SAM LEDs LED Type Location Teleco Critical alarm (CRIT) Alarm Display Panel Major alarm (MAJ) Minor alarm (MIN) 8.4.5.
Shelf Management Alarm Module 8.4.5.2 SAM/ADP Status LEDs Status is shown using an LED on the SAM face plate and ADP. The illumination state of the LED is normally controlled by the GPIO on the SAM. The following tables describe the LED states. Table 8-5 SAM LED Status Indicators SAM Face Plate LED LED Color State State/Condition IS (In Service) Green On Active, power good OOS (Out of Service) Red On Failed HS (How Swap) Blue On Remove OK Table 8-6 ADP LED Status Indicators 8.
Shelf Management Alarm Module 8.5.1.1 Voltage Sensors On-board sensors provide the following power supply voltages. All voltage sensors are implemented using the ADM1024 device on the master-only I2C bus. System management software running on the SAM is responsible for reacting to an event when an interrupt is triggered by the ADM1024 device. 8.5.1.2 Temperature Monitoring An on-board temperature sensor is available on the SAM. This sensor is implemented through the ADM1024. 8.5.1.
Shelf Management Alarm Module The deltaT set point is calculated as follows: Set Point S1 S2 T2 T1 Inlet Air Temperature For ambient air temperatures at or below 25°C (default T1), the deltaT set point is set to 20°C (default S1). For ambient air temperatures at or above 55°C (default T2), the deltaT set point is set to 10°C (default S2).
Shelf Management Alarm Module Using the above algorithm, at 40°C ambient, the cooling algorithm adjusts the fan speeds to maintain a deltaT rise in temperature at 15°C. Table 8-7 Cooling Budget Ambient Temperature Temperature Rise 25°C Delta T = 20° C 40°C Delta T = 15° C 55°C Delta T = 10° C The values for S1, S2, T1, and T2 are configurable.
Shelf Management Alarm Module 8.5.2 Redundancy Control The ShMM-1500R supports redundant operation with automatic switchover using a redundant ShMM-1500R. In a configuration where two ShMM-1500Rs are present, one acts as the active shelf manager and the other as a standby. Both ShMM-1500Rs monitor each other, and either can trigger a switchover if necessary. The ShMM-1500R provides a number of hardware redundancy signals on the CN1 connector. The HRI is implemented using the FPGA device. 8.5.2.
Shelf Management Alarm Module to the power or ground rails. Hence, the device prevents an unpowered ShMM-1500R from loading down the HRI of the peer ShMM-1500R. It also prevents a carrier from detecting the ACTIVE# output as a zero; that is, active, during a ShMM-1500R power cycle or a ShMM-1500R power supply failure. The FPGA device contains a built-in CRC error checker for detecting soft errors in the configuration data.
Shelf Management Alarm Module 8.5.2.3 Ethernet Signals The SAMs implement a four-port 10/100Base-T Ethernet switch. The SAM’s 10/100Base-T links to each of the system controller/switching blades in logical hub slots 1 and 2.The backplane has a cross-connect between each hub slot and the other SAM, as shown in the following figure.
Shelf Management Alarm Module 8.5.3 Switchover Signals A switchover takes place when the Standby SAM determines that the Active SAM is no longer operational. The signs of this are: 8.6 z The REMOTE_HEALTHY or REMOTE_PRESENT changes to FALSE. This indicates that the peer SAM is no longer healthy or present z The TCP connection between the Active and the Standby SAMS closes.
Shelf Management Alarm Module 8.6.1 Telco Alarm Cutoff Push Button The SAM provides a Telco alarm cutoff function with the front-panel push button switch located on the ADP. This push button activates the alarm cutoff (ACO) state. When ACO is activated, the active alarm LED blinks and all of the alarm relays are deactivated. This button does not clear alarms. Refer to Figure 8-2 on page 175 for the location of the alarm cutoff push button switch. 8.6.
Shelf Management Alarm Module Table 8-8 Hot Swap Interface Pin Out (continued) 8.7 Pin Description 13 Major Alarm - COM 14 Pwr Alarm - NO 15 Pwr Alarm - COM Hot Swap Interface The SAM provides a hot swap interface allowing the SAM to be replaced without powering down the shelf. The hot swap interface is implemented using the shelf manager mezzanine CPLD device. The interface is composed of three components: 8.
Shelf Management Alarm Module 8.9.1 imls Utility A utility called imls is available on the SAM. It can be used to list all firmware images present in flash. Note that the Shelf Manager flash is divided into two banks.
Shelf Management Alarm Module /dev/mtdblock4: Image Name: shelfman 4.0.0 build 21 Created: Fri Jun 6 15:07:27 2008 Image Type: PowerPC Linux RAMDisk Image (gzip compressed) Data Size: 5398657 Bytes = 5272.13 kB = 5.15 MB Load Address: 0x00000000 Entry Point: 0x00000000 /dev/mtdblock8: Image Name: U-Boot 1.1.4 for shmm1500 board Created: Thu Mar 27 21:27:47 2008 Image Type: PowerPC Linux Firmware (uncompressed) Data Size: 212992 Bytes = 208.00 kB = 0.
Appendix A A Related Documentation A.1 Emerson Embedded Communications Computing Documents The Emerson Network Power - Embedded Computing publications listed below are referenced in this manual. You can obtain electronic copies of Emerson Network Power - Embedded Computing publications by contacting your local Emerson sales office. For documentation of final released (GA) products, you can also visit the following website: http://www.emersonnetworkpowerembeddedcomputing.
Related Documentation A.2 Related Specifications For additional information, refer to the following table for related specifications. As an additional help, a source for the listed document is provided. Please note that, while these sources have been verified, the information is subject to change without notice. Table A-2 Related Specifications Organization Document IEEE http://standards.ieee.
Safety Notes This section provides warnings that precede potentially dangerous procedures throughout this manual. Instructions contained in the warnings must be followed during all phases of operation, service, and repair of this equipment. You should also employ all other safety precautions necessary for the operation of the equipment in your operating environment.
Safety Notes Before you begin to set up and cable your new system, consider these guidelines: z Restricted access area: Install the system only in a restricted access area. z Installation codes: This unit must be installed in accordance with the National Electrical Code, Articles 11016, 11017, and 11018 and the Canadian Electrical Code, Section 12.a z Overcurrent protection: A readily accessible listed branch circuit overcurrent protective device must be incorporated into the building wiring.
Safety Notes Personal Injury or System Damage A top-heavy rack can tip, causing damage to equipment and injury to personnel. If your system is the only one in the rack, make sure to mount the system in the lowest part of the rack. If several systems are installed in one rack, start with the heaviest component at the bottom. If the rack is equipped with stabilizing devices, make sure that they are installed and extended so that the rack is secure. Then proceed to mount or service the system.
Safety Notes System Damage or Injury Covers and Panels Failure to operate the system without covering vacant slots will void the manufacturer’s warranty. Do not operate the system with open module slots. For optimal cooling of the system and associated payload and to prevent electric shock, cover all open module slots and put all panels in place before turning on power. Slot covers and panels must remain in place during system operation.
Safety Notes System Malfunction Prior to the PEM exchange the operating voltage conditions of the system should be made optimal. To ensure uninterrupted service during PEM exchange, the input voltage should be kept at nominal -48 V to -60 VDC.
Safety Notes Serious Injury or Death This product operates with dangerous voltages that can cause injury or death. To prevent serious injury or death from dangerous voltages use extreme caution when handling, testing, and adjusting this equipment and its components. The following paragraphs are not translated to German because they are only part of the UL/CSA 60950-1 (section 3.2.1, Annex NAA) standard, not of the European version EN609501.
Safety Notes French translation: Cet appareil est conçu pour permettre le raccordement du conducteur relié à la terre du circuit d'alimentation c.c. au conducteur de terre de l'appareil. Pour ce raccordement, toutes les conditions suivantes doivent être respectées: z Ce matériel doit être raccordé directement au conducteur de la prise de terre du circuit d'alimentation c.c.
Safety Notes Personal Injury Cables that are not installed securely can cause injuries due to entanglement or tripping. To avoid injury make sure cables are securely installed. Never change the system’s cabling as delivered by Emerson. The cabling should follow existing cable paths using existing or similar cable fastenings. Check proper function of the system after cabling extensions.
Safety Notes System Damage Munich Running the system longer than 30 seconds with less than three fans damages the system. If you exchange a fan (three remaining operating fans) ensure that the exchange procedure is finished within 30 seconds. System Damage A torn filter is ineffective in trapping particulates and will interrupt air flow distribution. Before returning a filter to service, visually inspect it for tears or rips that may have occurred during cleaning. Do not reinstall a torn filter.
Safety Notes Couper l’alimentation avant l’entretien et le depannage. For important grounding information for a DC power source, read the instructions in “cross reference”. Personal Injury Hot PEMs may cause injury. Allow the PEM to cool before servicing. Personal Injury Removing power from the PEMs cannot be accomplished by pulling the PEM's circuit breakers to the OFF position. The PEMs remain powered until the -48 VDC power to each PEM is completely removed.
Safety Notes Laser Personal Injury If a label with the words CLASS 1 LASER PRODUCT is affixed to the back of your system, the unit is equipped with a laser device. These devices contain a laser diode that produces invisible laser radiation harmful to the eyes. Performing adjustments or procedures other than those specified in this manual may result in hazardous radiation exposure. Do not look into the optical lens at any time.
Safety Notes VCCI This is a Class A product based on the standard of the Voluntary Control Council for Interference by Information Technology Interference (VCCI). If this equipment is used in a domestic environment, radio disturbance may arise. When such trouble occurs, the user may be required to take corrective actions.
Sicherheitshinweise Dieses Kapitel enthält Hinweise, die potentiell gefährlichen Prozeduren innerhalb dieses Handbuchs vorrangestellt sind. Beachten Sie unbedingt in allen Phasen des Betriebs, der Wartung und der Reparatur des Systems die Anweisungen, die diesen Hinweisen enthalten sind. Sie sollten außerdem alle anderen Vorsichtsmaßnahmen treffen, die für den Betrieb des Systems innerhalb Ihrer Betriebsumgebung notwendig sind.
Sicherheitshinweise System Installation Beschädigung des Systems Bitte beachten Sie, dass die im Handbuch angegebenen Voraussetzungen erfüllt sein müssen, bevor Sie das System installieren. Beachten Sie folgende allgemeinen Sicherheitshinweise bei der Installation des Systems: z Bereich mit eingeschränktem Zugang - Installieren Sie das System nur in Bereichen mit eingeschränktem Zugang.
Sicherheitshinweise Beschädigung des Systems Die Gleichspannungseingänge des Systems dürfen ausschließlich an zugelassene Telekommunikationsnetzspannungen (TNV-2) oder Sicherheits-Kleinspannungs-Stromkreise (SELV) angeschlossen werden. Wenn Sie das System an andere Stromkreise als TNV-2/SELV Stromkreise anschließen, verfällt die Sicherheitszulassung. Verletzungsgefahr und Beschädigung des Systems Das System ist an eine TNV-2 Spannungsquelle angeschlossen. Diese Spannung kann gefährlich sein.
Sicherheitshinweise Betrieb Überhitzung des Systems Lüftungsöffnungen Unzureichende Lüftung kann Schäden an Blades und am System verursachen und die Herstellergarantie ungültig werden lassen. Um eine ausreichende Lüftung zu gewährleisten, stellen Sie sicher, dass das System während des Betriebs waagerecht steht. Halten Sie die Lüftungsschlitze an der Oberseite, der Rückseite und den Seiten des Systems frei.
Sicherheitshinweise Verunreinigungen in der Luft können den Luftfilter verschmutzen und so die Luftzufuhr des Systems beeinträchtigen. Das kann zur Überhitzung des Systems und zu Schäden an Systemteilen führen. Luftfilter sollten mindestens alle 90 Tage ausgewechselt werden. Je nach Umgebungsbedingen kann dies auch früher nötig sein. Da die Verhältnisse in Vermittlungsstellen sehr unterschiedlich sein können, sollten Sie die Luftfilter nach der Erstinstallation des Systems jede Woche kontrollieren.
Sicherheitshinweise Falls die ORing Dioden des Produktes durchbrennen, kann das Produkt einen Kurzschluss zwischen den Eingangsleitungen A und B verursachen. In diesem Fall ist Leitung A immer noch unter Spannung, auch wenn sie vom Versorgungskreislauf getrennt ist (und umgekehrt). Prüfen Sie deshalb immer, ob die Leitung spannungsfrei ist, bevor Sie Ihre Arbeit fortsetzen, um Schäden oder Verletzungen zu vermeiden.
Sicherheitshinweise Stecker und Verkabelung Beschädigung des Systems Bei den RJ-45 Steckern, die sich auf einigen Produkten befinden, handelt es sich entweder um Twisted-Pair-Ethernet (TPE) oder um E1/T1/J1-Stecker. Beachten Sie, dass ein versehentliches Anschließen einer E1/T1/J1 Leitung an einen TPE-Stecker Ihr System zerstören kann. z Kennzeichnen Sie deshalb TPE-Anschlüsse in der Nähe Ihres Arbeitsplatzes deutlich als Netzwerkanschlüsse.
Sicherheitshinweise Verletzungsgefahr Schließen Sie in jedem Fall aus, dass Personen durch einen elektrischen Schlag verletzt werden können, indem Sie sicherstellen, dass Kontakte und Kabel des Systems während des Betriebs nicht berührt werden können. Falls Sie Fragen bezüglich der Verkabelung haben, wenden Sie sich an die für Sie zuständige Geschäftsstelle von Emerson.
Sicherheitshinweise Beschädigung des Systems Ein beschädigter Filter kann Schwebstoffe nur ungenügend ausfiltern und den Luftstrom beeinträchtigen. Prüfen Sie einen gereinigten Filter auf Risse bevor Sie ihn wieder in Betrieb nehmen. Bauen Sie keine beschädigten Filter in das System ein. Sie können Ersatzfilter bei der für Sie zuständigen Geschäftsstelle von Emerson bestellen. Beschädigung des Systems und Verletzungsgefahr Lüfterschaufeln können sich noch bewegen, nachdem der Strom abgestellt ist.
Sicherheitshinweise Verletzungsgefahr Stellen Sie sicher, dass das System abgeschaltet und von allen Stromversorungen getrennt ist, bevor Sie Systemkomponenten warten. So vermeiden Sie die Gefahr von Stromschlägen. Lesen Sie den Abschnitt "Querverweis" für weitere wichtige Informationen bezüglich Erdung von Gleichstromsystemem. Verletzungsgefahr Sie können sich an heissen PEMs verletzen. Lassen Sie die PEMs abkühlen, bevor Sie mit bloßen Händen herausziehen.
Sicherheitshinweise Laser Verletzungsgefahr Wenn sich an der Rückseite Ihres Systems ein Aufkleber mit der Aufschrift CLASS 1 LASER PRODUCT befindet, beeinhaltet das System ein Bauteil mit einem Laser. Solche Bauteile enthalten Laserdioden, die unsichtbare und für die Augen schädliche Laserstrahlen abgeben. Falls Sie sich nicht an die Anweisung in diesem Handbuch halten, kann dies zu gefählichen Strahlungsbelastungen führen. Schauen Sie niemals direkt in den Laserstrahl.
Sicherheitshinweise Änderungen, die nicht ausdrücklich von Emerson erlaubt sind, können Ihr Recht das System zu betreiben zunichte machen. Ein AXP 1410, das als Ersatzteil, Austauschchassis oder unkonfiguriertes System ausgeliefert wird, enthält keine Platzhalter-Boards. Es liegt in der Kundenverantwortung sicherzustellen, dass alle leeren Steckplätze mit Boards, RTMs oder zugelassenen Platzhalter-Boards belegt sind, um die Sicherheits- und EMC-Vorschriften zu erfüllen.
Index A CPIO extension 177 airflow 105 architecture, SAM1500 174 ATCA-F120 28 D B Backplane 26 backplane interface IP addresses 91 baud rate, SAM 176 Blade Hub 28 Node 27 block diagram, SAM1500 174 Blue LED 64 bonding point 28 busses I2C 177 off-board 177 C Cable length Power input 45 cables power feed sensing 52 chip temperature 180 circuit breakers 57 clogged filter 105 command line interface 188 comments and suggestions 21 configuring the I2C bus 177 connectivity record 94 connectors SAM1500 171 co
Index I2C devices 177 Installation 49 System 49 interfaces hot swap 188 serial 176 IP address 86 backplane interface 91 logical 87 out-of-band interface 88 physical 83 virtual 87 K kits, mounting brackets 50, 51 L LED Blue 64 LEDs behavior 178 face plate, SAM 178 face plate, SAM1500 175 FTM 105 logical slot number 83 M Management unit 26 Module Rear Transition 28 mounting bracket, part numbers 50, 51 N network interface 86 Noise 44 Control 44 O on-board circuitry 104 Options System installation 41 out
Index voltage 180 serial interface, SAM 176 shelf description 26 shelf geographical address 84, 99 shelf management 171 shelf management controller 171 shelf management mezzanine module 171 shelf management software 188 Shelf manager 26, 62 shelf manager replacement 85 Shipment 35 Site preparation 35 slot addressing, PEM 28 slot number logical 83 physical 83 slots, shelf manager 171 software PEM 103 SAM1500 171, 180, 188 Speed 219 Fan 38 SSH 99 status LED, SAM1500 179 Switch 28 System Components 23 Insta
Index 220 AXP 1410 Installation and Use (6806800H70D)
HOW TO REACH LITERATURE AND TECHNICAL SUPPORT: Tempe, Arizona, USA 1 800 759 1107 1 602 438 5720 Munich, Germany +49 89 9608 0 For literature, training, and technical assistance and support programs, visit www.emersonnetworkpowerembeddedcomputing.com Emerson Network Power. The global leader in enabling Business-Critical Continuity™ AC Power Systems Connectivity DC Power Systems Embedded Computing Embedded Power Integrated Cabinet Solutions www.emersonnetworkpowerembeddedcomputing.
