HP ProLiant BL e-Class C-GbE Interconnect Switch User Guide February 2003 (Second Edition) Part Number 263682-002 HP CONFIDENTIAL Codename: DeLorean Part Number: 263682-002 Last Saved On: 2/5/03 10:38 AM
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Contents About This Guide Technician Notes........................................................................................................................................ vii Where to Go for Additional Help.............................................................................................................. viii Telephone Numbers ............................................................................................................................
Contents Chapter 2 Setting up and Installing the Interconnect Switch Overview....................................................................................................................................................2-1 Installing Interconnect Switch Hardware...................................................................................................2-1 Installing a New Interconnect Tray in a New ProLiant BL e-Class Server Blade Enclosure .............
Contents Packet Corruption ............................................................................................................................ D-12 Resource Errors................................................................................................................................ D-12 Identifying a Data Loop ................................................................................................................... D-12 Avoiding Trouble............................................
About This Guide This guide can be used for reference when servicing the HP ProLiant BL e-Class C-GbE Interconnect Switch. WARNING: To reduce the risk of personal injury from electric shock and hazardous energy levels, only authorized service technicians should attempt to repair this equipment. Improper repairs can create conditions that are hazardous. Technician Notes WARNING: Only authorized technicians trained by HP should attempt to repair this equipment.
About This Guide NOTE: Any indications of component replacement or printed wiring board modifications may void any warranty.
1 Introduction Overview This user guide provides installation and reference information for the HP ProLiant BL e-Class C-GbE Interconnect Switch. Configuration and management information provided in this guide applies to interconnect switches running firmware version 2.0.
Introduction ProLiant BL e-Class C-GbE Interconnect Switch The ProLiant BL e-Class C-GbE (Copper Gigabit Ethernet) Interconnect Switch uses 10/100/1000 Gigabit Layer 2 switch technology to provide up to a 40-to-1 reduction in the number of networking cables required for each ProLiant BL e-Class server blade enclosure. Each interconnect switch reduces forty 10Base-T/100Base-TX server networking ports to as few as one (up to four) RJ-45 10Base-T/100Base-TX/1000Base-T uplink ports.
Introduction • Support for saving and downloading switch configurations to a TFTP server, thus allowing for rapid deployment of multiple systems, and backup and restore capabilities • Uplink and management ports with link activity and speed indicators • Extra ports for management debugging and port mirroring Interconnect Switch Redundancy The ProLiant BL e-Class C-GbE Interconnect Switch offers several redundancy and failover features.
Introduction Diagnostic Tools The hardware, software, and firmware diagnostic tools that are available include: • ProLiant BL e-Class Integrated Administrator • Insight Manager 7 • Power-On Self Test (POST) built into the interconnect switch boot-up process • C-GbE Interconnect Switch Management System and Utilities • C-GbE Interconnect Switch port mirroring • C-GbE Interconnect Switch LEDs for port status and speed • Medium Access Control (MAC)-based backdoor password provision (contact HP te
Introduction Integrated Administrator The ProLiant BL e-Class Integrated Administrator provides centralized, remote management and monitoring for the ProLiant BL e-Class server blade enclosure, interconnect switch module, and 20 server blades. The Integrated Administrator acts as a combination terminal server and remote power controller, enabling out-of-band, secure, serial console connections to all server blades in the enclosure.
Introduction Supported Technologies The ProLiant BL e-Class C-GbE Interconnect Switch supports the following technologies. Layer 2 Switching The ProLiant BL e-Class C-GbE Interconnect Switch uses 10/100/1000 Gigabit Layer 2 switching technology. Layer 2 refers to the Data Link layer of the Open Systems Interconnection (OSI) model, which is concerned with moving data packets across a network by enforcing Carrier Sense Multiple Access with Collision Detection (CSMA/CD).
Introduction Simple Network Management Protocol and Remote Monitoring Each switch module can be configured and monitored remotely from a Simple Network Management Protocol (SNMP)/Remote Monitoring (RMON) based Network Management Station. The switch modules support industry-standard SNMP Management Information Bases (MIBs), HP Switch MIBs, and RMON groups 1 (statistics), 2 (History), 3 (Alarm), and 9 (Event) for fault detection, configuration, and monitoring of switch functionality.
Introduction IEEE 802.1p-Based Class of Service for Packet Prioritization Class of Service (CoS) for packet prioritization allows switch administrators to set priority levels on the interconnect switch for forwarding packets based on the priority setting information in the packets. The interconnect switch supports four classes of traffic (buffers or queues) for implementing priority. The interconnect switch allows administrators to map eight priority levels to four classes.
Introduction Simple Network Time Protocol The interconnect switch can maintain the current date and time. This information displays on the management interfaces and is used to record the date and time of switch events. Current date and time information can be manually set on the interconnect swithc or can be obtained through Simple Network Time Protocol (SNTP).
Introduction Table 1-1: Interconnect Switch External Panel Item Description Location 1 Gigabit Ethernet port 26 connector on Switch B Interconnect switch 2 Gigabit Ethernet port 25 connector on Switch B Interconnect switch 3 Integrated Administrator management RJ-45 connector (Switch A Port 24—10/100 Ethernet) Integrated Administrator module 4 Integrated Administrator console connector (serial) Integrated Administrator module 5 Reserved for future use Integrated Administrator module 6 Re
Introduction Figure 1-4: Interconnect switch external panel LEDs Table 1-2: Interconnect Switch External Panel LEDs Item LED Description Status 1 Integrated Administrator module health Green = Enclosure on, Integrated Administrator health good Amber = Integrated Administrator health degraded Red = Integrated Administrator health critical Off = Enclosure off 2 Interconnect switch health Green = Enclosure on, interconnect switch health good Amber = Interconnect switch health degraded Red = Interconne
2 Setting up and Installing the Interconnect Switch Overview This chapter describes how to set up and install the ProLiant BL e-Class C-GbE Interconnect Switch and connect it to your network. The setup and installation procedure includes the following tasks: 1. Installing the interconnect switch hardware 2. Planning the interconnect switch configuration 3. Cabling the interconnect tray to the network 4. Configuring the Integrated Administrator module 5.
Setting up and Installing the Interconnect Switch Installing a New Interconnect Tray in a New ProLiant BL e-Class Server Blade Enclosure To install a new interconnect tray: Figure 2-1: Removing a hot-plug power supply 1. Press the port-colored latch to release one hot-plug power supply (1). NOTE: Port-color indicates hot-plug components. 2. Pull the handle to its open position (2). 3. Slide the hot-plug power supply out of the server blade enclosure (3). 4.
Setting up and Installing the Interconnect Switch NOTE: Slate blue indicates internal touch point components. Figure 2-3: Inserting the interconnect tray and engaging the interconnect tray levers 7. Insert the interconnect tray into the server blade enclosure (1). 8. Simultaneously rotate both ejector levers to the locked position (2). Figure 2-4: Installing a hot-plug power supply 9. Install the hot-plug power supplies (1). 10. Push the power supply handles to the closed position (2).
Setting up and Installing the Interconnect Switch Replacing an Existing Interconnect Tray To replace an existing interconnect tray: 1. Upload the current switch configuration to a TFTP server. Refer to the “Saving Settings to a TFTP Server” section in the management interface reference guides. IMPORTANT: HP recommends saving the switch module configuration to a TFTP server once the switch module configuration is complete or has changed. Figure 2-5: Removing a hot-plug power supply 2.
Setting up and Installing the Interconnect Switch 7. Simultaneously pull both slate blue ejector levers toward the rear of the server blade enclosure (2). IMPORTANT: Slate blue indicates internal touch point components. 8. Pull the existing interconnect tray out of the server blade enclosure. Figure 2-7: Inserting the new interconnect tray and engaging the interconnect tray levers 9. Insert the new interconnect tray into the server blade enclosure (1). 10.
Setting up and Installing the Interconnect Switch Replacing a Patch Panel Tray To remove the patch panel tray and install an interconnect tray: Figure 2-9: Removing a hot-plug power supply 1. Press the port-colored latch to release one hot-plug power supply (1). IMPORTANT: Port-color indicates hot-plug components. 2. Pull the handle to its open position (2). 3. Slide the hot-plug power supply out of the server blade enclosure (3). 4. Repeat steps 1 through 3 to remove the other hot-plug power supply.
Setting up and Installing the Interconnect Switch 7. Pull the patch panel tray out of the server blade enclosure (3). Figure 2-11: Inserting the interconnect tray and engaging the interconnect tray levers 8. Insert the interconnect tray into the server blade enclosure (1). 9. Simultaneously rotate both ejector levers to the locked position (2). Figure 2-12: Installing a hot-plug power supply 10. Install the hot-plug power supplies (1). 11. Push the power supply handles to the closed position (2).
Setting up and Installing the Interconnect Switch Planning the Interconnect Switch Configuration Before you configure the switch modules, HP recommends that you plan the configuration. As you plan, keep in mind the default settings, security issues and privileges, and whether you want to configure each switch module manually or configure multiple switch modules at the same time. Default Settings IMPORTANT: Refer to Appendix C for detailed default configuration settings.
Setting up and Installing the Interconnect Switch Interconnect Switch Security When planning the configuration for a switch module, secure access to the management interface by: • Creating users with various access levels to the local console, remote Telnet, and Web interface. Refer to Table 2-1 for the three levels of user access privileges. • Enabling or disabling access to various management interfaces to fit the security policy.
Setting up and Installing the Interconnect Switch Configuring Multiple Switch Modules You can configure multiple switch modules by using scripted Command Line Interface (CLI) commands through Telnet or by downloading a configuration file using a TFTP server. Using Scripted CLI Commands through Telnet The CLI, provided with the interconnect switch, allows you to execute customized configuration scripts on multiple switch modules.
Setting up and Installing the Interconnect Switch To cable the interconnect tray: Figure 2-13: Connecting the Integrated Administrator module 1. Connect the Integrated Administrator module to your network by using the management connector (10/100 Ethernet). Figure 2-14: Connecting the network cables 2. Install the network cables. By default, each server blade has PXE enabled on Ethernet Port 1.
Setting up and Installing the Interconnect Switch Figure 2-15: Connecting the power cables 3. Install the power cords. The server blade enclosure and interconnect switch power up as soon as power is applied to the enclosure. CAUTION: Because the server blade enclosure uses both power supplies for power redundancy and proper cooling, be sure that both power cords are connected at all times. Figure 2-16: Routing the cables 4.
Setting up and Installing the Interconnect Switch Configuring the Integrated Administrator After cabling the interconnect switch to your network, the next step is to configure the Integrated Administrator module. The Integrated Administrator module enables monitoring and managing of all functions within a server blade enclosure, as well as the ability to configure the switch modules.
Setting up and Installing the Interconnect Switch IMPORTANT: User name and password are case-sensitive. 4. Determine the Integrated Administrator IP address using one of the following methods: NOTE: For more information, such as determining the Integrated Administrator IP address using the Web-based user interface, refer to the HP ProLiant BL e-Class Integrated Administrator User Guide on the Documentation CD provided with your server blade enclosure. a.
Setting up and Installing the Interconnect Switch b. If you have not logged on to the Integrated Administrator, you can use one of two special logon accounts to access the switch module consoles directly, depending on whether you want to access Switch A or Switch B. At the login prompt type in both the user name and password as either: switcha or switchb The logon screen for Switch A or Switch B will now be displayed. 2. Perform the following tasks for each switch module: a. Configure the IP address b.
Setting up and Installing the Interconnect Switch Supporting Software and Special Considerations The following supporting software is available to assist you in configuring the interconnect switch: • Utilities package and documentation—provides interconnect switch utilities, secure replacement procedures, and information on scripting and firmware upgrades • Interconnect Switch Firmware Upgrade Smart Component (for Microsoft Windows only)—Provides quick and easy installation of the interconnect switch fi
A Regulatory Compliance Notices Class A Equipment This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment.
Regulatory Compliance Notices European Union Notice Products bearing the CE marking comply with the EMC Directive (89/336/EEC) and the Low Voltage Directive (73/23/EEC) issued by the Commission of the European Community and if this product has telecommunication functionality, the R&TTE Directive (1999/5/EC).
B Technical Specifications Table B-1: General Specifications Standards IEEE 802.1D Spanning Tree IEEE 802.1p QoS prioritization IEEE 802.1Q VLAN IEEE 802.3 10Base-T Ethernet IEEE 802.3ab 1000Base-T Ethernet IEEE 802.3ac Frame Extensions for VLAN IEEE 802.3ad Link Aggregation Protocol (No LACP support) IEEE 802.3u 100Base-TX Fast Ethernet IEEE 802.3x Full-Duplex Flow Control ANSI/IEEE 802.
Technical Specifications Table B-1: General Specifications continued Network Cables 10Base-T 2 Pair UTP Category 3,4,5 (100 m) EIA/TIA-568 100-ohm STP (100 m) 100Base-TX 2 Pair or 4 Pair UTP Category 5 (100 m) EIA/TIA-568 100-ohm STP (100 m) 1000Base and 1000Base-T 4 Pair UTP Category 5e (100 m) EIA/TIA-568 100-ohm STP (100 m) Number of Ports 42—10/100-Mb/s Nway Ethernet Ports 4—10/100/1000 Base-T/TX/T Uplink Ethernet Ports 1—Serial RS-232 Console Management Port (through the Integrated Administrato
Technical Specifications Table B-3: Performance Specifications Transmission Method Store-and-forward Memory 32MB Main, 8MB flash, and 16MB packet buffer per switch module Filtering Address Table 8K Packet Filtering/Forwarding Rate Full-wire speed for all connections. 148,809.
C Runtime Switching Software Default Settings Default Settings This section provides the default settings for the interconnect switch modules.
Runtime Switching Software Default Settings Table C-1: Default Settings continued Setting Value Web Status Enabled Telnet/RS232 Interface Menu Group Address Filter Mode Forward all unregistered Scheduling Mechanism for CoS Queues Strict Trunk Load Sharing Algorithm Src Address Backpressure Disabled Port Speed/Duplex Auto Flow Control On Setup Restart Ingress Bandwidth None Setup Restart Egress Bandwidth None Switch STP Enabled Bridge Max Age 20 seconds Bridge Hello Time 2 seconds
Runtime Switching Software Default Settings Table C-1: Default Settings continued Setting Value Port Mirroring—Mirror Status Disabled Broadcast Storm Monitoring Disabled Multicast Storm Monitoring Disabled DA Unknown Storm Monitoring Disabled Storm Threshold 500 packets/second Port State Enabled Class of Service—Max Packets 10 Class of Service—Max Latency 0 Port Priority 0 Class of Traffic Priority 0, 1: Class 0 Priority 4, 5: Class 2 Priority 2, 3: Class 1 Priority 6, 7: Class 3 P
Runtime Switching Software Default Settings Table C-1: Default Settings continued Setting Value Serial Port Baud Rate Fixed 115,200 VLAN Mode IEEE 802.1Q SNTP Disabled SNTP Server 1 0.0.0.0 SNTP Server 2 0.0.0.0 SNTP Poll Interval 720 seconds Time Zone -06.
Runtime Switching Software Default Settings Port Names, VLANs, STP/By Pass, Trunking Default Settings Table C-2: Switch Module A Port Type UI Port # Speed VID VLAN Member AS VLAN Name Port Name STP / ByPass Enabled Server 1 10/100 (Auto) 1 Egress DEFAULT_VLAN Server1_Port1 Yes Server 2 10/100 (Auto) 1 Egress DEFAULT_VLAN Server2_Port1 Yes Server 3 10/100 (Auto) 1 Egress DEFAULT_VLAN Server3_Port1 Yes Server 4 10/100 (Auto) 1 Egress DEFAULT_VLAN Server4_Port1 Yes Serv
Runtime Switching Software Default Settings Table C-2: Switch Module A continued Port Type UI Port # Speed VID VLAN Member AS VLAN Name Port Name STP / ByPass Enabled Server 18 10/100 (Auto) 1 Egress DEFAULT_VLAN Server18_Port1 Yes Server 19 10/100 (Auto) 1 Egress DEFAULT_VLAN Server19_Port1 Yes Server 20 10/100 (Auto) 1 Egress DEFAULT_VLAN Server20_Port1 Yes X-Connect 21 10/100 (Auto) 1 Egress DEFAULT_VLAN XConnect1 No XConnect X-Connect 22 10/100 (Auto) 1 Egre
Runtime Switching Software Default Settings Table C-3: Switch Module B Port Type UI Port # Speed VID VLAN Member AS VLAN Name Port Name STP / ByPass Enabled Server 1 10/100 (Auto) 1 Egress DEFAULT_VLAN Server1_Port2 Yes Server 2 10/100 (Auto) 1 Egress DEFAULT_VLAN Server2_Port2 Yes Server 3 10/100 (Auto) 1 Egress DEFAULT_VLAN Server3_Port2 Yes Server 4 10/100 (Auto) 1 Egress DEFAULT_VLAN Server4_Port2 Yes Server 5 10/100 (Auto) 1 Egress DEFAULT_VLAN Server5_Por
Runtime Switching Software Default Settings Table C-3: Switch Module B continued Port Type UI Port # Speed VID VLAN Member AS VLAN Name Port Name STP / ByPass Enabled Server 19 10/100 (Auto) 1 Egress DEFAULT_VLAN Server19_Port2 Yes Server 20 10/100 (Auto) 1 Egress DEFAULT_VLAN Server20_Port2 Yes X-Connect 21 10/100 (Auto) 1 Egress DEFAULT_VLAN XConnect1 No XConnect X-Connect 22 10/100 (Auto) 1 Egress DEFAULT_VLAN XConnect2 No XConnect IA NIC 23 10/100 (Auto) NA
D Spanning Tree Protocol Introduction When Spanning Tree Protocol determines a port should be transitioned to the forwarding state, the following occurs: • The port is put into the listening state where it receives Bridge Protocol Data Units (BPDUs) and passes them to the GbE Interconnect Switch’s CPU. • If no BPDUs that suggest the port should go to the blocking state are received, the BPDU packets from the CPU are processed — The port waits for the expiration of the forward delay timer.
Spanning Tree Protocol • Does not transmit BPDUs received from the CPU. • Receives and responds to network management messages. Figure D-1: Blocking State Listening State The listening state is the first transition for a port from the blocking state. Listening is an opportunity for the switch to receive BPDUs that may tell the switch that the port should not continue to transition to the forwarding state, but should return to the blocking state (that is, a different port is a better choice).
Spanning Tree Protocol A port in the listening state does the following: • Discards frames received from the network segment to which it is attached. • Discards packets sent from another port on the switch for forwarding. • Does not add addresses to its forwarding database. • Receives BPDUs and directs them to the CPU. • Processes BPDUs received from the CPU. • Receives and responds to network management messages.
Spanning Tree Protocol Learning State A port in the learning state prepares to participate in frame forwarding. The port enters the learning state from the listening state. A port in the learning state does the following: D-4 • Discards frames received from the network segment to which it is attached. • Discards packets sent from another port on the switch for forwarding. • Adds addresses to its forwarding database. • Receives BPDUs and directs them to the CPU.
Spanning Tree Protocol Figure D-3: Learning State Forwarding State A port in the forwarding state forwards packets. The port enters the forwarding state from the learning state when the forward delay timer expires.
Spanning Tree Protocol A port in the forwarding state does the following: • Forwards packets received from the network segment to which it is attached. • Forwards packets sent from another port on the switch for forwarding. • Incorporates station location information into its address database. • Receives BPDUs and directs them to the system CPU. • Receives and responds to network management messages.
Spanning Tree Protocol Disabled State A port in the disabled state does not participate in frame forwarding or STP. A port in the disabled state is virtually non-operational. A disabled port does the following: • Discards packets received from the network segment to which it is attached. • Discards packets sent from another port on the switch for forwarding. • Does not add addresses to its forwarding database. • Receives BPDUs, but does not direct them to the system CPU.
Spanning Tree Protocol Figure D-5: Disabled State D-8 HP ProLiant BL e-Class C-GbE Interconnect Switch User Guide HP CONFIDENTIAL Codename: DeLorean Part Number: 263682-002 Last Saved On: 2/5/03 10:46 AM
Spanning Tree Protocol Troubleshooting STP This section describes several troubleshooting tips. Spanning Tree Protocol Failure A failure in the STP generally leads to a bridging loop. A bridging loop in an STP environment comes from a port that should be in the blocking state, but is forwarding packets. Figure D-6: Example of Spanning Tree Protocol failure In this example, B has been elected as the designated bridge, and Port 2 on C is in the blocking state.
Spanning Tree Protocol Full/Half Duplex Mismatch A mismatch in the duplex state of two ports is a very common configuration error for a pointto-point link. If one port is configured as full-duplex, and the other port is left in autonegotiation mode, the second port will end up in half-duplex because ports configured as half- or full-duplex do not negotiate.
Spanning Tree Protocol Unidirectional Link Unidirectional links can be caused by an undetected failure in one side of a fiber cable, or a problem with a ports transceiver. Any failure that allows a link to remain up while providing one-way communication is very dangerous for STP. Figure D-8: Example unidirectional link In this example, Port 2 on B can receive but not transmit packets.
Spanning Tree Protocol Packet Corruption Packet corruption can also lead to Spanning Tree Protocol failure. If a link is experiencing a high rate of physical errors, a large number of consecutive BPDUs can be dropped and a port in the blocking state would transition to the forwarding state. The blocking port would have to have the BPDUs are dropped for 50 seconds (at the default settings) and a single BPDU would reset the timer. If the max age is set too low, this time is reduced.
Spanning Tree Protocol Avoiding Trouble Below are some tips for avoiding trouble. Know Where the Root is Located Although the STP can elect a root bridge, a well-designed network will have an identifiable root for each VLAN. Careful setup of the STP parameters will lead to the selection of this best interconnect switch as the root for each VLAN. Redundant links can then be built into the network.
Spanning Tree Protocol The above graphic is an example of a common network design. The switches C and D have redundant links to the backbone switches A and B using trunks. Trunks, by default, carry all the VLAN traffic from VLAN 1 and VLAN 2. So switch C is not only receiving traffic for VLAN 1, but it is also receiving unnecessary broadcast and multicast traffic for VLAN 2. It is also blocking one port for VLAN 2.
E SNMP/RMON MIBs Support Introduction Management and statistics information is stored in the interconnect switch in the Management Information Base (MIB). The interconnect switch supports several standard MIBs. Values for MIB objects can be retrieved with any SNMP-based network management software. In addition to the standard MIBs, the switch also supports its own proprietary enterprise MIB as an extended Management Information Base.
SNMP/RMON MIBs Support Use an SNMP manager, such as HP OpenView or IBM Tivoli NetView, to access the enterprise-specific MIBs. Compile the MIBs into the MIB database and then use a MIB browser to navigate through them. For detailed information, access the individual descriptions of each MIB or refer to the documentation that came with your SNMP manager software.
SNMP/RMON MIBs Support • vesubio.mib — swL2BwMgmt—Management of the ingress and egress bandwidth — swL2CosMgmt—Management of Class of Service — swL2PortSecurityMgmt—Management of port security — dswL2DevMgmt—Management of device advanced settings — swL2PortMgmt—Management of the port link • CIMTRAPS.mib—Redefining of the entConfigChange trap in SNMP SNMP Traps The interconnect switch may generate the following SNMP traps (event notifications). Refer to the MIBs for detailed information.
SNMP/RMON MIBs Support E-4 • switchPostSuccess • switchLoginFailure • switchLocationChange • switchCubeTypeChange • switchSNTPServiceUnavailable HP ProLiant BL e-Class E-GbE Interconnect Switch User Guide HP CONFIDENTIAL Codename: DeLorean Part Number: 263682-002 Last Saved On: 2/5/03 10:48 AM
F Upgrading Firmware through the Serial Port You can upgrade the system firmware of a switch module by connecting your computer to the serial console port of the Integrated Administrator and using terminal emulation software that supports the ZModem or XModem protocol. This procedure is only necessary if your interconnect switch does not have access to a TFTP server, or if the firmware procedure was previously interrupted and the switch module is not booting properly.
Upgrading Firmware through the Serial Port Figure F-1: POST message 3. Press the pound (#) key as soon as you see the Boot Procedure header. This action forces the switch module into the download mode. A screen similar to the following is displayed.
Upgrading Firmware through the Serial Port 4. Configure the download protocol (ZModem or XModem) or use the default boot configuration settings. a. Within 60-90 seconds, press the Ctrl+C keys to display the Boot Configuration Menu. b. To use the default boot configuration settings, go to step 9. Figure F-3: Boot Configuration menu 5. Select XModem or ZModem as the download protocol. 6. Highlight Reboot. 7. Press the Enter key. The switch module reboots.
Upgrading Firmware through the Serial Port 8. While the switch module is rebooting, press the pound (#) key again to force the switch module into download mode. The download mode message is displayed. (Refer to Figure F-2.) NOTE: For faster transfers, you may want to change the speed of your console connection from 9600 to 115200. If you continue to transfer at 9600, go to step 13. 9. Press the Integrated Administrator escape character _.
Upgrading Firmware through the Serial Port Figure F-4: Connection-established message 13. Before beginning the ZModem transfer, disable the Integrated Administrator escape character to ensure a transparent connection for the file transfer.
Upgrading Firmware through the Serial Port 15. From the Interconnect Switch HyperTerminal window menu, select Transfer, then Send File. The following window is displayed. Figure F-5: Send File window 16. Click Browse and select the firmware file to be downloaded to the switch module. 17. Select the download protocol from the drop-down menu. 18. Press Send to start the download process. The following screen is displayed.
Upgrading Firmware through the Serial Port After the firmware file transfer is complete, a download-completed message is displayed. Then, the interconnect login screen is displayed. Figure F-7: Download-completed message Figure F-8: ProLiant BL e-Class C-GbE Interconnect Switch login screen 19. Close your connection with the Integrated Administrator, which will reset the Integrated Administrator console port to 9600 baud (if you changed the speed previously).
Upgrading Firmware through the Serial Port 20. Press Ctrl+_ twelve times in sequence to re-enable the escape character. The following text is displayed: ----------------------------------------------------------------Command: D)isconnect, C)hange settings, R)eboot Switch, E)xit command mode ----------------------------------------------------------------- 21. Press D to disconnect your session. If you changed the speed previously, you must reset your terminal to 9600 baud to continue.
G Port Trunking and Load Balancing in Blade Switches Introduction IEEE 802.3ad and EtherChannel compatible port trunks allow multiple physical Ethernet links to be combined into one logical channel/trunk. This allows load sharing of traffic among the links in the port trunk as well as redundancy in the event that one or more links in the port trunk should fail.
Port Trunking and Load Balancing in Blade Switches Circumstances can occur where one address in the source/destination pair is a constant. For example, the destination might be a server or, even more likely, a router. In that case, if both the source address and destination address option is selected, you will still see statistical load balancing, because the source address is always different.
Port Trunking and Load Balancing in Blade Switches Configuring Load Balancing on Blade Switches To configure the load balancing and forwarding method using the menu-driven interface, access the Configure Advanced Switch Features screen. Toggle the Trunk Load Sharing Algorithm field to the appropriate selection. To configure the load balancing and forwarding method using the Web-based interface, access the Switch Information (Advanced Settings) screen.
Port Trunking and Load Balancing in Blade Switches Hashing Algorithms for Load Balancing The hashing algorithms use the last three least significant bits (LSB) of the destination MAC address (DA), source MAC address (SA), or destination and source MAC address (DA XOR SA) and the number of links that are available to forward frames in that port trunk group as operators.
Port Trunking and Load Balancing in Blade Switches For example: There is a port trunk group with eight member ports, and there is a frame with SA=0x0080C800000B DA=0x0080C800000C. • SA last three bits is 0b011 • DA last three bits is 0b100 • SA XOR DA is 0b111 In the following example, four trunk ports are link up in the port trunk. • For algorithm 1, N = 0b011 MOD 4 = 3 The outgoing port would be the fourth link up in the port trunk.
Port Trunking and Load Balancing in Blade Switches Redundancy: What Happens When One Link in the Port Trunk Fails? If a segment within the port trunk fails, traffic previously carried over the failed link switches to the remaining segments within the port trunk. Inbound broadcast and multicast packets on one segment in a port trunk are blocked from returning on any other segment of the port trunk. 802.
H XML Configuration Introduction Beginning in firmware version 2.0.0, interconnect switch firmware configuration files are specified in eXtensible Markup Language (XML) format. In previous versions, the configuration file was stored in binary format. Binary configuration files saved from previous versions cannot be downloaded into firmware version 2.0.0. However, previous configuration settings are preserved during the firmware upgrade to version 2.0.0.
XML Configuration Safe Mode When inserting a new or replacement interconnect switch into a production environment, you must be certain that the interconnect switch configuration is compatible with the production network. Compatibility with a network can include items such as: • Non-corruption of the network in general—Corruption, such as loops, can occur within the network without enabling Spanning Tree Protocol (STP).
XML Configuration Safe Mode Configuration File Templates Two example template configuration files have been provided as a basis to create an appropriate safe mode configuration. Each file is delivered with the Switch Management Utilities package specific to a particular type of interconnect switch. • esafe_ex.xml • psafe_ex.xml NOTE: The templates provided are only examples, and should not be used in a production environment without modifications rquired for your specific production network.
XML Configuration • Change the following settings to match the remote TFTP server. • Port 19 has been left Enabled on p-Class interconnect switches (port 23 on e-Class).
XML Configuration • You may wish to allow only a single IP address (management station) access. • Change the read-write community string per your environment.