Enterasys Networks 2000 manual Trap Definitions, Link State Traps

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Managing Ethernet MicroLAN Switches

The Board Trap Selection window is similar to the Repeater Trap Selection window displayed in Figure 5-10, and serves the same function (since, for the Ethernet MicroLAN Switch, a “board” is the equivalent of a repeater channel). If all port-level trap settings are uniform at the current level of device management (i.e., a given trap is either set to enabled or disabled for all ports on a repeated network segment), the check box for a given trap will return with an enabled or disabled state, as appropriate. If port-level trap settings are mixed at the current level of management (i.e., a given trap is enabled at some ports and disabled at other ports on the selected repeater channel), the check box for a given trap will be grayed, as illustrated above for Link State traps.

When you are changing trap settings at the Repeater or Board level, a check box that is left gray for a given trap is treated as a “No SET” indicator, so that the current settings at the individual port level with respect to that trap will not be overridden when you are changing other trap settings.

The Port Trap Selection window is similar to the other Trap Selection windows; however the gray mixed-mode will never appear when you first open the window (since at the port-level, a given trap can only be either enabled or disabled – not some combination of the two).

You can change trap settings from any level window; however, if you have established individual trap settings for any ports, remember that enabling and disabling traps from the repeater- or module-level windows will override those individual setting. Remember, too, that setting trap selection state at the repeater and module levels accomplishes the same thing, as each “board” on the Ethernet MicroLAN Switch is a repeated network.

Trap Definitions

You can enable or disable the following kinds of traps:

Link State Traps

Some Ethernet repeater ports – including RJ45 twisted pair and fiber optic ports – generate a link signal to monitor the status of their connection with the device at the other end of the cable segment. If the cable is removed or broken, the port’s link status goes to “No Link” and the repeater generates a portLinkDown trap. When a port in a “No Link” condition receives a link signal, the port goes to a “Link” condition and the repeater generates a portLinkUp trap. Devices at both ends of the disconnected or broken cable will generate the portLinkDown and portLinkUp traps, even when only one end of the cable has been removed.

Note that BNC (thin coax), AUI, and transceiver ports do not support a link signal. BNC ports respond to changes in link status by generating portSegmenting and portUnsegmenting traps (see description, below); AUI and transceiver ports do not respond at all to changes in link status (unless the port has been segmented due to excessive collisions), and will always display as on, even if no cable is connected.

Trap Selection

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Contents SmartSwitch 2000 User’s Guide Page Virus Disclaimer Restricted Rights Notice Contents Alarm Configuration Chapter Statistics Chapter Managing Ethernet MicroLAN SwitchesIndex Chapter HSIM-W87 ConfigurationChapter Fddi Applications Introduction Introduction Introduction Introduction Using the SmartSwitch 2000 User’s Guide Software Conventions Using the MouseRelated Manuals Left Mouse Button Right Mouse Button Device Name Common SmartSwitch 2000 Window FieldsIP Address LocationGetting Help Using Window ButtonsUsing On-line Help Getting Help from the Global Technical Assistance Center Accessing On-line DocumentationLogin Introduction Getting Help SmartSwitch 2000 Chassis View Connection Status Viewing Chassis InformationFront Panel Information Port Status Boot PromFirmware TimeMenu Structure SmartSwitch 2000 Chassis View Menu StructureDevice Menu Port Status Menu Fddi Menu Repeater MenuModule Menu Utilities MenuHelp Menu Port Menus Status Port Status DisplaysSelecting a Port Status View Load Mapping ErrorsSpeed TypeSmartSwitch 2000 Chassis View Port Assignment Errors or Frame SizePort Status Color Codes Chassis Manager WindowDevice Type Viewing Hardware TypesConnection Type Module TypeInterface Description Viewing I/F Summary InformationDescription IndexPhysical Status Logical StatusRaw Counts Viewing Interface Detail RateAddress ErrorUnicast Non-UnicastPackets Received Received only Unknown Protocol Received onlyTransmit Queue Size Transmit only Packets Transmitted Transmit onlyComponent Using Device Find Source AddressPort Instance Component Managing the Hub Configuring Ports12. The Port Configuration Window Configuring Standard Ethernet and Fddi PortsFull Duplex Standard ModeConfiguring Fast Ethernet Ports on First Generation Devices 13. The Fast Ethernet Port Configuration Window Desired Operational Mode Current Operational ModePort Type Link StateRemote Capabilities Advertised AbilitiesFor 100Base-FX ports, options are Setting the Desired Operational ModeConfiguring Ethernet Ports on Second Generation Devices 14. The Ethernet Configuration Window Auto Negotiate Config Remote Auto SignalAuto Negotiate Mode Operational Mode FieldsFlow Control DuplexAuto Negotiation Technologies Configuring the COM Port Setting Advertised Abilities for Auto NegotiationCom Port Function Com Port AdminSpeed Selection Using an Uninterruptable Power Supply UPSAccessing the UPS Window UPS ID Setting the UPS ID Using the Disconnect Option Redirecting Traffic on the SmartSwitchUsing the Test Option To access the Port Redirect window Priority Configuration Configuring Priority Queuing Based on Receive Port 18. The Port Priority Configuration Window 19. The MAC Based Priority Configuration Window Configuring Priority Queuing Based on MAC-layer InformationAddress Type Current Priority EntriesFrame Type PriorityTo assign a transmit priority based on MAC-layer information Configuring Priority Queuing Based on Packet Type System Resources Window Dram Installed Flash Memory InstalledSram Installed Nvram InstalledReserving CPU Bandwidth 802.1Q VLANs What is a VLAN?About 802.1Q Vlan Configuration and Operation What is an 802.1Q Port-Based VLAN?Egress List Operation Ingress List Operation802.1Q Port Types 1Q TrunkHybrid Configuring Your 802.1Q VlansSetting Vlan Parameters and Operational Modes Vlan Name Admin StatusDeleting VLANs Creating and Modifying VLANsEnabling and Disabling VLANs Updating Vlan Config Window InformationPerforming Ingress List Configuration Mode Slot/PortDiscard Port Operational ModePort Discard Assigning Vlan Membership to PortsSetting Port Frame Discard Formats Setting Port Operational ModesUpdating Vlan Port Config Window Information Performing Egress List ConfigurationName Slot NumberEgress Ports Broadcast SuppressionEgress Untagged List Building an Egress ListTotal RX Port #Peak Rate Time Since PeakThreshold 26. The Edit Time Window Setting the Device Date and TimeEnabling and Disabling Ports SmartSwitch 2000 Chassis View Managing the Hub About Rmon Alarms and Events Alarm ConfigurationAlarm Configuration Basic Alarm ConfigurationRmon Basic Alarm Configuration Window Accessing the Basic Alarm Configuration WindowKilobits Total Errors Broadcasts/Multicasts Viewing Alarm StatusIf Number If TypePolling Interval Log/TrapRising Threshold Rising ActionCreating and Editing a Basic Alarm Alarm Configuration Disabling a Basic Alarm Viewing the Basic Alarm Log Accessing the Rmon Advanced Alarm/Event List Advanced Alarm ConfigurationRmon Advanced Alarm/Event List Window Alarm Configuration Creating and Editing an Advanced Alarm Rmon Create/Edit Alarms Window Alarm Configuration Alarm Configuration Alarm Configuration Table index.lengthin bytes.instancein decimal format Alarm Configuration Creating and Editing an Event Rmon Create/Edit Events Window Alarm Configuration Adding Actions to an Event Rmon Create/Edit Actions Window Viewing an Advanced Alarm Event Log Deleting an Alarm, Event, or ActionAlarm Configuration How Rising and Falling Thresholds Work Alarm Configuration How Rising and Falling Thresholds Work Statistics Accessing the Statistics WindowsStatistics Rmon StatisticsBytes ProblemsPackets Drop EventsFrame Size Bytes Packets Viewing Total, Delta, and Accumulated Statistics Printing Statistics If StatisticsIf Statistics Discarded Repeater Statistics Managing Ethernet MicroLAN SwitchesStatistics Windows Accessing the Statistics WindowsTo access the port-level Statistics window Statistics Defined Hard ErrorsActive Users BroadcastsUsing the Total and Delta Option Buttons Soft ErrorsAccessing the Timer Statistics Windows Timer StatisticsTo access the port-level Timer Statistics window Repeater Performance Graphs Setting the Timer Statistics IntervalAccessing the Performance Graph Windows Frames Blue Total Errors RedPercent Load Green Detail Button Configuring the Performance GraphsFrame Status Breakdown Error BreakdownAccessing the Alarm Limits Windows Alarm LimitsManaging Ethernet MicroLAN Switches Managing Ethernet MicroLAN Switches Collisions Broadcast Packets Errors of TypeWithin Configuring AlarmsSetting the Alarm Limits Time Interval Trap Selection Setting Alarm LimitsAccessing the Trap Selection Windows Link State Traps Trap DefinitionsSource Address Traps Segmentation TrapsConfiguring Traps Managing Ethernet MicroLAN Switches Fddi Applications Click on Fddi Statistics Concentrator ConfigurationMAC State Concentrator Configuration WindowSMT Version Neg. Negotiated Req. Requested Target Token Rotation TimeConcentrator M Ports Concentrator Non-M PortsConnection Policy Window Ring ConfigurationFddi Applications Number of Nodes Station ListStations Panel Address ModeNode Class Fddi PerformanceTopology Upstream NeighborTransmit Frames Frame ErrorsReceive Frames Lost FramesFrames/sec Fddi StatisticsKBytes/sec Peak KBytes/secSetting the Fddi Statistics Poll Rate Configuring Fddi Frame Translation SettingsUtil Click on Frame TranslationFrame Translation Window Information about Ethernet and Fddi Frame TypesEthernet Ethernet FramesEthernet Snap Ethernet 802.3 Ethernet RawFddi Frames FddiIP Fragmentation Fddi Frame Translation OptionsTranslate all Non-Novell Fddi Snap frames to Translate all Ethernet Raw frames toTranslate all Novell Fddi 802.2 frames to Translate all Novell Fddi Snap frames toTranslate all Novell Fddi MAC frames to Auto Learn Novell Frame TranslationAccessing the ATM Connections Window ATM ConfigurationConnection Data SettingsRefresh AddDelete Deleting a Connection Configuring ConnectionsAdding a New Connection T3 Configuration Window HSIM-W87 ConfigurationValid Intervals Time ElapsedLine Status T1 Configuration WindowT3 Line Type T3 Loop BackT1 Line Number T1 Line BuildOut T1 Frame TypeT1 Loop Back Max Entries Configuring IP PriorityIP Priority Queue Status Number of EntriesHSIM-W87 Configuration Configuring IP Priority Numerics SymbolsIndex-2 Index-3 Index-4 Index-5 Index Index-6
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2000 specifications

Enterasys Networks, a key player in the networking space in 2000, was renowned for its innovative solutions that combined high-performance networking with robust security features. Founded with the vision of providing enterprise-level networking infrastructure, Enterasys positioned itself to cater to the growing demands of business networks during the dot-com boom.

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Overall, Enterasys Networks in 2000 was characterized by its commitment to delivering secure, intelligent networking solutions that catered to the needs of modern enterprises. With its innovative technologies and features, Enterasys played a significant role in shaping the networking landscape, laying the groundwork for future advancements in network security and management.