Introduction to the Catalyst 3920

• Half-duplex concentrator port—The port is connected to a single station in HDX mode. In this case, the port behaves like an active media access unit (MAU) port for classical Token Ring.
  
  
• Half-duplex station emulation—The port is connected to a port on an MAU. In this case, the port behaves like a station connected to a classical Token Ring segment that contains multiple stations.
  
  
• Full-duplex concentrator port—The port is connected to a single station in FDX mode.
  
  
• Full-duplex station emulation—The port is connected to another Token Ring switch in FDX mode.
  
  

The mode of operation can be configured, or it can be automatically sensed when equipment is connected to the port. The media speed (4 or 16 Mbps) can also be configured or automatically sensed in all port modes.

The queue for a frame is determined by the value of the priority field in the frame control (FC) byte of the frame. If FC priority is above a configurable level (the default is 3), the frame is put in the high-priority queue. If an output port becomes congested, you can dynamically configure the port to transmit all frames at high priority regardless of the FC byte contents.

The Catalyst 3920 CPU software monitors the size of the output queue at each Token Ring port to minimize the effects of congestion at output ports. When port congestion is detected, the Catalyst 3920 does the following:

• Raises the transmit priority to a higher level for low-priority frames
  
  
• Discards the oldest frames when the output queue is almost full
  
  

• MAC address (source address, destination address)
  
  
• Protocol (destination service access point [DSAP]/Subnetwork Access Protocol [SNAP] Type)
  
  

MAC address filters and broadcast filters can be applied only at input ports. DSAP and SNAP filters can be applied at input ports and output ports.

The Catalyst 3920 is also notified when a Token Ring beacon state is detected on the ring and when it disappears. If the beacon state remains for more than a specified amount of time, the port is instructed to discard all frames in the output queue and to reject new frames. When the beacon state disappears, the port is instructed to once again accept frames.

There are two levels of VLANs supported by the Catalyst 3920. The first level is the Token Ring Concentrator Relay Function (TrCRF). This is the level of VLAN to which the ports are assigned. The second level is the Token Ring Bridge Relay Function (TrBRF). This is the parent VLAN to which TrCRF VLANs are assigned. Traffic is switched between ports in a TrCRF and bridged between TrCRFs in a TrBRF.

The Catalyst 3920 maintains certain configuration information and management statistics on a per VLAN basis. Therefore, when you access VLAN-specific Catalyst 3920 configuration or management panels (such as the Current Spanning Tree Information panel), you will be prompted to specify the desired TrBRF or TrCRF.

The standard MIBs supported are:

• Management Information Base for Network Management of TCP/IP-based Internets: MIB-II (RFC 1213)
  
  
• Evolution of Interfaces Group of MIB-II (RFC 1573)
  
  
• Definitions of Managed Objects for Bridges (RFC 1493)
  
  
• Token Ring Extensions to the Managed Objects for Bridges (RFC 1525)
  
  
• IEEE 802.5 Token Ring MIB (RFC 1748)
  
  
• RMON MIB/Token Ring Extensions (RFC 1757/1513) partial support
  
  
• IEEE 802.5 DTR Concentrator MIB
  
  
• IEEE 802.5 DTR MAC MIB
  
  

The private MIBs supported are:

• Catalyst 3900 Proprietary MIB
  
  
• Cisco VLAN Trunking Protocol MIB
  
  
• Cisco Discovery Protocol MIB
  
  

Most user configurable variables are supported in either the standard MIBs or private MIBs. Configuration settings, such as port attributes, and operational information, such as address tables, are fully accessible through SNMP. Certain other settings, such as passwords and console settings, cannot be viewed or modified via SNMP for security reasons.

In typical SNMP management, the SNMP client has to continuously poll the Catalyst 3920 for fault, performance, and configuration information while waiting for the value to change. This causes increased traffic through the network. With RMON, you can have the switch monitor a particular statistic internally, and when the statistic reaches a threshold, the Catalyst 3920 will send a trap to the client. This monitoring method reduces traffic between the SNMP client and the Catalyst 3920 switch.

As an option, the Catalyst 3920 provides RMON support statistics, history, alarms, and events. It also provides support for the following groups of the Token Ring extensions to the Remote Network Monitoring MIB (RFC 1513):

• MAC-layer Statistics Group
  
  

  A collection of MAC-layer statistics kept for each Token Ring interface, such as the total number of MAC packets received and the number of times the port entered a beaconing state.

• Promiscuous Statistics Group
  
  

  A collection of promiscuous statistics kept for non-MAC packets on each Token Ring interface, such as the total number of good non-MAC frames received that were directed to an LLC broadcast address.

• Token Ring Ring Station Group
  
  

  A collection of statistics and status information associated with each Token Ring station on the local ring. In addition, this group provides status information for each ring being monitored.

• Token Ring Ring Station Order Group
  
  

  A listing of the order of stations on the monitored rings.

You can use an external RMON probe for full RMON support.

Access to RMON data is available only via an SNMP management application that supports RFC 1757 and RFC 1513. You cannot access RMON via the Catalyst 3920 console interface; however, the console statistics provide similar information. For full utilization of RMON data, you should use Cisco's TrafficDirector.

The Cisco RPS supports quasi-redundant and fully redundant configurations in the following ways:

• In a quasi-redundant configuration, the internal power supply of the Catalyst 3900 is considered the main supply. Using a one-to-one cable, you connect a single DC output of the RPS to the Catalyst 3920. The RPS continually monitors the status of the main supply. If the main supply falls below a set voltage, the RPS intervenes and begins providing power to the switch. When the Catalyst 3920 power supply is changed from the main supply to the RPS, the switch will reset.
  
  
• In a fully-redundant configuration, all power is supplied by the RPS; the internal power supply of the Catalyst 3920 is not used. Using a two-to-one cable, you connect two of the RPS DC output to the Catalyst 3920. The two-to-one cable is a Y-shaped cable with two connectors at one end of the cable and one connector at the other end. The two connectors at one end of the Y-shaped cable connect to two DC output power modules. The other end of the cable connects to one external device, such as the Catalyst 3920.
  
  

Caution If a fully-redundant configuration is used, do not connect the AC power cord to the Catalyst 3920 as this may cause damage to the Catalyst 3920 or the RPS.

This port enables attachment of a terminal or terminal emulator that is used to customize the configuration of the switch, monitor switch activity and status, and test the switch. Console access can be either local, by direct attachment to the EIA 232 port, or remote, through a modem connection.

The EIA 232 port automatically detects the baud rate of the terminal to which it is attached.