Cisco Systems CRS-1 manual Show controllers switch inter-rack stp location node-id

Page 34

Chapter 2 Converting to an Integrated Switch System

How to Convert from the Cisco Catalyst 65xx Switch to the Integrated Switch System for Single-FCC Multishelf and

Two-FCC Multishelf Systems

Replace the interface number argument with the port that is connected to the active Cat6k.

Replace the node-idargument with the newly inserted standby 22-port SCGE card.

The following example sample output displays information for STP from the show controllers switch inter-rack stp command:

RP/0/RP0/CPU0:router(admin)# show controllers switch inter-rack stp ports 0 location

GE_0 of MST1 is designated forwarding

 

 

 

Edge port:

no

 

(default)

port guard :

none

(default)

Link type: point-to-point

 

(auto)

bpdu filter: disable

(default)

Boundary : internal

 

 

 

bpdu guard : disable

(default)

Bpdus (MRecords) sent 204605, received 8

 

 

 

Instance Role Sts Cost

 

Prio.Nbr Vlans

mapped

 

 

-------- ---- --- --------- -------- -------------------------------

 

1 Desg FWD

20000 128.

1 1

 

 

 

For the 22-port SCGE ports which are connected to each other, one is in the forwarding state and the other is in the blocked state.

Transferring the Backup Cisco Catalyst 65xx Switch Gigabit Ethernet Connections to a Standby 22-port SCGE (Single-FCC Multishelf and Two-FCC Multishelf Systems)

To transfer the backup Cisco Catalyst 65xx switch GE connections to a standby 22-port SCGE card and to isolate the backup Cisco Catalyst 65xx switch from the control network, perform the following steps:

Step 1 Shut down the ports on the backup Cat6K one at a time. Make the interCat6K port the last port to shut down.

Step 2 Move the disabled GE connections between the active RPs (on both the LCC in case of a 2 FCC MC) and the backup Cat6K to the standby 22-port SCGE.

Step 3 Use the show controllers switch stp command, with the location keyword, in administration EXEC mode, to verify that the RP ports (GE1) that are connected to the 22-port SCGE are in the blocked state, and that the RP ports (GE0) that are connected to an active Cat6K are in the forwarding state, as shown in the following syntax:

show controllers switch inter-rack stp location node-id

Replace the node-idargument with the location of the 22-port SCGE card. In addition, you can use the newly inserted standby 22-port SCGE card.

Cisco CRS-1 Carrier Routing System Multishelf System Upgrade and Conversion Guide

2-6

OL-12571-01

 

 

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Contents Americas Headquarters Page N T E N T S Index Obtaining Documentation Changes to This DocumentCisco.com Cisco Product Security Overview Documentation FeedbackProduct Documentation DVD Ordering Documentation Reporting Security Problems in Cisco Products Product Alerts and Field NoticesObtaining Technical Assistance Cisco Technical Support & Documentation WebsiteDefinitions of Service Request Severity Submitting a Service RequestObtaining Additional Publications and Information Preface Obtaining Additional Publications and Information Contents Prerequisites for Upgrading to a Multishelf SystemRestrictions for Upgrading to a Multishelf System Multishelf System section onHow to Upgrade to a Multishelf System Information About Upgrading to a Multishelf SystemUpgrading the Fabric Cards and Adding an FCC NoneAll commands listed in this procedure should be Apply power to the FCCPlaces the router in administration Exec mode Places the router in administration configuration modeEnter this command sequence for each of the eight Configures the FCC identified by the serial number as anConfigures a plane to operate in an FCC slot To 7 you want to configureExamine Do command prefix allows the Exec mode showCommand to execute in administration configuration Replace the planeNumber parameter with the numberDisplays the administrative and operational status of all Modifies the target configuration to bring up the specifiedWhich is now configured to use the FCC-SFC Displays the status of the Rack 0 fabric slot specified byAdding an LCC to a Multishelf System What to Do NextConfiguration to installation mode Configures the additional LCC as Rack 1 in the multishelfModifies the target configuration to change the Rack For racks in installation modeDisplaying Chassis Serial Numbers Example Adding a Fabric Card Chassis Example Power is applied to the FCC at this time FC/S card is replaced with an FC/M card at this point Fabric cable is attached to the FC/M card at this pointApply power, attach cables, and check cable LEDs Adding an LCC to a Multishelf System ExampleNormal Additional References Where to Go NextRelated Documents Related Documentation for the Catalyst 6509 Switch Technical AssistanceConverting to an Integrated Switch System Prerequisites for the Integrated Switch System Cisco CRS-1 Multishelf Integrated Switch Solution Naming ConventionsThis section contains the following procedures Repeat to for the remaining FCC Partner node F0/SC1/CPU0 is in Standby roleShow controllers switch inter-rack stp location node-id Redundancy switchover location node-id Repeat to for the other fabric chassis on a two-FCC MC MST1 Validating the 22-port Scge Cards Four-FCC Multishelf System OL-12571-01 OL-12571-01 For Cist Redundancy switchover location node-id Show controllers switch inter-rack udld all location node-id Show controllers switch inter-rack udld all location node-id Serial number configuration Admin configure command 1-5,1-10Installation documents LEDs Fabric card, single-chassis systemIN-2
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CRS-1 specifications

Cisco Systems' Carrier Routing System (CRS-1) is a cutting-edge, high-capacity router designed to meet the demands of service providers and large enterprises. Introduced in the early 2000s, the CRS-1 represents a significant leap forward in routing technology, offering unparalleled performance, scalability, and reliability.

One of the primary features of the CRS-1 is its exceptional scalability. The system is built on a modular architecture that allows for easy upgrades and expansions. This enables service providers to start with a configuration that suits their immediate needs while having the flexibility to expand as traffic demands grow. The CRS-1 supports a wide range of line cards, enabling data, voice, and video to be managed on a single platform, which simplifies network management and reduces operating costs.

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Another key characteristic of the CRS-1 is its strong focus on reliability and redundancy. The system is designed with high availability in mind, ensuring that it can continue to operate seamlessly even in the event of hardware failures. Redundant components, such as power supplies and route processors, allow the CRS-1 to maintain its performance and uptime, a critical requirement for mission-critical network operations.

Additionally, the CRS-1 supports a wide variety of protocols and technologies, including Internet Protocol (IP), Multiprotocol Label Switching (MPLS), and various service provider features. This versatility makes it a compelling choice for organizations looking to implement advanced networking capabilities, such as Quality of Service (QoS) and traffic engineering.

In summary, the Cisco Systems CRS-1 stands out as a formidable solution for modern routing needs. Its modular design, exceptional scalability, robust performance, reliability, and support for multiple protocols and services make it an ideal choice for service providers and enterprises seeking to future-proof their networks. As the demand for bandwidth continues to surge, the CRS-1 remains a pivotal component in the evolution of networking infrastructure.