Cisco Systems Network Router Address and Closed User Group Planning, Address Planning Overview

Page 51

C H A P T E R 3

Address and Closed User Group Planning

Proper address planning can greatly increase the performance of a PNNI WAN. Although a PNNI WAN can support almost any addressing scheme, an uncoordinated address scheme can cause excessive address advertisement and needless rerouting, both of which reduce network performance. A good addressing plan is one which is hierarchical in nature and thus summarizes simply and efficiently.

The PNNI Closed User Group (CUG) feature allows the network administrator to define user groups of ATM addresses. Once these user groups are defined, the administrator can control how users within the groups communicate with other group members and with those outside the group.

This chapter provides an address planning overview, a CUG planning overview, and general guidelines for creating an ATM address plan and a CUG plan.

Note All Cisco MGX and SES switch products ship with default addresses. These defaults are provided for lab evaluations of these products. Before the switch is deployed, Cisco Systems advises you to reconfigure the default addresses using the address plan guidelines in this chapter.

Address Planning Overview

Every route across a PNNI network is determined by two ATM End Station Addresses (AESAs), a source and a destination. When a connection is being established, the source PNNI routing node looks up the destination address in PNNI routing tables. If the routing tables do not contain a satisfactory predefined route, the switch uses the PNNI topology database to search for a route. Routing decisions are made based on many criteria as discussed in Chapter 4, “Planning Intermediate Route Selection.” This section focuses on how proper address planning can make PNNI routing more efficient.

Note The source end of a connection is also called the master end of the connection, as the master end is responsible for initiating the connection. The destination end is also called the slave end.

PNNI provides both a routing protocol and a signaling protocol. The routing protocol is used to build a topology database and create a route table of all the reachable AESAs. The signalling protocol is used to establish calls across the PNNI network. When initiating a call, the signaling protocol refers to the routing table or topology database to locate a route to the destination ATM address.

To understand the importance of an address plan, consider how PNNI would respond if there were no plan. Consider a network with 100 non-coordinated destination ATM addresses. Assume that all addresses were chosen at random. To enable access to all destinations, PNNI has to create a separate route for each of the 100 destinations, and this has to be repeated on every switch in the network.

 

 

Cisco PNNI Network Planning Guide for MGX and SES Products, Release 5

 

 

 

 

 

 

 

Part Number OL-3847-01 Rev. D0, April, 2004

 

 

3-1

 

 

 

 

 

Image 51
Contents Text Part Number OL-3847-01 Rev. D0 Corporate HeadquartersCopyright 2003, Cisco Systems, Inc All rights reserved Iii N T E N T SCompatible Standards Worksheets Part Number OL-3847-01 Rev. D0, April Vii G U R E SViii B L E S Part Number OL-3847-01 Rev. D0, April Objectives AudienceOrganization Xii ConventionsXiii DocumentationDocumentation Notes for the April 2004 Product Releases Related DocumentationXiv Technical Manual Order of UseTerms Technical Manual Titles and DescriptionsXvi Xvii Xviii Xix Reference Guides Xxi Xxii Document Title DescriptionXxiii Xxiv Xxv Xxvi Xxvii Obtaining DocumentationCisco.com Ordering DocumentationChanges to This Document Chapter ChangesXxviii Opening a TAC Case Obtaining Technical AssistanceDocumentation Feedback Cisco TAC WebsiteObtaining Additional Publications and Information TAC Case Priority DefinitionsXxx Xxxi Xxxii Pnni Network Database Introduction to PnniSingle Peer Group Topology Example Single Peer Group Topology Hierarchical Pnni Network TopologyPeer group Ppeer Simple Node Representation Peer Group LeadersSimple Node Representation Complex Node RepresentationPnni Internetworking with Aini Border NodesHierarchical Pnni Network Benefits Example Pnni Internetworking with Aini Topology Pnni Internetworking with IispPart Number OL-3847-01 Rev. D0, April Compatible Standards SpecificationsPXM45/B PXM45Capabilities PXM1ESES Capabilities SESDAX Spvc Connection Limit AdjustmentsConnection Type Switch Connections CWM Endpoints SVCInstall Redundant Hardware in Switches Parallel Links Between Adjacent SwitchesPhysical Network Planning Multiple Paths Between Network Nodes Planning Guidelines for Individual Peer GroupsMultiple Links Between Adjacent Peer Groups Multiple Links to an External NetworkPlanning Guidelines for Hierarchical Networks Planning Guidelines for Peer Group LeadersPlanning Guidelines for Border Nodes Part Number OL-3847-01 Rev. D0, April Address Planning Overview Address and Closed User Group PlanningPnni Addressing Example Selecting an ATM Address Format Planning Address Configuration SettingsESI SEL IDP DSP Supported Address FormatsGuidelines for Selecting an Address Format ATM Field Description Default ValuesDCC Selecting a Pnni LevelAddress Registration Authorities Category Type Authorities4shows an example topology of a Pnni MPG WAN Part Number OL-3847-01 Rev. D0, April Level Peer Group ID Portion of ATM Address Bytes LengthSelecting the Pnni Peer Group ID Default Peer Group ID20-byte Node Address Selecting the ATM AddressSelecting the Ilmi Address Prefix Selecting the Spvc Address PrefixPlanning Address Prefixes for Aini and Iisp Links Additional Guidelines for Creating an Address Plan Selecting Static Addresses for UNI PortsClosed User Group Example Closed User Group OverviewPlanning CUG Configuration Settings Selecting an Interlock CodeSelecting an Index Selecting CPE Addresses Selecting Internal CUG Access OptionsSpecifying a Preferential CUG Selecting External CUG Access OptionsWorksheets Selecting a Default CUG AddressCUG Part Number OL-3847-01 Rev. D0, April Administrative Weight How MGX and SES Nodes Select RoutesLink and Route Metrics Cell Transfer Delay Cell Delay VariationAvailable Cell Rate Shortest Path Table Routing Maximum Cell RateShortest Path Tables Traffic Metric Class of Service TablesService Class Acronym Definition Guidelines CTD CDVHow SPVCs and SPVPs use the SPTs How SVCs and SVPs use the SPTsHow MGX and SES Nodes Select Links On-Demand RoutingLoad Balancing for SPT and On-Demand Routing CLR0+12 Additional Routing Features in MGX and SES NodesService Preferred RoutingGrooming Priority RoutingNodal Point-to-Multipoint Branch Restriction Soft ReroutingPriority Bumping Blocking Pass-Through ConnectionsAXSM-XG AXSM/AAXSM/B AXSM-EFarthest Node Branching Part Number OL-3847-01 Rev. D0, April Ansi APS ABRAesa AiniIN-2 P2MPCBR CTDIN-3 CUGCWM DININ-4 IN-5 PGLPnni MGX SESIN-6 IN-7 UBRUNI TACIN-8