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List of Figures
- Figure 1: BGP Peers
- Figure 2: Internal and External BGP
- Figure 3: Interior Gateway Protocols
- Figure 4: Routing Without CIDR
- Figure 5: Routing with CIDR
- Figure 6: Transit Service
- Figure 7: Nontransit Service
- Figure 8: IPv6 Routing over TCP IPv4
- Figure 9: IPv6 Routing over TCP IPv6
- Figure 10: Configuring Neighbors
- Figure 11: BGP Peer Groups
- Figure 12: Using EBGP-Multihop
- Figure 13: Prefixes Originating in an AS
- Figure 14: Redistributing Routes into
BGP
- Figure 15: Advertising a Default Route
- Figure 16: Setting a Static Default Route
- Figure 17: Configuring Aggregate Addresses
- Figure 18: Advertising a Route
When Another Route is Present
- Figure 19: Advertising a Route When Another Route
is Absent
- Figure 20: Advertising a Default Route When Another
Route is Present
- Figure 21: Filtering with Access Lists
- Figure 22: Filtering Routes with an Access List
- Figure 23: Filtering with AS-Path Access Lists
- Figure 24: Assigning a Filter List
- Figure 25: Route Map Filtering
- Figure 26: Communities
- Figure 27: Community Lists
- Figure 28: Configuring Next-Hop Processing
- Figure 29: Next-Hop Behavior for Broadcast Multiaccess
Media
- Figure 30: Next-Hop Behavior for Nonbroadcast Multiaccess
Media
- Figure 31: Assigning a Weight to a Neighbor Connection
- Figure 32: Configuring the Local-Preference Attribute
- Figure 33: The Origin Attribute
- Figure 34: AS-Path Attributes
- Figure 35: Configuring the MED
- Figure 36: Synchronization
- Figure 37: Disabling Synchronization
- Figure 38: Administrative Distances
- Figure 39: Administrative Distance and Synchronization
- Figure 40: Backdoor Route
- Figure 41: A Fully Meshed Autonomous System
- Figure 42: A Confederation of Subautonomous Systems
- Figure 43: Simple Route Reflection
- Figure 44: Route Reflection: Logical Redundancy
- Figure 45: Route Reflection: Physical and Logical
Redundancy
- Figure 46: BGP Route Reflection
- Figure 47: Simple MPLS Domain
- Figure 48: Label Switching
- Figure 49: Label Stacking
- Figure 50: Shim Header
- Figure 51: TTL Processing on Incoming MPLS Packets
- Figure 52: TTL Processing on Outgoing MPLS Packets
- Figure 53: LSP Creation, Downstream-on-Demand, Ordered
Control
- Figure 54: LSP Creation, Downstream-Unsolicited,
Independent Control
- Figure 55: Explicit Routing in an MPLS Domain
- Figure 56: MPLS Interface Stacking for the Platform
Label Space
- Figure 57: MPLS Interface Stacking for the Interface Label
Space
- Figure 58: LDP Tunneled Through an RSVP-TE Core
- Figure 59: Simple MPLS Domain
- Figure 60: FEC Aggregation and Equal-Cost Paths
- Figure 61: Bypass Tunnel
- Figure 62: Flow for Initial Setting of EXP Bits
for the First Label Pushed
- Figure 63: Flow for Setting EXP Bits for All Pushed
Labels
- Figure 64: Differentiated Services over an MPLS
Network
- Figure 65: Associations Between PHB ID, EXP Bits,
and Traffic Classes/Colors
- Figure 66: Signaled Mapping
- Figure 67: Sample MPLS L3VPN Topology
- Figure 68: ECMP BGP/MPLS VPN Scenario
- Figure 69: BGP/MPLS VPN Scenario
- Figure 70: BGP/MPLS VPN Components
- Figure 71: Route and Label Distribution
- Figure 72: Standard and Extended BGP Update Messages
- Figure 73: BGP/MPLS VPN Route Exchange
- Figure 74: LSP Creation for BGP/MPLS VPN
- Figure 75: Traffic Across the MPLS Backbone of a
BGP/MPLS VPN
- Figure 76: IPv6 VPN Services over IPv4 MPLS
- Figure 77: Inter-AS Topology with VRFs on Each AS
Boundary Router
- Figure 78: Inter-AS Topology with End-to-End Stacked
MPLS Tunnels
- Figure 79: Topology for Three-label Stack Configuration
for Inter-AS Option C
- Figure 80: Topology for Inter-AS Option C with Route
Reflectors
- Figure 81: Inter-AS IPv6 VPN Services
- Figure 82: Site Connectivity in a Full-Mesh VPN
- Figure 83: Route Target Configuration for a Full-Mesh
VPN
- Figure 84: Site Connectivity in a Hub-and-Spoke
VPN
- Figure 85: Route Target Configuration for a Hub-and-Spoke
VPN
- Figure 86: Site Connectivity in an Overlapping VPN
- Figure 87: Route Target Configuration for an Overlapping
VPN
- Figure 88: Overlapping VPNs on a Single PE
- Figure 89: Fully Meshed VPNs
- Figure 90: Hub-and-Spoke VPN
- Figure 91: Import and Export Maps
- Figure 92: Configuring Static Routes
- Figure 93: BGP/MPLS VPN IBGP Example
- Figure 94: BGP/MPLS VPN EIBGP Example
- Figure 95: PE-to-CE Session
- Figure 96: Network with Potential Routing Loops
- Figure 97: Preventing Potential Routing
Loops in the Network
- Figure 98: Allowing Local AS in VPNv4 Address Family
- Figure 99: Topology for Fast Reconvergence by Means
of Unique VRF RDs, Before Tunnels Go Down
- Figure 100: Topology for Fast Reconvergence by Means
of Reachability Checking, After Tunnels Go Down
- Figure 101: Static Default Route for Internet Access
- Figure 102: Fallback Global Option
- Figure 103: Global Import Map Applied to Routes Imported
from VRF BGP RIB
- Figure 104: BGP Session Between CE Router and Parent
VR
- Figure 105: Static Route to Shared IP Interface
- Figure 106: Global Export Map Applied to Routes Exported
from VRF BGP RIB
- Figure 107: Carrier-of-Carriers Internet Service
- Figure 108: Carrier-of-Carriers VPN Service
- Figure 109: Carrier-of-Carrier IPv6 VPNs
- Figure 110: IPv6 Tunneled over MPLS-IPv4
- Figure 111: IPv6 Tunneled Across IPv4 Domains
- Figure 112: OSPF Topology with Backdoor Link
- Figure 113: OSPF Sham Link
- Figure 114: Layer 2 Services over a Provider’s
MPLS Network
- Figure 115: Common ISP Network
- Figure 116: E-series Router Replacing Remote ATM
Switch
- Figure 117: AAL5 Pseudowire and MPLS Tunnel
- Figure 118: CE-Side MPLS L2VPN
Tunnel over LAG
- Figure 119: Local Cross-Connect Between Ethernet/VLAN
Interfaces
- Figure 120: CE-Side Load-Balancing Topology
- Figure 121: Sample Frame Relay over MPLS Configuration
- Figure 122: MPLS L2VPN Tunnel over VLAN over LAG Configuration Example
- Figure 123: MPLS L2VPN
Tunnel over LAG Configuration Example
- Figure 124: MPLS L2VPN Tunnel
over LAG Configuration Example
- Figure 125: Ethernet Packet
Distribution over Martini Circuits
- Figure 126: Martini Circuit with
Two Pseudowires Between PE-Facing Routers
- Figure 127: VPLS Sample Topology
- Figure 128: Topology for VPLS Configuration Example
with BGP Signaling
- Figure 129: Topology for VPLS Configuration Example
with LDP Signaling
- Figure 130: VPWS Sample Topology
- Figure 131: VPWS Components
- Figure 132: VPWS Cross-Connects
- Figure 133: Topology for VPWS Configuration Example
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