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Chapter 7: Routing Dynamically
Routing & Switching

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Chapter 7
§7.1 Dynamic Routing Protocols
§7.2 Distance Vector Dynamic Routing
§7.3 RIP and RIPng Routing
§7.4 Link-State Dynamic Routing
§7.5 The Routing Table
§7.6 Summary

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Chapter 7: Objectives
§Explain the basic operation of dynamic routing protocols.
§Compare and contrast dynamic and static routing.
§Determine which networks are available during an initial network discovery phase.
§Define the different categories of routing protocols.
§Describe the process by which distance vector routing protocols learn about other networks.
§Identify the types of distance-vector routing protocols.
§Configure the RIP routing protocol.
§Configure the RIPng routing protocol.
§Explain the process by which link-state routing protocols learn about other networks.
§

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Chapter 7: Objectives (cont.)
§Describe the information sent in a link-state update.
§Describe advantages and disadvantages of using link-state routing protocols.
§Identify protocols that use the link-state routing process. (OSPF, IS-IS)
§Determine the route source, administrative distance, and metric for a given route.
§Explain the concept of a parent/child relationship in a dynamically built routing table.
§Compare the IPv4 classless route lookup process and the IPv6 lookup process.
§Analyze a routing table to determine which route will be used to forward a packet.

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Dynamic Routing Protocol Operation
The Evolution of Dynamic Routing Protocols
§Dynamic routing protocols used in networks since the late 1980s
§Newer versions support the communication based on IPv6
Routing Protocols Classification

7.1.1.1 The Evolution of Dynamic Routing Protocols

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Dynamic Routing Protocol Operation
Purpose of Dynamic Routing Protocols
§Routing Protocols are used to facilitate the exchange of routing information between routers.
§The purpose of dynamic routing protocols includes:
§Discovery of remote networks
§Maintaining up-to-date routing information
§Choosing the best path to destination networks
§Ability to find a new best path if the current path is no longer available

7.1.1.2 Purpose of Dynamic Routing Protocols

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Dynamic Routing Protocol Operation
Purpose of Dynamic Routing Protocols (cont.)
§Main components of dynamic routing protocols include:
§Data structures - Routing protocols typically use tables or databases for its operations. This
information is kept in RAM.
§Routing protocol messages - Routing protocols use various types of messages to discover
neighboring routers, exchange routing information, and other tasks to learn and maintain accurate
information about the network.
§Algorithm - Routing protocols use algorithms for facilitating routing information for best path
determination.

7.1.1.2 Purpose of Dynamic Routing Protocols (cont.)

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Dynamic Routing Protocol Operation
Purpose of Dynamic Routing Protocols (cont.)

7.1.1.2 Purpose of Dynamic Routing Protocols (cont.)

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Dynamic Routing Protocol Operation
The Role of Dynamic Routing Protocols
Advantages of dynamic routing include:
§Automatically share information about remote networks
§Determine the best path to each network and add this information to their routing tables
§Compared to static routing, dynamic routing protocols require less administrative overhead
§Help the network administrator manage the time-consuming process of configuring and maintaining
static routes
Disadvantages of dynamic routing include:
§Part of a router’s resources are dedicated for protocol operation, including CPU time and network
link bandwidth
§Times when static routing is more appropriate

7.1.1.3 The Role of Dynamic Routing Protocols

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Dynamic verses Static Routing
Using Static Routing
§Networks typically use a combination of both static and dynamic routing.
§Static routing has several primary uses:
§Providing ease of routing table maintenance in smaller networks that are not expected to grow
significantly.
§Routing to and from a stub network. A network with only one default route out and no knowledge of
any remote networks.
§Accessing a single default router. This is used to represent a path to any network that does not
have a match in the routing table.
§

7.1.2.1 Using Static Routing

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Dynamic verses Static Routing
Using Static Routing (cont.)

7.1.2.1 Using Static Routing (cont.)

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Dynamic verses Static Routing
Static Routing Scorecard

7.1.2.2 Static Routing Scorecard

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Dynamic verses Static Routing
Dynamic Routing Scorecard

7.1.2.4 Dynamic Routing Scorecard

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Routing Protocol Operating Fundamentals
Dynamic Routing Protocol Operation
§In general, the operations of a dynamic routing protocol can be described as follows:
1.The router sends and receives routing messages on its interfaces.
2.The router shares routing messages and routing information with other routers that are using the
same routing protocol.
3.Routers exchange routing information to learn about remote networks.
4.When a router detects a topology change the routing protocol can advertise this change to other
routers.

7.1.3.1 Dynamic Routing Protocol Operation

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Routing Protocol Operating Fundamentals
Cold Start
§R1 adds the 10.1.0.0 network available through interface FastEthernet 0/0 and 10.2.0.0 is
available through interface Serial 0/0/0.
§R2 adds the 10.2.0.0 network available through interface Serial 0/0/0 and 10.3.0.0 is available
through interface Serial 0/0/1.
§R3 adds the 10.3.0.0 network available through interface Serial 0/0/1 and 10.4.0.0 is available
through interface FastEthernet 0/0.
Routers running RIPv2

7.1.3.2 Cold Start

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Routing Protocol Operating Fundamentals
Network Discovery
R1:
§Sends an update about network 10.1.0.0 out the Serial0/0/0 interface
§Sends an update about network 10.2.0.0 out the FastEthernet0/0 interface
§Receives update from R2 about network 10.3.0.0 with a metric of 1
§Stores network 10.3.0.0 in the routing table with a metric of 1

Routers running RIPv2

7.1.3.3 Network Discovery

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Routing Protocol Operating Fundamentals
Network Discovery (cont.)
R2:
§Sends an update about network 10.3.0.0 out the Serial 0/0/0 interface
§Sends an update about network 10.2.0.0 out the Serial 0/0/1 interface
§Receives an update from R1 about network 10.1.0.0 with a metric of 1
§Stores network 10.1.0.0 in the routing table with a metric of 1
§Receives an update from R3 about network 10.4.0.0 with a metric of 1
§Stores network 10.4.0.0 in the routing table with a metric of 1
Routers running RIPv2

7.1.3.3 Network Discovery (cont.)

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Routing Protocol Operating Fundamentals
Network Discovery (cont.)
R3:
§Sends an update about network 10.4.0.0 out the Serial 0/0/1 interface
§Sends an update about network 10.3.0.0 out the FastEthernet0/0
§Receives an update from R2 about network 10.2.0.0 with a metric of 1
§Stores network 10.2.0.0 in the routing table with a metric of 1
Routers running RIPv2

7.1.3.3 Network Discovery (cont.)

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Routing Protocol Operating Fundamentals
Exchanging the Routing Information
R1:
§Sends an update about network 10. 1. 0. 0 out the Serial 0/0/0 interface
§Sends an update about networks 10. 2. 0. 0 and 10. 3. 0. 0 out the FastEthernet0/0 interface
§Receives an update from R2 about network 10. 4. 0. 0 with a metric of 2
§Stores network 10. 4. 0. 0 in the routing table with a metric of 2
§Same update from R2 contains information about network 10. 3. 0. 0 with a metric of 1. There is no
change; therefore, the routing information remains the same
Routers running RIPv2

7.1.3.4 Exchanging the Routing Information

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Routing Protocol Operating Fundamentals
Exchanging the Routing Information (cont.)
R2:
§Sends an update about networks 10. 3. 0. 0 and 10. 4. 0. 0 out of Serial 0/0/0 interface
§Sends an update about networks 10. 1. 0. 0 and 10. 2. 0. 0 out of Serial 0/0/1 interface
§Receives an update from R1 about network 10. 1. 0. 0. There is no change; therefore, the routing
information remains the same.
§Receives an update from R3 about network 10. 4. 0. 0. There is no change; therefore, the routing
information remains the same.
Routers running RIPv2

7.1.3.4 Exchanging the Routing Information (cont.)

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Routing Protocol Operating Fundamentals
Exchanging the Routing Information (cont.)
R3:
§Sends an update about network 10. 4. 0. 0 out the Serial 0/0/1 interface
§Sends an update about networks 10. 2. 0. 0 and 10. 3. 0. 0 out the FastEthernet0/0 interface
§Receives an update from R2 about network 10. 1. 0. 0 with a metric of 2
§Stores network 10. 1. 0. 0 in the routing table with a metric of 2
§Same update from R2 contains information about network 10. 2. 0. 0 with a metric of 1. There is no
change; therefore, the routing information remains the same.
Routers running RIPv2

7.1.3.4 Exchanging the Routing Information (cont.)

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Routing Protocol Operating Fundamentals
Achieving Convergence
The network is converged when all routers have complete and accurate information about the entire
network:
§
§Convergence time is the time it takes routers to share information, calculate best paths, and
update their routing tables.
§
§A network is not completely operable until the network has converged.

§Convergence properties include the speed of propagation of routing information and the calculation
of optimal paths. The speed of propagation refers to the amount of time it takes for routers within
the network to forward routing information.
§
§Generally, older protocols, such as RIP, are slow to converge, whereas modern protocols, such as
EIGRP and OSPF, converge more quickly.

7.1.3.5 Achieving Convergence

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Types of Routing Protocols
Classifying Routing Protocols

7.1.4.1 Classifying Routing Protocols

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Types of Routing Protocols
IGP and EGP Routing Protocols
Interior Gateway Protocols (IGP) -
§Used for routing within an AS
§Include RIP, EIGRP, OSPF, and IS-IS
Exterior Gateway Protocols (EGP) -
§Used for routing between AS
§Official routing protocol used by the Internet

7.1.4.2 IGP and EGP Routing Protocols

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Types of Routing Protocols
Distance Vector Routing Protocols
Distance vector IPv4 IGPs:
§RIPv1 - First generation legacy protocol
§RIPv2 - Simple distance vector routing protocol
§IGRP - First generation Cisco proprietary protocol (obsolete)
§EIGRP - Advanced version of distance vector routing
For R1, 172.16.3.0/24 is one hop away (distance). It can be reached through R2 (vector).

7.1.4.3 Distance Vector Routing Protocols

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Types of Routing Protocols
Distance Vector or Link-State Routing Protocols
Distance vector protocols use routers as sign posts along the path to the final destination.
A link-state routing protocol is like having a complete map of the network topology. The sign posts
along the way from source to destination are not necessary, because all link-state routers are
using an identical map of the network.  A link-state router uses the link-state information to
create a topology map and to select the best path to all destination networks in the topology.

7.1.4.3 Distance Vector Routing Protocols (cont.)

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Types of Routing Protocols
Link-State Routing Protocols
Link-state IPv4 IGPs:
§OSPF - Popular standards based routing protocol
§IS-IS - Popular in provider networks.

7.1.4.4 Link-State Routing Protocols

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Types of Routing Protocols
Classful Routing Protocols
Classful routing protocols do not send subnet mask information in their routing updates:
§Only RIPv1 and IGRP are classful.
§Created when network addresses were allocated based on classes (class A, B, or C).
§Cannot provide variable length subnet masks (VLSMs) and classless interdomain routing (CIDR).
§Create problems in discontiguous networks.

7.1.4.5 Classful Routing Protocols

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Types of Routing Protocols
Classless Routing Protocols
Classless routing protocols include subnet mask information in the routing updates:
§RIPv2, EIGRP, OSPF, and IS_IS
§Support VLSM and CIDR
§IPv6 routing protocols

7.1.4.6 Classless Routing Protocols

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Types of Routing Protocols
Routing Protocol Characteristics

7.1.4.7 Routing Protocol Characteristics

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Types of Routing Protocols
Routing Protocol Metrics
A metric is a measurable value that is assigned by the routing protocol to different routes based
on the usefulness of that route:
§Used to determine the overall “cost”  of a path from source to destination.
§Routing protocols determine the best path based on the route with the lowest cost.

7.1.4.8 Routing Protocol Metrics

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Distance Vector Routing Protocol Operation
Distance Vector Technologies
Distance vector routing protocols:
§Share updates between neighbors
§Not aware of the network topology
§Some send periodic updates to broadcast IP 255.255.255.255 even if topology has not changed
§Updates consume bandwidth and network device CPU resources
§RIPv2 and EIGRP use multicast addresses
§EIGRP will only send an update when topology has changed

7.2.1.1 Distance Vector Technologies

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Distance Vector Routing Protocol Operation
Distance Vector Algorithm
RIP uses the Bellman-Ford algorithm as its routing algorithm.
IGRP and EIGRP use the Diffusing Update Algorithm (DUAL) routing algorithm developed by Cisco.

7.2.1.2 Distance Vector Algorithm

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Types of Distance Vector Routing Protocols
Routing Information Protocol
RIPng is based on RIPv2 with a 15 hop limitation and the administrative distance of 120
Updates use UDP port 520
Routing updates broadcasted every 30 seconds

7.2.2.1 Routing Information Protocol

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Types of Distance Vector Routing Protocols
Enhanced Interior-Gateway Routing Protocol
EIGRP:
§Is bounded triggered updates
§Uses a Hello keepalives mechanism
§Maintains a topology table
§Supports rapid convergence
§Is a multiple network layer protocol support

7.2.2.2 Enhanced Interior-Gateway Routing Protocol

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Configuring the RIP Protocol
Router RIP Configuration Mode
Advertising Networks

7.3.1.1 Router RIP Configuration Mode
7.3.1.2 Advertising Networks

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Configuring the RIP Protocol
Examining Default RIP Settings

7.3.1.3 Examining Default RIP Settings

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Configuring the RIP Protocol
Enabling RIPv2

7.3.1.4 Enabling RIPv2

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Configuring the RIP Protocol
Disabling Auto Summarization
§Similarly to RIPv1, RIPv2 automatically summarizes networks at major network boundaries by
default.
§To modify the default RIPv2 behavior of automatic summarization, use the no auto-summary router
configuration mode command.
§This command has no effect when using RIPv1.
§When automatic summarization has been disabled, RIPv2 no longer summarizes networks to their
classful address at boundary routers. RIPv2 now includes all subnets and their appropriate masks in
its routing updates.
§The show ip protocols now states that automatic network summarization is not in effect.
§

7.3.1.5 Disabling Auto Summarization

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Configuring the RIP Protocol
Configuring Passive Interfaces
Sending out unneeded updates on a LAN impacts the network in three ways:
§Wasted Bandwidth
§Wasted Resources
§Security Risk

7.3.1.6 Configuring Passive Interfaces

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Configuring the RIP Protocol
Propagating a Default Route

7.3.1.7 Propagating a Default Route

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Configuring the RIPng Protocol
Advertising IPv6 Networks

7.3.2.1 Advertising IPv6 Networks

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Configuring the RIPng Protocol
Examining the RIPng Configuration

7.3.2.2 Examining the RIPng Configuration

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Configuring the RIPng Protocol
Examining the RIPng Configuration (cont.)

7.3.2.2 Examining the RIPng Configuration (cont.)

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Link-State Routing Protocol Operation
Shortest Path First Protocols

7.4.1.1 Shortest Path First Protocols

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Link-State Routing Protocol Operation
Dijkstra’s Algorithm

7.4.1.2 Dijkstra's Algorithm

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Link-State Updates
Link-State Routing Process

7.4.2.1 Link-State Routing Process

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Link-State Updates
Link and Link-State
The first step in the link-state routing process is that each router learns about its own links and
its own directly connected networks.

7.4.2.2 Link and Link-State

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Link-State Updates
Say Hello
The second step in the link-state routing process is that each router is responsible for meeting
its neighbors on directly connected networks.

7.4.2.3 Say Hello

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Link-State Updates
Say Hello
The third step in the link-state routing process is that each router builds a link-state packet
(LSP) containing the state of each directly connected link.
1.R1; Ethernet network 10.1.0.0/16; Cost 2
2.R1 -> R2; Serial point-to-point network; 10.2.0.0/16; Cost 20
3.R1 -> R3; Serial point-to-point network; 10.7.0.0/16; Cost 5
4.R1 -> R4; Serial point-to-point network; 10.4.0.0/16; Cost 20

7.4.2.4 Building the Link-State Packet

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Link-State Updates
Flooding the LSP
The fourth step in the link-state routing process is that each router floods the LSP to all
neighbors, who then store all LSPs received in a database.

7.4.2.5 Flooding the LSP

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Link-State Updates
Building the Link-State Database
The final step in the link-state routing process is that each router uses the database to construct
a complete map of the topology and computes the best path to each destination network.

7.4.2.6 Building the Link-State Database

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Link-State Updates
Building the SPF Tree

7.4.2.6 Building the Link-State Database (cont.)

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Link-State Updates
Building the SPF Tree

7.4.2.7 Building the SPF Tree

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Link-State Updates
Adding OSPF Routes to the Routing Table

7.4.2.8 Adding OSPF Routes to the Routing Table

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Why Use Link-State Routing Protocols
Why Use Link-State Protocols?

7.4.3.1 Why Use Link-State Protocols?

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Why Use Link-State Routing Protocols
Why Use Link-State Protocols?

7.4.3.1 Why Use Link-State Protocols?

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Why Use Link-State Routing Protocols
Disadvantages of Link-State Protocols

7.4.3.2 Support for Multiple Areas

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Why Use Link-State Routing Protocols
Protocols that Use Link-State
There are only two link-state routing protocols:
§Open Shortest Path First (OSPF) most popular
•began in 1987
•two current versions
•OSPFv2 - OSPF for IPv4 networks
•OSPFv3 - OSPF for IPv6 networks
§
§IS-IS was designed by International Organization for Standardization (ISO )

7.4.3.3 Protocols that Use Link-State

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Parts of an IPv4 Route Entry
Routing Table Entries

7.5.1.1 Routing Table Entries

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Parts of an IPv4 Route Entry
Directly Connected Entries

7.5.1.2 Directly Connected Entries

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Parts of an IPv4 Route Entry
Remote Network Entries

7.5.1.3 Remote Network Entries

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Dynamically Learned IPv4 Routes
Routing Table Terms
Routes are discussed
in terms of:
§Ultimate route
§Level 1 route
§Level 1 parent route
§Level 2 child routes

7.5.2.1 Routing Table Terms

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Dynamically Learned IPv4 Routes
Ultimate Route
An ultimate route is a routing table entry that contains either a next-hop IP address or an exit
interface. Directly connected, dynamically learned, and link local routes are ultimate routes.

7.5.2.2 Ultimate Route

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Dynamically Learned IPv4 Routes
Level 1 Route

7.5.2.3 Level 1 Route

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Dynamically Learned IPv4 Routes
Level 1 Parent Route

7.5.2.4 Level 1 Parent Route

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Dynamically Learned IPv4 Routes
Level 2 Child Route

7.5.2.5 Level 2 Child Route

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1.If the best match is a level 1 ultimate route, then this route is used to forward the packet.
2.If the best match is a level 1 parent route, proceed to the next step.
3.The router examines child routes (the subnet routes) of the parent route for a best match.
4.If there is a match with a level 2 child route, that subnet is used to forward the packet.
5.If there is not a match with any of the level 2 child routes, proceed to the next step.
The Routing Table
Route Lookup Process

7.5.3.1 Route Lookup Process

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6.The router continues searching level 1 supernet routes in the routing table for a match,
including the default route, if there is one.
7.If there is now a lesser match with a level 1 supernet or default routes, the router uses that
route to forward the packet.
8.If there is not a match with any route in the routing table, the router drops the packet.
The Routing Table
Route Lookup Process (cont.)

7.5.3.1 Route Lookup Process (cont.)

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The IPv4 Route Lookup Process
Best Route = Longest Match

7.5.3.2 Best Route = Longest Match

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§Components of the IPv6 routing table are very similar to the IPv4 routing table (directly
connected interfaces, static routes, and dynamically learned routes).
§IPv6 is classless by design, all routes are effectively level 1 ultimate routes. There is no level
1 parent of level 2 child routes.
The IPv4 Route Lookup Process
IPv6 Routing Table Entries

7.5.4.1 IPv6 Routing Table Entries

I suggest using the Fig 2 router output instead of the Fig 1 (on the left)

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Analyze an IPVv6 Routing Table
Directly Connected Entries

7.5.4.2 Directly Connected Entries

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Analyze an IPVv6 Routing Table
Remote IPv6 Network Entries

7.5.4.3 Remote IPv6 Network Entries

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Chapter 7: Summary
§Dynamic routing protocols:
§Used by routers to automatically learn about remote networks from other routers
§Purpose includes: discovery of remote networks, maintaining up-to-date routing information,
choosing the best path to destination networks, and ability to find a new best path if the current
path is no longer available
§Best choice for large networks but static routing is better for stub networks.
§Function to inform other routers about changes
§Can be classified as either classful or classless, distance-vector or link-state, and an interior
or an exterior gateway protocol
§

•Chapter 7 Summary

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Chapter 7: Summary (cont.)
§Dynamic routing protocols:
§A link-state routing protocol can create a complete view or topology of the network by gathering
information from all of the other routers
§Metrics are used to determine the best path or shortest path to reach a destination network
§Different routing protocols may use different  (hops, bandwidth, delay, reliability, and load)
§Show ip protocols command displays the IPv4 routing protocol settings currently configured on the
router,  for IPv6, use show ipv6 protocols
§

•Chapter 7 Summary

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Chapter 7: Summary (cont.)
§Dynamic routing protocols:
§Cisco routers use the administrative distance value to determine which routing source to use
§Each dynamic routing protocol has a unique administrative value, along with static routes and
directly connected networks, lower is preferred the route
§Directly connected networks are preferred source, followed by static routes and then various
dynamic routing protocols
§An OSPF link is an interface on a router, information about the state of the links is known as
link-states
§Link-state routing protocols apply Dijkstra’s algorithm to calculate the best path route which
uses accumulated costs along each path, from source to destination, to determine the total cost of
a route
§

•Chapter 7 Summary

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