Title: CCNA Guide to Cisco Networking
1CCNA Guide to Cisco Networking
- Chapter 8 Routing Protocols and Network Address
Translation
2Objectives
- Understand the purpose and operation of network
address translation (NAT) - Configure static NAT, dynamic NAT, and dynamic
NAT with overload - Understand and configure port address translation
(PAT) - Differentiate between nonroutable, routed, and
routing protocols - Define Interior Gateway Protocols, Exterior
Gateway Protocols, distance-vector routing
protocols, and link-state routing protocols
3Objectives (continued)
- Explain the concepts of count-to-infinity, split
horizon, split horizon with poison reverse, and
hold-down timers - Describe, configure, and monitor the interior
routing protocols RIP and IGRP - Explain static routing and administrative
distance - Configure static routing and default routes
4Network Address Translation
- Static NAT
- Dynamic NAT
- Port Address Translation
- Dynamic Nat with overload
- Overlapping
5Network Address Translation (continued)
6Network Address Translation (continued)
7Network Address Translation (continued)
8Configuring Network Address Translation
- Configure static NAT
- Define static mapping between the inside address
and the outside address - Define the routers interfaces as inside or
outside - Basic NAT interface assignment
- RouterA(config) int fa 0/0
- RouterA(config-if) ip nat inside
- RouterA(config-if) int serial 0/1
- RouterA(config-if) ip nat outside
9Configuring Dynamic NAT
- Configure a standard access control list to
define what internal traffic will be translated - Define a pool of addresses to be used for dynamic
NAT allocation - Link the access list to the NAT pool
- Define interfaces as either inside or outside
10Configuring Dynamic NAT (continued)
- Dynamic NAT router configurations
- RouterA(config) access-list 1 permit 192.168.0.0
0.0.0.255 - RouterA(config) ip nat pool PoolExample
209.86.192.200 209.86.192.240 netmask
255.255.255.0 - RouterA(config) ip nat inside source list 1 pool
PoolExample - RouterA(config) int fa 0/0
- RouterA(config-if) ip nat inside
- RouterA(config-if) int serial 0/1
- RouterA(config-if) ip nat outside
11Configuring Port Address Translation To An
Outside Interface
- Configure PAT router commands
- Configure a standard access list to define what
internal traffic will be translated - Link the access list to the interface to be used
for PAT - Define interfaces as either inside or outside
12Configuring Port Address Translation To An
Outside Interface (continued)
- PAT router commands
- RouterA(config) access-list 1 permit 192.168.0.0
0.0.0.255 - RouterA(config) ip nat inside source list 1
interface serial 0/1 overload - RouterA(config) interface serial 0/1
- RouterA(config-if) ip nat outside
- RouterA(config-if) interface fa 0/0
- RouterA(config-if) ip nat inside
13Configuring Port Address Translation To An
Outside Interface (continued)
14Configuring Dynamic NAT With Overload
- Dynamic NAT with overload is a mixture of dynamic
NAT and PAT - Dynamic NAT Pool of inside addresses to a small
pool of outside addresses - PAT Same pool of inside addresses to an single
outside address - PAT function becomes available when pool of
outside addresses are all in use - Use dynamic NAT and PAT configurations using the
same pool of inside addresses
15Nonroutable Protocols
- Peer-to-peer networks
- Microsoft Windows operation systems
- NetBIOS Enhanced User Interface (NetBEUI)
- Very small
- Fast
- Efficient
- Cannot scale
16Nonroutable Protocols (continued)
17Routed Protocols
- Routed protocols
- Support networks
- Logical addresses
- Transmission Control Protocol/Internet Protocol
(TCP/IP) - Internetwork Packet Exchange/Sequence Packet
Exchange (IPX/SPX)
18Routed Protocols (continued)
19Routing Protocols
- Path determination
- Routing tables
- Metric
- Autonomous system (AS)
- Convergence
- Interior gateway protocols (IGP)
- Routing information protocol (RIP)
- Interior gateway routing protocol (IGRP)
- Enhanced Interior gateway routing protocol
(EIGRP) - Open shortest path first (OSPF)
- Exterior gateway protocols (EGP)
- Border gateway protocol (BGP)
20Routing Protocols (continued)
21Routing Protocols (continued)
22Two Types Of IGPs
- Distant vector and link-state
- Distant-vector
- Routing by rumor
- Routing loops
- Count-to-infinity
- Split horizon
- Split horizon with poison reverse
- Hold-down timers
23Two Types Of IGPs (continued)
- Link-state
- Link-state advertisements (LSA)
- Shortest path first (SPF) algorithm
- Link-state packets
- Common view of the topology
- Floods or multicasts LSPs
- Triggered updates
24Two Types Of IGPs (continued)
25Two Types Of IGPs (continued)
26Two Types Of IGPs (continued)
27Two Types Of IGPs (continued)
28Two Types Of IGPs (continued)
29Routing Information Protocol
- RIP has the following attributes
- Distance-vector routing protocol
- Maximum hop count of 15
- 16 hops is considered infinity
- Hop count is the only metric available for path
selection - Broadcasts the entire routing table to neighbors
every 30 seconds - Capable of load balancing
- Easy to configure
30Enabling RIP Routing
31Enabling RIP Routing (continued)
32Configuring RIP Routing For Each Major Network
- Design the network for the appropriate networks
- Configure interfaces to be gateways for networks
- Configure routing protocol
- In router mode establish networks to be advertised
33Configuring RIP Routing For Each Major Network
(continued)
34Configuring RIP Routing For Each Major Network
(continued)
35show ip protocol and debug ip rip (continued)
36show ip protocol and debug ip rip
(continued)
37show ip route Command
38show ip route Command (continued)
39show ip route Command (continued)
40Interior Gateway Routing Protocol
- Proprietary distance-vector routing protocol
- Supports hop count of 255
- 100 is the default hop count
- Supports up to four equal cost paths
- Routing table updates every 90 seconds
41Interior Gateway Routing Protocol (continued)
- IGRP metrics
- Hops Number of routers between source and
destination networks - Load The load on a link in the path
- Bandwidth The speed of the link (default)
- Reliability Measures reliability with a scale of
0 to 255 - Delay The delay on the medium (default)
- MTU The size of the datagram
42Interior Gateway Routing Protocol (continued)
43Interior Gateway Routing Protocol (continued)
44Interior Gateway Routing Protocol (continued)
45Interior Gateway Routing Protocol (continued)
46Static Routing
- Adding static routes
- Router(config) ip route destination
network/destination ip address next hop ip
address/forwarding interface administrative
distance - RouterD(config) ip route 172.32.3.0
255.255.255.0 172.32.2.2 - Changing administrative distance
- Default administrative distance of a static route
is - 0 if a forwarding interface is configured
- 1 if a next hop ip address is configured
- Router(config) ip route 192.168.5.0
255.255.255.0 192.168.4.2. 150
47Static Routing (continued)
48Configuring A Default Route
- Routing protocols do not behave equally with
default routes - Router(config) ip route 0.0.0.0 0.0.0.0 next
hop ip address/forwarding interface
administrative distance - Router(config) ip default-network forwarding ip
address
49Configuring A Default Route (continued)
50Summary
- NAT is a technology that allows organizations to
map valid external addresses to private or
unregistered internal addresses - This allows organizations to maintain a
separation between the Internet and the intranet
(internal network) while still providing access
to the Internet - Organizations can use NAT to allow many more
people to access the Internet by sharing one or
more valid public addresses - PAT allows an organization to map more than one
internal private IP address to a public IP address
51Summary (continued)
- Protocols vary in their functions, some protocols
are designed to be used in small networks without
the need for Network layer addressing - These protocols are described as nonroutable
protocols, the most common nonroutable protocol
is NetBEUI - Other protocols were designed with the ability to
move between multiple networks via Network layer
addressing - These protocols are routed protocols, the most
common routed protocol suite is TCP/IP
52Summary (continued)
- Protocols must be available that can find the
best path throughout an internetwork and relay
that information to routers - Routing protocols serve this function on modern
networks - Routing protocols are classed in two major
groups Interior Gateway Protocols and Exterior
Gateway Protocols - Interior Gateway Protocols are routing protocols
that function within a single autonomous system - Exterior Gateway Protocols function as routing
protocols between autonomous systems
53Summary (continued)
- Interior routing protocols are further divided
into distance-vector and link-state routing
protocols - These two types of Interior Gateway Protocols use
very different methods to determine the best path
in an internetwork - Distance-vector protocols periodically broadcast
entire routing tables to neighbor routers - Link-state protocols multicast link updates to
routers in their area upon startup and when
network topology changes - Two common distance-vector IGPs are the Routing
Information Protocol and the Interior Gateway
Routing Protocol
54Summary (continued)
- RIP is an easy-to-configure routing protocol that
uses hop count as its sole metric - RIP has a hop count limit of 15
- RIP uses split horizon, split horizon with poison
reverse, and hold-down timers to help limit
routing loops - RIP can be used on Cisco and non-Cisco routers
55Summary (continued)
- IGRP is also a distance-vector routing protocol
with maximum hop count of 255 - IGRP is not limited to using hop count as its
sole metric - IGRP can also use load, bandwidth, reliability,
and delay when determining best path - IGRP uses only bandwidth and delay by default
- IGRP is a Cisco proprietary protocol and can only
be used on Cisco routers
56Summary (continued)
- Static routes are used to conserve bandwidth and
lower memory and CPU load on a router while still
allowing for correct routing table creation - Static routes give administrators control and
flexibility in path selection in a network