Title: Switches
1(No Transcript)
2Switches Routers
3Section Objectives
- Overview of Switches and Routers in a Network
Environment - Switch Configuration
- Routing Basics and Configuration
- Displaying Router Information
- Troubleshooting Routers and Switches
4Layer 3 (IP) Basics
- Provides ability to address devices with a
logical address and route traffic not locally
attached - Logical addresses are applied to source and
destination nodes or devices - Paths are determined to forward data from a local
device to a remote device on another network
5Router Functionality
Network A
Network B
e1
e0
Routing Table Network A e0 Network B e1
Routers Separate Broadcast Domains
6Why a Logical Address
- Hierarchical addresses provide reachability
across boundaries called subnets - Similar to the phone system with area codes to
differentiate geographical regions or zip codes
to indicate different cities and towns - A hierarchical logical computer address contains
a network identifier and host or unit identifier
7Network Segments
- The size of a network dictates traffic load and
potential for overload - As growth overwhelms a network (similar to cars
crowding a highway), segments can be created to
off load traffic - Each new segment is autonomous of other network
segments - Without segmentation, all addressing would be
done through a flat addressing scheme (MAC
addressing) overwhelming segmentation discovery
devices (routers)
8Connectivity Between Segments
- Segments can communicate through devices that
determine a path from one network to another over
communications lines - Devices (routers) can determine the best path in
the case of multiple paths - Paths or routes are stored in routing tables
172.16.0.0/24 is subnetted, 1 subnets C
172.16.1.0 is directly connected,
Ethernet0 10.0.0.0/24 is subnetted, 2
subnets R 10.2.2.0 120/1 via
10.1.1.2, 000007, Serial2 C
10.1.1.0 is directly connected, Serial2 R
192.168.1.0/24 120/2 via 10.1.1.2, 000007,
Serial2
Portion of a Routing Table
9Network Layer Addressing
- Routers use a portion of the address to
determination Network identification - All hosts or devices within a given network
segment are identified by a host portion of the
address - IP Addresses 172.16.10.100
Network ID
Host ID
10Path Determination
- Network layer determines BEST path from source to
destination - A router examines reported paths over links,
determining best path from metrics associated
with each path
Best Path
11IP Header Detail
Version 4
Header Length 4
Type of Service 8
Total Length 16
Identification 16
Flags 3
Fragment Offset 13
Time to Live 8
Protocol (Upper Level) 8
Header Checksum 16
Source IP Address 32
Destination IP Address 32
IP Options Variable
Data
Padding (If Needed)
12IP Address Numbering
- IP Addresses are 32 bits in length
Network
Host
.
.
.
172
16
122
204
10101100
00010000
01111010
11001100
Each Octet is 8 bits in length, representing a
byte
13Converting IP Addresses from Binary to Decimal
Note All 0s indicates a decimal 0, totaling 256
Decimal Values
14Conversion Example
128 32 16 4 1 181
15IP Classes
Class A
Class B
Class C
- Network numbers are assigned by ARIN - Host
numbers assigned by Network Administrators
16Class A Notes
- Address range 1 to 126
- Address 10 is reserved as a private address
- Address 127 is reserved for loopback purposes
- First bit begins with a 0 (zero)
0
17Class B Notes
- Address range 128 to 191
- Address 172.16 to 172.31 is reserved as a private
address range - First two bits begin with a 10
10
18Class C Notes
- Address range 192 to 223
- Address 192.168 is reserved as a private address
range - First three bits begin with a 110
110
19Reserved Address Space
- 0s (zeros) in the host portion of the address
space is reserved for the network number - Example 172.16.0.0
- 1s in the host portion of the address is reserved
for the broadcast address - Example 172.16.255.255
20A Case for Subnetting
- The original IP addressing scheme was sufficient
for the early days of the internetworking
environment - As the Internet grew in the 1990s, addressing,
using classful addressing became impractical - Subnetting (classless) addressing became the
answer for address space depletion
21Subnetting
- Subnetting borrows host bits to increase the
number of networks - The number of hosts is reduced in proportion to
the number of bits borrowed
22A Subnetted Network
172.16.3.0
172.16.4.0
172.16.5.0
172.16.1.0
172.16.2.0
Original Network 172.16.0.0
23Subnet Mask without Subnets
Network
Host
172.16.2.160
10101100
00010000
10100000
00000010
11111111
11111111
00000000
00000000
255.255.0.0
00000000
00000000
10101100
00010000
Subnet Mask
NetworkNumber
16
172
0
0
- Subnets not in usethe default
24Subnet Mask with Subnets
Network
Subnet
Host
172.16.2.160
10101100
00010000
10100000
00000010
11111111
11111111
00000000
11111111
255.255.255.0
10101100
00010000
00000010
00000000
128 192 224 240 248 252 254 255
NetworkNumber
16
172
2
0
- Network number extended by eight bits
25 Defining a Subnet Mask
Convert the Number of Segments to Binary Count
the Number of Required Bits Convert the Required
Number of Bits to Decimal (High Order)
1
2
3
Example of Class B Address
6
Number of Subnets
0 0 0 0 0 1 1 0
(3 Bits)
Binary Value
6
42
Convert to Decimal
11111111 11111111 11100000 00000000
255 . 255 . 224 . 0
Subnet Mask
Ignore the first bit borrowed, add the additional
bits borrowed to determine the number of new
subnets
26 Defining Subnet IDs
255
255
224
0
1
1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1
1 1 1 0 0 0 0 0
0 0 0 0 0 0 0 0
00000000 0 00100000 32 01000000 64 01100000
96 10000000 128 10100000 160 11000000
192 11100000 224
Evaluate the bit patterns established within the
subnetted region
2
3
27Shortcut to Defining Subnet IDs
11000000
1
List the Number of Bits (High Order) Used for
Subnet Mask Convert the Bit with the Lowest
Value to Decimal Increment the Value for Each Bit
Combination
64
2
3
0 64 64 64 128 64 192
w.x.64.1
w.x.127.254
w.x.128.1
w.x.191.254
28Defining Host IDs for a Subnet
Subnet IDs
Host ID Range
Invalid x.y.32.1 x.y.63.254 x.y.64.1
x.y.95.254 x.y.96.1 x.y.127.254 x.y.128.1
x.y.159.254 x.y.160.1 x.y.191.254 x.y.192.1
x.y.223.254 Invalid
- Each Subnet ID Indicates the Beginning Value in a
Host Range - The Ending Value Is One Less Than the Beginning
Value of the Next Subnet ID
29Network to Network Connectivity
- Router strips off the data link header
- Examines the network layer address
- Consults the routing table to find the
interface for the network
1
2
3
30Network-Layer Protocol Operations
X
Y
C
A
B
A
B
C
Each router provides its services to support
upper-layer functions
31Routed Versus Routing Protocols
- Routed Protocols Any network protocol run on a
workstation as a part of the network operating
system that provides networking capabilities (Ex
TCP/IP) - Routing Protocols Protocols run on a router to
provide the ability for the router to share path
information (Ex RIP, IGRP)
32Routing Protocols
- Interior Routing Protocols support the sharing
of routes or paths within the internal
internetwork - (Ex RIP, IGRP, EIGRP, OSPF)
- Exterior Routing Protocols support the sharing
of routes or paths across large internetworks,
such as the Internet - (Ex BGP and EGP)
33Routing Metrics
- All routing protocols utilize metrics to
characterize best path information - Hop Count
- Bandwidth
- Delay
- Load
- Reliability
- Ticks (Novell)
- Cost generic definition of metric information
34Static versus Dynamic Routes
- Static routes are established by a network
administrator and manually input directly into
the routing table - Dynamic routes are learned through the use of a
Routing Protocol. Dynamic routes are adaptive.
Changes to path availability or establishment of
new paths are automatically shared with other
routers
35Routers
- A Router is a computer, with similar
functionality - Forwards packets, from incoming interface to
outgoing interfaced, based on best path as
determined by routes available in the routers
Routing Table - Segments a LAN into separate Broadcast Domains
- Must be used when connecting LANs across wide
area network environment
36Typical Router System Board Layout
Polarization Notch
Memory Types RAM/DRAM NVRAM Flash
Memory ROM
37Typical Cisco Motherboard for a 2500 Series
38Sources For Configuring
VTY 0 - 4
Interfaces
Console Port
Auxiliary Port
TFTP Server
Network Management Station
Dial-in Access with modems
39Router and Switch Configuration