IP address Universally accepted addressing method is required

IP address • Universally accepted addressing method is required so that all hosts can communicate with each other • TCP/IP based network is assigned with unique addresses known as IP addresses

IP address • Network layer addresses (IP addresses) are 32 bits long. • Presented as four octets in dotted decimal format. • IP address has two components: Network ID and Host ID.

IP address format

IP address classes H H H • Different class addresses reserve different amounts of bits for Network and Host portions of the address • Provide flexibility required to support different size networks

IP address classes: Class A

IP address classes: Class A • First bit of a Class A address is always 0. • First 8 bits identify network part of the address. • Possible network address from 1. 0. 0. 0 to 127. 0. 0. 0. • Remaining three octets used for the host portion of the address. • Each class A network have up to 16, 777, 214 possible IP addresses.

IP address classes: Class B

IP address classes: Class B • First 2 bits of Class B address is always 10. • First two octets identify network part of the address. • Possible network address from 128. 1. 0. 0 to 191. 254. 0. 0. • Remaining two octets used for host portion of the address. • Class B network have up to 65. 534 possible IP addresses.

IP address classes: Class C

IP address classes: Class C • First 3 bits of a Class C address is always 110. • First three octets identify network part of the address. • Possible network address from 192. 0. 1. 0 to 223. 255. 254. 0. • Remaining last octet used for host portion of the address. • Class C network have up to 254 possible IP addresses.

Binary and decimal conversion

Fast conversion

Bits on the IP address • Network Bits : – Identifies network ID – Identifies class of the IP address – All of bits are 0: not allowed • Host Bits : – Identifies host ID – All of bits are 0: reserved for network address – All of bits are 1: reserved for broadcast address

IP address classes: Summary • • • 1. 0. 0. 0 - 126. 0. 0. 0 : Class A. 127. 0. 0. 0 : Loopback network. 128. 1. 0. 0 - 191. 254. 0. 0 : Class B. 192. 0. 1. 0 - 223. 255. 254. 0 : Class C. 224. 0. 0. 0 - 239. 255: Class D, multicast. • >= 240. 0 : Class E, reserved.

Network address • provide a convenient way to refer to all of the addresses on a particular network or subnetwork. • Two hosts with differing network address require a device, typically a router, in order to communicate. • An IP address that ends with binary 0 s in all host bits is reserved for the network address.

Broadcast address • Broadcast goes to every host with a particular network ID number. • IP address that ends with binary 1 s in all host bits is reserved for the directed broadcast address. • An IP address with binary 1 s in all network bits and host bits is reserved for the local broadcast address.

Example: 172. 16. 200 • • • 172. 16. 200 is Class B address Network portion: 172. 16 Host portion: 20. 200 Network address: 172. 16. 0. 0 Broadcast address: 172. 16. 255

Private addresses • According to RFC-1918. • Organizations make use of the private Internet address space for hosts that require IP connectivity within their enterprise network, but do not require external connections to the global Internet. • Class A: 10. 0. • Class B: 172. 16. 0. 0 - 172. 31. 0. 0. • Class C: 192. 168. 0. 0 - 192. 168. 255. 0.

Reserved addresses • The bits that define the host portion of an IP address should not be all “ 1”. Any IP address with the host portion consisting of all “ 1” is interpreted as “all host”. – Example : 128. 1. 255 means all hosts on network number 128. 1

Reserved addresses • The bits that define the host portion of an IP address should not be all “ 0”. Any IP address with the host portion consisting of all “ 0” is interpreted as network address. – Example : 128. 1. 0. 0 means network number.

Reserved addresses • The bits used to define the network portion of an IP address should not be all “ 0”. A network portion address of all “ 0” is interpreted as “this network”. – Example : 0. 0. 0. 63 means Host 63 on this network.

Reserved addresses • The Class A network number 127. x. x. x is assigned as “Loop-back” function. This means that a datagram sent by a higherlevel protocol to a Network 127 address should loop back inside the host.

Review • Classes of IP address and range of IP on each class. • Determine network portion and host portion in a IP address. • Understand about broadcast addresses. • Understand about valid host address. • Binary and Decimal conversion.

Introduction to Subnetworks

What Is a Subnet? • Series of Networks within a Network • Created by subdividing Host address field and creating a Subnetwork Field • All Hosts on a Subnetwork share a common subnetwork address

Why Subnet a Network? • Provides Greater Organization of Large Networks (Class A 16 Million Hosts!) • Allows Additional Networks (subnets) without applying for additional IPs • Gives local administrators more control • Provides a Third Level of Hierarchy • Reduces the Size of Broadcast Domains

How Do You Create Subnets? • Bits are Borrowed from the Host Field – This Creates a Subnet Field in the IP address

Class C Subnets Network S H H Network H H Host H H Two Bits Borrowed from the Host Field to form a third layer of hierarchy - A Subnet Field Two Bits must always remain so a maximum of 6 Bits may be borrowed from a Class C network How many bits can be borrowed from a Class B network? From a Class A network?

Class C Subnets Network S H H Network H H Host H H The number of Subnets Created is calculated using the following formula: # Subnets Created = 2# Borrowed Bits

Class C Subnets S S H H H Borrow 2 Bits = 22 = 4 Subnets S S S H H H Borrow 3 Bits = 23 = 8 Subnets S S H H Borrow 4 Bits = 24 = 16 Subnets

Class C Subnets S S S H H H Borrow 5 Bits = 25 = 32 Subnets S S S H H Borrow 6 Bits = 26 = 64 Subnets Borrow 7 Bits = Cannot Two Host Bits Must Remain

How Many Subnets? Borrow 2 Bits = 22 = 4 Subnets • If you Borrow 2 Host Bits you do NOT get 4 Subnets. Why? • Remember the Network Address and Broadcast Address - Both of these addresses are Reserved, they cannot be used!

How Many Hosts/Subnet? Network S H H Network H H Host H H The number of Hosts per subnet is calculated using the following formula: # Hosts/Subnet = 2# Host Bits Remaining # Hosts = 26 = 64 hosts/subnet

How Many Hosts/Subnet? 6 Host Bits Remain = 26 = 64 Hosts • If there are 6 Host Bits remaining you do NOT get 64 Hosts/Subnet. Why? • Each subnetwork has its own Subnetwork Address and Broadcast Address - Both of these addresses are Reserved and cannot be used! • Thus only 62 Hosts are available.

Formulas to Remember! # Subnets Created = 2# Borrowed Bits • Remember to subtract 2 for the Network Address and Broadcast Address. # Hosts/Subnet = 2# Host Bits Remaining • Remember to subtract 2 for the Subnetwork Address and Subnetwork Broadcast Address.

Determining Network/Host ID • Given 2 IP addresses 192. 20. 1. 5. and 192. 20. 6. 8. The subnet mask is 255. 0. Determine the network address and the host address, also decide whether the message need to be send through the router.

Determining Network/Host ID 192. 20. 1. 5 = 255. 0 = Network ID = Host ID = 192. 20. 6. 8 = 255. 0 = Network ID = Host ID = 11000000. 00010100. 0000000101 11111111. 0000 11000000. 00010100. 00000001. 0000 => 192. 20. 1. 0 00000000. 00000101 => 0. 0. 0. 5 11000000. 00010100. 00000110. 00001000 11111111. 0000 11000000. 00010100. 00000110. 0000 => 192. 20. 6. 0 00000000. 00001000 => 0. 0. 0. 8

Determining Network/Host ID • Given 2 IP addresses 192. 20. 1. 5 and 192. 20. 6. 8. The subnet mask is 255. 0. 0. Determine the network address and the host address, also decide whether the message need to be send through the router.

Determining Network/Host ID 192. 20. 1. 5 255. 0. 0 Network ID = = = Host ID = 192. 20. 6. 8 255. 0. 0 Network ID = = = Host ID = 11000000. 00010100. 0000000101 11111111. 0000 11000000. 00010100. 0000 => 192. 20. 0. 0 000000001. 00000101 => 0. 0. 1. 5 11000000. 00010100. 00000110. 00001000 11111111. 0000 11000000. 00010100. 00000000 => 192. 20. 0. 0 00000000110. 00001000 => 0. 0. 6. 8

Determining Network/Host ID • Suppose a Class B IP address is 191. 20. 0. 0 and the subnet mask is 255. 224. 0. Find the number of subnet available and state the subnet addresses. How many hosts can each subnet have ?

Determining Network/Host ID 191. 20. x. x = 10111111. 00010100. xxxxxxxx 255. 224. 0 = 11111111. 11100000 Network ID = 10111111. 00010100. xxx 00000 => 191. 20. x. 0 As extra 3 bits is added into the subnet mask, we have increased the bits available for the network ID. Now, we can have 6 [(2^3) – 2 ] different Network ID.

Determining Network/Host ID 10111111. 00010100. 00100000 10111111. 000101000000 10111111. 00010100. 01100000 10111111. 00010100. 10000000 10111111. 00010100000. 0000 10111111. 00010100. 11000000 => => => Each subnet can have [2^13 – 2] = 8190 hosts. 191. 20. 32. 0 191. 20. 64. 0 191. 20. 96. 0 191. 20. 128. 0 191. 20. 160. 0 191. 20. 192. 0