1 / 34

Network layer (2)

Kingdom of Saudi Arabia Prince Norah bint Abdul Rahman University College of Computer Since and Information System NET331. Network layer (2). T.Najah AlSubaie. IP Address. The communication at the network layer is host-to-host (Source-to-destination);

ophrah
Télécharger la présentation

Network layer (2)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Kingdom of Saudi Arabia • Prince Norah bint Abdul Rahman University • College of Computer Since and Information System • NET331 Network layer (2) T.NajahAlSubaie

  2. IP Address • The communication at the network layer is host-to-host (Source-to-destination); • The packet transmitted by the sending computer may pass through several LANs or WANs before reaching the destination computer. • For this level of communication, we need a global addressing scheme; we called this logical addressing in Chapter 2 • We use the term IP address to mean a logical address in the network layer of the TCP/IP protocol suite

  3. IP Address • The Internet addresses are 32 bits in length. • This gives us a maximum of 232 addresses. • These addresses are referred to as IP addresses. • An IP address is uniquely and universally defines the connection of a device (for example, a computer or a router) to the Internet. • Two devices on the Internet can never have the same address at the same time

  4. Address Space • An address space is the total number of addresses used by the protocol. • If a protocol uses N bits to define an address, the address space is 2N because each bit can have two different values (0 or 1) and N bits can have 2N values.

  5. Notations • There are two prevalent notations to show an IP address: binary notation and dotted-decimal notation.

  6. Binary Notation • In binary notation, the IP address is displayed as 32 bits. • Each octet is often referred to as a byte. • So it is common to hear an IP address referred to as a 32-bit address or a 4-byte address. • The following is an example of an IP address in binary notation: 01110101 10010101 00011101 00000010

  7. Dotted-Decimal Notation • To make the IP address more compact and easier to read, Internet addresses are usually written in decimal form with a decimal point (dot) separating the bytes. • The following is the dotted-decimal notation of the address (01110101 10010101 00011101 00000010) 117.149.29.2

  8. dotted-decimal notation and binary notation for an IPv4 address

  9. Example • Change the following IP addresses from binary notation to dotted-decimal notation. • 10000001 00001011 00001011 11101111 • 11000001 10000011 00011011 11111111 Solution We replace each group of 8 bits with its equivalent decimal number (see Appendix B) and add dots for separation. • 129.11.11.239 • 193.131.27.255

  10. Example • Change the following IPv4 addresses from dotted-decimal notation to binary notation. a. 111.56.45.78 b. 221.34.7.82 Solution We replace each decimal number with its binary equivalent . a. 01101111 00111000 00101101 01001110 b. 11011101 00100010 00000111 01010010

  11. Example • Find the error, if any, in the following IPv4 addresses. a. 111.56.045.78 b. 221.34.7.8.20 c. 75.45.301.14 d. 11100010.23.14.67 Solution a. There must be no leading zero (045). b. There can be no more than four numbers in an IPv4 address. c. Each number needs to be less than or equal to 255 (301 is outside this range). d. A mixture of binary notation and dotted-decimal notation is not allowed.

  12. Routing • Routing means to place the packet in its route to its destination. • Routing requires a host or a router to have a routing table. When a host has a packet to send or when a router has received a packet to be forwarded, it looks at this table to find the route to the final destination

  13. Routing • A dynamic table, is one that is updated automatically when there is a change somewhere in the internet. • For instance, they need to be updated when a router is down, and they need to be updated whenever a better route has been found.

  14. Optimization • Router is usually attached to several networks. • When it receives a packet, the decision of what network should it pass the packet is based on the optimization criteria.

  15. Optimization • Optimality can be defined by several approaches : • A cost is assigned for passing through a network. We call this cost a metric. • One protocol, allow the administrator to assign a cost for passing through a network based on the type of service required. • if maximum throughput is the desired type of service, a satellite link has a lower metric than a fiber-optic line. • On the other hand, if minimum delay is the desired type of service, a fiber-optic line has a lower metric than a satellite link. • Other protocol treat all network as equals. It is one hop count. • If packet passes through networks to reach the destination. The total cost is 10 hope counts.

  16. Routing Protocols • Routing protocols have been created in response to the demand for dynamic routing tables. • A routing protocol is a combination of rules and procedures that lets routers in the internet inform each other of changes.

  17. Routing

  18. Intra and Inter-domain Routing • An autonomous system (AS) is a group of networks and routers under the authority of a single administration. • Routing inside an autonomous system is referred to as intradomain routing. • Routing between autonomous systems is referred to as interdomain routing.

  19. Distance vector routing tables • In distance vector routing, each node shares its routing table with its immediate neighbors periodically and when there is a change. • In distance vector routing, the least-cost route between any two nodes is the route with minimum distance. • In this protocol, each node maintains a vector (table) of minimum distances to every node. • The table at each node also guides the packets to the desired node by showing the next stop in the route (next-hop routing).

  20. Distance vector routing tables

  21. Initialization of tables in distance vector routing

  22. Updating in distance vector routing

  23. Two node insatiability

  24. Link State Routing • In link state routing, if each node in the domain has the entire topology of the domain, the list of nodes and links. • The node can use Dijkstra's algorithm to build a routing table. • Each node uses the same topology to create a routing table.

  25. Concept of link state routing

  26. Link state knowledge

  27. Example of formation of shortest path tree

  28. Routing table for node A

  29. Path Vector Routing • Path vector routing proved to be useful for interdomain routing. • we assume that there is one node in each autonomous system that acts on behalf of the entire autonomous system. This nod is called a speaker node. • Only speaker nodes in each AS can communicate with each other. • A speaker node advertises the path, not the metric of the nodes

  30. Path Vector Routing • Path vector includes tow phases: • Initialization: • Each speaker node can know only the reachability of nodes inside its autonomous system. • Sharing: • A speaker in an autonomous system shares its table with immediate neighbors. • Updating • When a speaker node receives a two-column table from a neighbor, it updates its own table by: • adding the nodes that are not in its routing table • adding its own autonomous system and the autonomous system that sent the table

  31. Initial routing tables in path vector routing

  32. Stabilized tables for three autonomous systems

  33. Multicasting and Broadcasting • In multicast communication, there is one source and a group of destinations. • The relationship is one-to-many. • In this type of communication, the source address is a unicast address, but the destination address is a group address, which defines one or more destinations.

  34. Broadcasting • In broadcast communication, the relationship between the source and the destination is one-to-all. • There is only one source, but all the other hosts are the destinations.

More Related