Introduction

1. Introduction Chapter 1

2. Metropolitan Area Networks • A metropolitan area network based on cable TV.

3. Wide Area Networks • Relation between hosts on LANs and the subnet.

4. Wide Area Networks (2) • A stream of packets from sender to receiver.

5. Wireless Networks • Categories of wireless networks: • System interconnection • Wireless LANs • Wireless WANs

6. Wireless Networks (2) • (a) Bluetooth configuration • (b) Wireless LAN

7. Wireless Networks (3) • (a) Individual mobile computers • (b) A flying LAN

8. Home Network Categories • Computers (desktop PC, PDA, shared peripherals • Entertainment (TV, DVD, VCR, camera, stereo, MP3) • Telecomm (telephone, cell phone, intercom, fax) • Appliances (microwave, fridge, clock, furnace, airco) • Telemetry (utility meter, burglar alarm, babycam).

9. Network Software • Protocol Hierarchies • Design Issues for the Layers • Connection-Oriented and Connectionless Services • Service Primitives • The Relationship of Services to Protocols

10. Network SoftwareProtocol Hierarchies • Layers, protocols, and interfaces.

11. Protocol Hierarchies (2) • The philosopher-translator-secretary architecture.

12. Protocol Hierarchies (3) • Example information flow supporting virtual communication in layer 5.

13. Connection-Oriented and Connectionless Services • Six different types of service.

14. Service Primitives • Five service primitives for implementing a simple connection-oriented service.

15. Service Primitives (2) • Packets sent in a simple client-server interaction on a connection-oriented network.

16. Services to Protocols Relationship • The relationship between a service and a protocol.

17. Reference Models • The OSI Reference Model • The TCP/IP Reference Model • A Comparison of OSI and TCP/IP • A Critique of the OSI Model and Protocols • A Critique of the TCP/IP Reference Model

18. OSI Reference model : • The Open System Interconnection (OSI) Reference Model is a description for layered communications and computer network protocol design. It was developed as part of the Open Systems Interconnection (OSI) initiative. It divides network architecture into seven layers which are, from top to bottom, the Application, Presentation, Session, Transport, Network, Data-Link, and Physical Layers. It is therefore often referred to as the OSI Seven Layer Model. • A layer is a collection of similar functions that provide services to the layer above it and receives service from the layer below it. • On each layer an instance provides services to the instances at the layer above and requests service from the layer below.

19. Why do we need the OSI Model? To address the problem of networks increasing in size and in number, the International Organization for Standardization (ISO) researched many network schemes and recognized that there was a need to create a network model that would help network builders implement networks that could communicate and work together and therefore, released the OSI reference model in 1984. 19

21. Reference Models The OSI reference model.

22. Layer 7: Application Layer • the application layer provides services for an application program to ensure that effective communication with another application program in a network is possible. It is a service layer that provides these services: • Allows applications to use the network. • Message authenticates either the message sender or receiver or both • Makes sure that necessary communication resources exist • Determines protocol and data syntax rules at the application level • Interface between the user & the computer (applications & Gateways). Provides services that directly support user applications, such as the USER INTERFACE, E-MAIL, FILE TRANSFER, TERMINAL EMULATION, DATABASE ACCESS. • Handles Network access, flow control & error recovery. • Messages are sent between layers.

23. Layer 7 - The Application Layer This layer deal with networking applications. Examples:  Email  Web browsers PDU - User Data 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

24. Layer 6: Presentation Layer • The Presentation Layer enables translation between Application Layer entities, in which the higher-layer entities can use different syntax and semantics, as long as the Presentation Service understands both and the mapping between them. • This layer formats and encrypts data to be sent across a network. • The presentation service data units are then encapsulated into Session Protocol Data Units, and moved to the lower layers. • Translation of data into understandable format for transmission (into a form usable by the application layer i.e. translates data between the formats the network requires and the computer expects). • Handles character encoding, bit order and byte order issues. Encodes and decodes data. • Data compression and encryption takes place at this layer. • Generally determines the structure of data • The redirector works at this layer. • Responsible for protocol conversion

25. Layer 6 - The Presentation Layer This layer is responsible for presenting the data in the required format which may include:  Encryption  Compression PDU - Formatted Data 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

26. Layer 5: Session Layer • The Session layer controls the dialogues (connections) between computers. It establishes, manages and terminates the connections between the local and remote application. It provides for full-duplex, half-duplex, or simplex operation. • Provides synchronization between communicating computers (nodes), messages are sent between layers (i.e. Manages upper layer errors). • Places checkpoints in the data flow, so that if transmission fails, only the data after the last checkpoint needs to be retransmitted.

27. Layer 5 - The Session Layer This layer establishes, manages, and terminates sessions between two communicating hosts. Example:  Client Software ( Used for logging in) PDU - Formatted Data 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

28. Layer 4: Transport Layer • The Transport Layer provides transparent transfer of data between end users, providing reliable data transfer services to the upper layers. • Responsible for PACKET HANDLING. Ensures error free delivery. Repackages messages, divides messages into smaller packets (Fragments and reassembles data), and handles error handling • Ensures proper sequencing and without loss and duplication. • Takes action to correct faulty transmissions • Controls flow of data • Acknowledges successful receipt of data • Sliding window is at this Layer -segments of message fragments are sent between layers • TCP - connection oriented communication for applications to ensure error free delivery. • UDP- connectionless communications and does not guarantee packet delivery between transfer points

29. Layer 4 - The Transport Layer This layer breaks up the data from the sending host and then reassembles it in the receiver. It also is used to insure reliable data transport across the network. PDU - Segments 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

30. Layer 3: Network Layer • The Network Layer provides the functional and procedural means of transferring variable length data sequences from a source to a destination via one or more networks. The Network Layer performs network routing functions, and might also perform fragmentation and reassembly, and report delivery errors. • A well known example of the network layer protocol is the Internet Protocol (IP). • Logical addressing - software addresses to hardware addresses are resolved (ARP/RARP). • Determining the best route (Makes routing decisions & forwards packets. • Layer 2: Data Link Layer • The Data Link Layer provides the functional and procedural means to transfer data between network entities and to detect and correct errors that may occur in the Physical Layer • Data link layer arrange bits, from the Physical Layer, into logical sequences called frames.

31. Layer 3 - The Network Layer Sometimes referred to as the “Cisco Layer”. Makes “Best Path Determination” decisions based on logical addresses (usually IP addresses). PDU - Packets 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

32. Layer 2 - The Data Link Layer This layer provides reliable transit of data across a physical link. Makes decisions based on physical addresses (usually MAC addresses). PDU - Frames 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

33. Layer 1: Physical Layer • The Physical Layer defines the electrical and physical specifications for devices. This includes the layout of pins, voltages, cable specifications, Hubs, repeaters, network adapters, and more. • The Physical Layer will tell one device how to transmit to the communication medium, and another device how to receive from it • The major functions and services of the Physical Layer are: • Establishment and termination of a connection to a communications medium. • Flow control. • Modulation (conversion between the representation of digital data) .These are signals operating over the physical cabling (such as copper and optical fiber) or over a radio link

34. Layer 1 - The Physical Layer This is the physical media through which the data, represented as electronic signals, is sent from the source host to the destination host. Examples:  CAT5 (what we have)  Coaxial (like cable TV)  Fiber optic PDU - Bits 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical

35. Host Layers These layers only exist in the source and destination host computers. 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical 35

36. Media Layers These layers manage the information out in the LAN or WAN between the source and destination hosts. 7 Application 6 Presentation 5 Session 4 Transport 3 Network 2 Data Link 1 Physical 36

37. The OSI Layers Communications 37