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Communicating over the Network

Communicating over the Network. Network Fundamentals – Chapter 2. Objectives. Describe the structure of a network, including the devices and media that are necessary for successful communications. Explain the function of protocols in network communications.

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Communicating over the Network

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  1. Communicating over the Network Network Fundamentals – Chapter 2

  2. Objectives • Describe the structure of a network, including the devices and media that are necessary for successful communications. • Explain the function of protocols in network communications. • Explain the advantages of using a layered model to describe network functionality. • Describe the role of each layer in two recognized network models: The TCP/IP model and the OSI model. • Describe the importance of addressing and naming schemes in network communications.

  3. Network Structure • The elements of communication • 3 common elements of communication • Message source • The channel • Message destination • A network: the definition • Data or information networks capable of carrying many different types of communications

  4. Network Structure • How messages are communicated? • Data is sent across a network in small “chunks” called segments

  5. Network Structure • The components of a network • Network components • Hardware • Software

  6. Network Structure • End Devices and their Role in the Network • End devices form interface with human network & communications network • Role of end devices: • Client • Server • Both client and server

  7. Network Structure • Role of an intermediary device • Provides connectivity and ensures data flows across network

  8. Network Structure • Network media • Criteria for making a network media choice • Network media – this is the channel over which a message travels

  9. Network Types • Local Area Networks (LANs) • A network serving a home, building or campus is considered a Local Area Network (LAN)

  10. Network Types • Wide Area Networks (WANs) • LANs separated by geographic distance are connected by a network known as a Wide Area Network (WAN)

  11. Network Types • The Internet • The internet is defined as a global mesh of interconnected networks

  12. Network Topology • Star Topology • Ring Topology • Bus Topology • Tree Topology • Mesh Topology • Hybrid Topology • http://www.edrawsoft.com/Network-Topologies.php

  13. Network Types • Network representations

  14. Function of Protocol in Network Communication • Protocols • A protocol is a set of predetermined rules • used to facilitate communication over data networks

  15. Function of Protocol in Network Communication • Network protocols • Network protocols are used to allow devices to communicate successfully

  16. Function of Protocol in Network Communication • Protocol suites and industry standards • A standard is a process or protocol that has been endorsed by the networking industry and ratified by a standards organization

  17. Function of Protocol in Network Communication • Protocolsand how they interact • Ethernet • Local Talk • Token Ring • FDDI • ATM • http://www.edrawsoft.com/Network-Protocol.php

  18. Function of Protocol in Network Communication • Technology independent Protocols • Many diverse types of devices can communicate using the same sets of protocols • This is because protocols specify network functionality, not the underlying technology to support this functionality

  19. Layers with TCP/IP and OSI Model • Benefits of using a layered model • Benefits include • Assists in protocol design • Fosters competition • Changes in one layer do not affect other layers • Provides a common language

  20. Layers with TCP/IP and OSI Model • TCP/IP Model

  21. Layers with TCP/IP and OSI Model • The Communication Process

  22. Layers with TCP/IP and OSI Model • Protocol data units (PDU) and encapsulation PDU

  23. Layers with TCP/IP and OSI Model • The process of sending and receiving messages TCP is one of the main protocols in TCP/IP networks. Whereas the IP protocol deals only with packets, TCP enables two hosts to establish a connection and exchange streams of data. TCP guarantees delivery of data and also guarantees that packets will be delivered in the same order in which they were sent.

  24. Layers with TCP/IP and OSI Model • Protocol and reference models • A protocol model provides a model that closely matches the structure of a particular protocol suite • A reference model provides a common reference for maintaining consistency within all types of network protocols and services

  25. Layers with TCP/IP and OSI Model • OSI

  26. The sending process passes data to the application layer. The application layer attaches an application header and then passes the frame to the presentation layer. • The presentation layer can transform data in various ways, if necessary, such as by translating it and adding a header. It gives the result to the session layer. The presentation layer is not aware of which portion (if any) of the data received from the application layer is the application header and which portion is actually user data, because that information is irrelevant to the presentation layer's role. • The process of adding headers is repeated from layer to layer until the frame reaches the data link layer. There, in addition to a data-link header, a data-link trailer is added. The data-link trailer contains a checksum and padding if needed. This aids in frame synchronization. The frame is passed down to the physical layer, where it is transmitted to the receiving computer. • On the receiving computer, the various headers and the data trailer are stripped off one by one as the frame ascends the layers and finally reaches the receiving process.

  27. Layers with TCP/IP and OSI Model • OSI and TCP/IP model

  28. Addressing and Naming Schemes • Labels in encapsulation headers are used to manage communication in data networks.

  29. Addressing and Naming Schemes • Ethernet MAC Addresses, IP Addresses, and TCP/UDP Port numbers • Layer 2 addresses (e.g., Ethernet) are used to move messages to the correct end device. • Layer 3 addresses (e.g., IP addresses) are used to move message between different parts of the network and to identify the correct end device . IP addresses have two parts: • the network (e.g., the IP number assigned to google.com) and • the specific computer within that part of the network (e.g., a specific web server or e-mail server within the Google network). • Layer 4 addresses (e.g., TCP port numbers) are used to move the message to correct Application layer conversation at the end device (e.g., the Web browser or e-mail software on your computer). • Layer 7 addresses (e.g., a Web URL: www.google.com) are used by the Application layer programs.

  30. Addressing and Naming Schemes • Labels in encapsulation headers are used to manage communication in data networks

  31. Addressing and Naming Schemes • Information in the encapsulation header is used to identify the source and destination processes for data communication

  32. Summary

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