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CS716 Advanced Computer Networks By Dr. Amir Qayyum

CS716 Advanced Computer Networks By Dr. Amir Qayyum. Lecture No. 1. Instructor’s Introduction. Ph.D. Mobile Wireless Net., Univ. of Paris-Sud, France Elect. Engg.,U.E.T. Lahore M.S. Comp. Engg., E.S.I.M., France D.E.A. Parallel Comp. Arch., Univ. of Paris-Sud, France

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CS716 Advanced Computer Networks By Dr. Amir Qayyum

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  1. CS716 Advanced Computer Networks By Dr. Amir Qayyum

  2. Lecture No. 1

  3. Instructor’s Introduction Ph.D. Mobile Wireless Net., Univ. of Paris-Sud, France Elect. Engg.,U.E.T. Lahore M.S. Comp. Engg., E.S.I.M., France D.E.A. Parallel Comp. Arch., Univ. of Paris-Sud, France Active participant of MANET wg of IETF since 1997 Co-author of an RFC on routing protocol for MANETs Associated with INRIA, France as a research fellow Worked on Praxitele, PRIMA and IPANEMA projects Protocol implement. experience at Enabling Technologies Implementation of RTP-RTCP/UDP-TCP/IP stack for a RISC based packet processor, including CRTP, PPP/MP, IPsec, QoS. Currently working at CARE Pvt. Ltd. and CASE Design/development of long-range, secure mobile ad hoc networks 3

  4. Significance and Rationale of course • Networks and telecommunication is getting more and more importance • Future telecomm networks will be more oriented toward “networks” rather than “communication” • Widespread Internet, diffused in our daily life is a ground reality; its beneficial to understand it • Its fun to play with protocols (software) and able to design exciting new type of networks

  5. Foundation Course in Network Stream • This Computer Networks course is a foundation course for “Networks” as the Area of Specialization • It is a required pre-requisite course for the following advanced level courses in networking • Performance Analysis of Communication Networks • Integrated Services over Packet Networks • Computer Network Security • Mobile Networking • It is a recommended pre-requisite for the course: • Network and System Programming

  6. Course Material • Reference books • Many textbooks on Networking may be consulted • Lot of research papers! • Many will be made available on course web site • RFCs and Internet drafts • Related to TCP/IP suite and other protocols • Web resources • Tutorials, white papers, reports, etc.

  7. Text Book • Larry L. Peterson and Bruce S. Davies, Computer Networks: A Systems Approach • Third Edition [2003], Morgan Kaufmann Publishers, San Mateo, California, USA • W. Richard Stevens, UNIX Network Programming, Volume 1, (Networking APIs: Sockets and XTI) • Second Edition, Prentice Hall • Recommended ONLY for programming part

  8. Prerequisites • Required: • An undergraduate level course on computer networks • Good knowledge of C language, preferably in Unix/Linux • e.g. C and Data Structures course

  9. Course Evaluation • Assignments • Quizzes • Research Papers • Term Projects / Reports • Midterm exam • Final exam

  10. Expectations What do you want (or expect) to learn from this course ?

  11. Expectations • This course IS about … • Network principles and concepts • General purpose computer networks • Internet perspective • Major components of the Internet protocol suite • Network software • Designing and building a system

  12. Expectations • This course IS NOT about … • Survey of existing protocol standards • Specialized networks (e.g. CATV, telephone) • OSI perspective • Network hardware • Data transmission on physical layer • Queuing theory (we do survey, if time permits)

  13. Expectations We will learn why networks are like they are

  14. Objectives: Principles and Concepts • At the end of this course, you should be able to: • Identify the problems that arise in networked communication • Explain advantages/disadvantages of existing solutions to these problems in different networking scenarios • Evaluate novel approaches to these problems • Understand the components of Internet protocol suite • Understand the implications of a given solution for performance in various networking environments

  15. Objectives: Programming • At the end of this course, you should be able to: • Identify and describe the purpose of each component of the TCP/IP protocol suite • Develop client-server applications using TCP/IP • Understand the impact of trends in network hardware on network software issues • Understand over 1000 useful (or useless) VUAs

  16. Course Contents • Overview • Introduction to network programming • Direct link networks • Packet switching • Internetworking • End-to-end protocols • Congestion control and resource allocation • End-to-end data • Applications • Performance analysis and queuing theory (?)

  17. Introduction • Outline • Statistical Multiplexing • Inter-Process Communication • Performance Metrics • Network Architecture

  18. What is Your Over-ambitious Goal ? • Build a computer network which • Can grow to global proportions • Support diverse applications • Then … think about • Underlying building blocks • Which available technologies to use • Integrating the blocks to communicate • Which software architecture to use

  19. Network Design Before looking inside a computer network, first agree on what a computer network is?

  20. Computer Network ? • Set of serial lines to attach terminals to mainframe ? • Telephone network carrying voice traffic ? • Cable network to disseminate video signals ? Specialized to handle: Keystrokes Voice Video

  21. What Distinguishes a Computer Network ? • Generality • Built from general purpose programmable hardware • Supports wide range of applications

  22. Applications – Users’ Contact with the Network • Most people know the Internet through its applications • Web, email, streaming audio and video, chat, … • Applications present an intuitively simple interface • Textual and graphical objects • Simple “clicks” to maneuver the application • However, users are not aware of what happens in the network with their simple “clicks” !!!

  23. Applications – Consumers of Networks • On a simple click, several messages may be exchanged over the Internet • In a web browser, 17 messages may be exchanged • up to six messages to translate the server name • three messages to set up a TCP connection • four messages to send HTTP “get” request + response • four messages to tear down the TCP connection • Moreover, millions of messages are exchanged each day by Internet nodes to make their presence and services known

  24. Applications – the Driving Force • Streaming audio and video is an emerging application • Source generates and sends the video stream in messages across the Internet • Video-on-demand: reads a preexisting movie • One-way data transfer • Videoconferencing: interactive session • Very tight timing constraints • Diversity of applications that can be built on top of the Internet hint at the complexity of the Internet design

  25. Our Road Map … • Fortunately, we are not the first to build a computer network • Lets start exploring the path that others have already dig deep • By asking (and answering) why networks are designed the way they are

  26. Network Overview • What must a network provide ? • Connectivity • Cost-effective sharing • Functionality • Performance • How are networks designed and built ? • Layering • Protocols • Standards

  27. Perspective • For network user • Connectivity: for services required; error free delivery within acceptable time limits • For network designer • Efficiency: cost-effective design, fair allocation and efficient use of resources • For network operator • Maintenance: easy to administer, fault localization & isolation, usage accounting

  28. Building Blocks • Nodes: PC, special-purpose hardware… • Hosts • Switches • Links: coax cable, optical fiber… • Point-to-point • Multiple access …

  29. Why not connect each node with every other node ? • Number of computers that can be connected becomes very limited • Number of wires coming out of each node becomes unmanageable • Amount of physical hardware/devices required becomes very expensive • Solution: indirect connectivity using intermediate data forwarding nodes

  30. Switched Networks • A network can be defined recursively as... • Two or more nodes connected by a link • Circular nodes (switches) implement the network • Squared nodes (hosts) use the network

  31. Switched Networks • A network can be defined recursively as... • Two or more networks connected by one or more nodes: internetworks • Circular nodes (router or gateway) interconnects the networks • A cloud denotes “any type of independent network”

  32. A Network A network can be defined recursively as Two or more nodes connected by a physical link OR Two or more networks connected by one or more nodes

  33. Components of a Network

  34. Switching Strategies • Packet switching: store-and-forward messages • operates on discrete blocks of data • utilizes resources dynamically according to traffic demand • send/receive messages at variable rate • example: Internet • Circuit switching: carry bit streams • establishes a dedicated circuit • links reserved for use by communication channel • send/receive bit stream at constant rate • example: original telephone network

  35. What next ? • Hosts are directly or indirectly connected to each other • Can we now provide host-host connectivity ? • Nodes must be able to say which host it wants to communicate with

  36. Addressing and Routing • Address: byte-string that identifies a node • Usually unique • Routing: forwarding decisions • Process of determining how to forward messages to the destination node based on its address • Types of addresses • unicast: node-specific • broadcast: all nodes on a network • multicast: some subset of nodes on a network

  37. Wrap-up • A network can be constructed from nesting of networks • An address is required for each node that is reachable on the network • Address is used to route messages toward appropriate destination

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