1. Aleksandra Smiljanić aleks@ieee.org Introduction

2. Uses of Computer Networks Business Applications Home Applications

3. Business Applications Sharing resources Common databases for customer records, inventory, accounts E-commerce Video-conferencing Disseminating the information, and coordination

4. Home Applications Getting the remote information Person-to-person information E-commerce Entertainment E-flea

5. Network Types Local Area Networks Metropolitan Area Networks Wide Area Networks Wireless Networks Home Networks

6. Network Types Classification of interconnected processors by scale.

7. Local Area Networks Two LANs (a) Bus-broadcast (b) Ring

8. Metropoliten Area Networks Two MANs (a) Star-switched (b) Ring Switch

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

10. Wide Area Networks Relation between hosts on LANs and the subnet. Circuit switch

11. Wide Area Networks A stream of packets from sender to receiver.

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

13. Wireless Networks (a) Bluetooth configuration (b) Wireless LAN

14. 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).

15. Network Hardware Transmission medium Transceivers: transmitters and receivers on the point-to-point connections Multiplexers, demultiplexers Packet and circuit switches Bridges Routers Servers, gateways, management units

16. Transmission Medium Air: different frequency bands Wires: twisted pairs Coaxial cables Optical fibers

17. Transceivers Transmitters perform modulation and coding to provide efficient and reliable communication. Receivers perform the reverse operations. Depending on the medium transceivers are electronic devices, antenas, or lasers and photodiodes.

18. Multiplexers and Demultiplexers Multiplexers receive multiple lower bit-rate streams of data and according to some rule transmit the higher bit-rate stream of data. Demultiplexers do the opposite.

19. Circuit and Packet Switches It does not make sense to connect every user with every other user in the network. Circuit and packet switches connect multiple inputs to multiple outputs. In circuit switches, the configuration pattern changes on a slow time scale. In packet switches, the configuration changes on a packet-per-packet basis.

20. Servers, Gateways, etc. Servers store various kinds of information for users, for example DNS databases, e-mails, web pages and provide it to the users. Gateways convert data format, and negotiate QoS with the network.

21. Layered Structure of Networks Layers, protocols, and interfaces.

22. Protocol Hierarchies Example information flow supporting virtual communication in layer 5.

23. Design Issues for the Layers Addressing Error Control Flow Control Multiplexing Routing

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

25. Reference Models with Layers A layer should have well defined function Function of a layer should be internatinationally standardized The information flow between interfaces should be minimized

26. Reference Models The OSI reference model The TCP/IP reference model Hybrid reference model

27. Reference Models The OSI reference model.

28. Reference Models The TCP/IP reference model.

29. Reference Models Protocols and networks in the TCP/IP model initially.

30. Comparing OSI and TCP/IP Models Concepts central to the OSI model Services Interfaces Protocols Concept of TCP/IP Implementation of the required functionality with three layers

31. A Critique of the OSI Model and Protocols Why OSI did not take over the world Bad timing Bad technology Bad implementations Bad politics

32. Bad Timing The apocalypse of the two elephants.

33. A Critique of the TCP/IP Reference Model Problems: Service, interface, and protocol not distinguished Not a general model Host-to-network “layer” not really a layer No mention of physical and data link layers Minor protocols deeply entrenched, hard to replace

34. Hybrid Model The hybrid reference model to be used in this book.

35. Example Networks The Internet Ethernet Wireless LANs: 802.11

36. Example Networks 1960. Barn from RAND co. first proposal 1957 Advanced Research Project Agency (ARPA) 1967 Larry Roberts proposes ARPANET, that was implemented by BBN co. Interface Message Processors (IMP) were connected by 54kbps links. Protocols: host-IMP, IMP-IMP, host-host 1969 experimental network, UCLA, UCSB, Stanford University, Yuta University

37. The ARPANET (a) Structure of the telephone system. (b) Baran’s proposed distributed switching system.

38. The ARPANET The original ARPANET design.

39. The ARPANET Growth of the ARPANET (a) December 1969. (b) July 1970. (c) March 1971. (d) April 1972. (e) September 1972.

40. TCP/IP Development In 1974, TCP/IP model has been established by Cerf and Kahn, and incorporated into Berkeley UNIX. Because of the large number of hosts, domain name system (DNS) was created in 1980s.

41. NSFNET NSF (National Science Foundation) invested into the network for all universities. Backbone included supercomputers at several universities, it is connected to ARPANET at Carnegie-Mellon university. MCI rented cables at 448kbps, and IBM provided computers as routers.

42. NSFNET The NSFNET backbone in 1988.

43. Further Development 1990 non-profit organization Advanced Networks and Services (ANS) started comercialization, and improved speed to 45Mbps, ANSNET started. In 1995 sold to AOL In nineties EuropaNET and EBONE are developed

44. Internet Usage Traditional applications (1970 – 1990) –E-mail –News –Remote login –File transfer World Wide Web developed by CERN physicist Tim Bernars-Lee, and Mark Andressen at National Center for Supercomputer applications

45. Architecture of the Internet Overview of the Internet.

46. Ethernet Bob Metacalfe graduated MIT and Harvard, and worked on Hawaii on ALOHANET. He designed first computer LAN at Xerox Parc in Palo Alto. DEC, Intel, Xerox make DIX standard that becomes IEEE802.3 Metcalfe founds 3Com

47. Ethernet Architecture of the original Ethernet.

48. Wireless LANs (a) Wireless networking with a base station. (b) Ad hoc networking.

49. Wireless LANs The range of a single radio may not cover the entire system.

50. Wireless LANs A multicell 802.11 network.

51. WLAN Issues CSMA/CD may not be applicable Multipath fading Mobility

52. Network Standardization Who’s Who in the Telecommunications World Who’s Who in the International Standards World Who’s Who in the Internet Standards World

53. ITU Main sectors Radiocommunications Telecommunications Standardization Development Classes of Members National governments Sector members (AT&T, Cisco, Intel, AOL Time Warner…) Associate members Regulatory agencies (FCC)

54. ISO 200 Technical Committees, divided into subcommittees, and working groups involving 100000 voluneers. TC97 in charge for computers and information processing. American National Standards Institute (ANSI) is US representative in ISO. National standards organization -> committee draft ->draft international standard -> standard

55. IEEE 802 Standards The 802 working groups. The important ones are marked with *. The ones marked with  are hibernating. The one marked with † gave up.

56. Internet Standards In 1983, Internet Activities Board (IAB) was established. Communication was done through “request for comments” (RFC) documents. IAB is moved to Internet Research Task Force (IRTF) and Internet Engineering Task Force. Proposed standard -> draft standard -> standard