1. McGraw-Hill©The McGraw-Hill Companies, Inc., 2000 1 Data Communication & Networking DKT 224 Data Communication & Networking DKT 224 Ir Anuar Mat Safar 04-9851684 / 013-4223242 Puan Shahadah Bt. Ahmad 04-9854979 / 017-5722339 School of Computer & Communication Engineering KUKUM anuarms@unimap.edu.my shahadah@unimap.edu.my shahadah@unimap.edu.my

2. 2 Course Outcomes 1.Students will be able to understand the theory and basic of data communication and network. 2.Able to identify network connection concept and protocol used 3.Students be familiarize with the data communication network equipments and instruments to analyze network protocol and perform some troubleshooting 4.Students be exposed to network architecture and new technologies in data communication and network.

3. 3Syllabus Study W e e k Course Content 1,2INTRODUCTION Chapter 1 Introduction to data communications - component, data representation and data flow Chapter 2 Chapter 2 Introduction to data communication networks, -network criteria, physical structures, network models, categories of networks and Internet work. networks and Internet work. -protocols and standards (4 hours) 3,4, 5 PHYSICAL LAYER AND MEDIA (review) PHYSICAL LAYER AND MEDIA (review) Chapter 3,4,5 Chapter 3,4,5 Data and signals, Digital transmission and analog transmission Data and signals, Digital transmission and analog transmission Chapter 6,7 Chapter 6,7 Bandwidth utilization & transmission media Bandwidth utilization & transmission media (6 hours)

4. 4Syllabus Study Week Course Content 6,7 DATA LINK LAYER Chapter 10 Chapter 10 Error Detection and Correction Error Detection and Correction (4 hours) 9,10 9,10 DATA LINK LAYER( cont..) DATA LINK LAYER( cont..) Chapter 11,12 Chapter 11,12 Data link control & Multiple access Data link control & Multiple access (4 hours)

5. 5 Study Week Course Content 11,12 11,12 Chapter 13,14 Wired and wireless LANs (4 hours) 13,14 13,14 SECURITY SECURITY Chapter 30,31 Cryptography & network Security Cryptography & network Security (4 hours) Syllabus

6. McGraw-Hill©The McGraw-Hill Companies, Inc., 2000 6 Assessment Assessment Final Exam - 50 % Course Work – 50 % Lab – 30 % Lab – 30 % Test/ Assigment – 10% Test/ Assigment – 10% Lab Project – 10% Lab Project – 10%

7. 7 Lab experiment LAB 1 - Introduction to LINUX LAB 2 - Network protocol analyzer LAB 3 - Network setup 1 LAB 4 - Network setup 2 LAB 5 - Wireless access point configuration

8. McGraw-Hill©The McGraw-Hill Companies, Inc., 2000 8 References References 1.Behrouz A. Forouzan, Data Communications and Networking, 4th Edition, McGraw Hill, 2007 (TEXT BOOK) Networking, 4th Edition, McGraw Hill, 2007 (TEXT BOOK) 2. William Stalling, Data and Computer Communications,7th Edition, Prentice Hall, 2005. Communications,7th Edition, Prentice Hall, 2005. 3.Wayne Tomasi, Introduction to Data 3.Wayne Tomasi, Introduction to Data Communications and Networking, Communications and Networking, Prentice Hall,2004. Prentice Hall,2004.

9. 9 Chapter 1 Introduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

10. 10 1-1 DATA COMMUNICATIONS The term telecommunication means communication at a distance. The word data refers to information presented in whatever form is agreed upon by the parties creating and using the data. Data communications are the exchange of data between two devices via some form of transmission medium such as a wire cable. Components Data Representation Data Flow Topics discussed in this section:

11. 11 Figure 1.1 Five components of data communication

12. 12 Data Representation TEXT – unicode (32 bits to represent character)- ASCII NUMBERS IMAGES-composed of a matrix of pixel AUDIO- recording or broadcasting of sound or music. VIDEO- recording or broadcasting of a picture or movie

13. 13 Figure 1.2 Data flow (simplex, half-duplex, and full-duplex)

14. 14 1-2 NETWORKS A network is a set of devices (often referred to as nodes) connected by communication links. A node can be a computer, printer, or any other device capable of sending and/or receiving data generated by other nodes on the network. Distributed Processing Network Criteria Physical Structures Network Models Categories of Networks Interconnection of Networks: Internetwork Topics discussed in this section:

15. 15 NETWORKS Set of nodes connected via physical links 1) Distributing Processing 1) Distributing Processing 2) Sharing Data and centralization 2) Sharing Data and centralization 3) Security and robustness 3) Security and robustness

16. 16 Network Criteria 1) Performance, Transmission and response times’ throughput and delay. 2) Reliability: How often the networks fail 3) Security: Privacy and integrity of communication Data; recovery from breaches and data loss.

17. 17 Physical Structures: Types of connections: 1) Point to Point: (P to P) Dedicated link to be utilized only by end devices. 2) Multipoint (Multidrop): Many end devices share the link capacity.

18. 18 Figure 1.3 Types of connections: point-to-point and multipoint

19. 19 Physical Topology Physical Topology

20. 20 Figure 1.4 Categories of topology

21. 21 Physical Topology A) Mesh: Each device has dedicated point-to-point link to other devices. Fully connected mesh will have n( n-1)/ 2 F.D. links Where n = number of nodes Where n = number of nodes Pros: Fast communication, Robust and Privacy (Security) Cons: Cabling Space and cost

22. 22 Figure 1.5 A fully connected mesh topology (five devices)

23. 23 Physical Topology (cont..) B) Star: Devices are connected Point to Point to a central “Hub” (Controller Exchanger) Pros: Less cabling and H/W ports, two hops only. Cons: Not robust

24. 24 Figure 1.6 A star topology connecting four stations

25. 25 Figure 1.7 A bus topology connecting three stations

26. 26 C) Bus: C) Bus: Multipoint link as “backbone” for a network where devices have drop line to tap into the bus Pros: Less Cabling Pros: Less Cabling Cons: Topology dependent, limit number of nodes on the bus due to signal power loss with distance, not so robust

27. 27 Figure 1.8 A ring topology connecting six stations

28. 28 C) Ring: Each device connects Point to Point with only two other devices in a left and right neighbors arrangement via a repeater. Pros : easy installation, better fault isolation and robustness. Pros : easy installation, better fault isolation and robustness. Cons: N/2 hops communication

29. 29 Figure 1.9 A hybrid topology: a star backbone with three bus networks

30. 30 D) Hybrid: Pizza “star” inside a “ ring” Pros: Better robustness, still low cost, Delay is 1 hop (until the star is not with a ring cut, max 2. Star of busses

31. 31 Categories of Networks: Local Area Networks (LAN): Few Kilometers Connects devices (Pcs, printers, servers.) within the same room, building, company, and campus. Topologies most used are bus, ring and star.

32. 32 Figure 1.10 An isolated LAN connecting 12 computers to a hub in a closet

33. 33 Categories of Networks(cont..) Wide Area Networks (WAN): span a large geographical area about 100’s – 1000’s of Km span a large geographical area about 100’s – 1000’s of Km 1) Switched: End users connected via a cloud of switches (subnet). 2) Point-to Point: Line leased from telephone company/ TV connecting users to the ISP for Internet access.

34. 34 alternative technologies used include: circuit switching circuit switching packet switching packet switching frame relay frame relay Asynchronous Transfer Mode (ATM Asynchronous Transfer Mode (ATM

35. 35 Circuit Switching uses a dedicated communications path established for duration of conversation comprising a sequence of physical links with a dedicated logical channel eg. telephone network

36. 36 Packet Switching data sent out of sequence small chunks (packets) of data at a time packets passed from node to node between source and destination used for terminal to computer and computer to computer communications

37. 37 Frame Relay packet switching systems have large overheads to compensate for errors modern systems are more reliable errors can be caught in end system Frame Relay provides higher speeds with most error control overhead removed

38. 38 Asynchronous Transfer Mode (ATM) evolution of frame relay fixed packet (called cell) length with little overhead for error control anything from 10Mbps to Gbps constant data rate using packet switching technique with multiple virtual circuits

39. 39 Figure 1.11 WANs: a switched WAN and a point-to-point WAN

40. 40 Figure 1.12 A heterogeneous network made of four WANs and two LANs

41. 41 Categories of Networks(cont..) Metropolitan Area Networks: MAN town/city MAN town/city High-speed backbone linking multiple LAN’s, DSL, TV cables.

42. 42 1-3 THE INTERNET The Internet has revolutionized many aspects of our daily lives. It has affected the way we do business as well as the way we spend our leisure time. The Internet is a communication system that has brought a wealth of information to our fingertips and organized it for our use. A Brief History The Internet Today (ISPs) Topics discussed in this section:

43. 43 The Internet Internet evolved from ARPANET first operational packet network first operational packet network applied to tactical radio & satellite nets also applied to tactical radio & satellite nets also had a need for interoperability had a need for interoperability led to standardized TCP/IP protocols led to standardized TCP/IP protocols

44. 44 The Internet: Huge number of interconnected Networks (100000’s) private organized, e.g.’ government, schools, research facilities, in many countries Collection of LAN’S, MAN’S and WAN’s. The internet protocol stack is the TCP/IP The internet protocol stack is the TCP/IP End users use the internet via Internet Service providers (ISPs) which are of the following hierarchies: End users use the internet via Internet Service providers (ISPs) which are of the following hierarchies:

45. 45 Figure 1.13 Hierarchical organization of the Internet

46. 46 Internet Elements

47. 47 Internet Architecture

48. 48 Example Configuration

49. 49 1-4 PROTOCOLS AND STANDARDS In this section, we define two widely used terms: protocols and standards. First, we define protocol, which is synonymous with rule. Then we discuss standards, which are agreed-upon rules. Protocols Standards Standards Organizations Internet Standards Topics discussed in this section:

50. 50 What is a protocol? What is a protocol?  Communications between computers requires very specific unambiguous rules  A protocol is a set of rules that governs how two or more communicating parties are to interact Examples  Internet Protocol (IP)  Transmission Control Protocol (TCP)  HyperText Transfer Protocol (HTTP)  Simple Mail Transfer Protocol (SMTP)

51. 51 Elements: 1) Syntax: PDU format 1) Syntax: PDU format 2) Semantics: The meaning of each PDU’s field 2) Semantics: The meaning of each PDU’s field 3) Timing: Synchronization of communication when PDU is to be transferred and its data rate. 3) Timing: Synchronization of communication when PDU is to be transferred and its data rate.

52. 52 What is a standard? A “ standard is set of guidelines” to users and manufactures to ensure interconnectivity. A “ standard is set of guidelines” to users and manufactures to ensure interconnectivity. 1) “Defacto” not approved but widely used (TCP/IP) 1) “Defacto” not approved but widely used (TCP/IP) 2) “Dejure”: approved by recognized body (IEEE 802.X). 2) “Dejure”: approved by recognized body (IEEE 802.X).

53. 53 Summary introduced data communications needs communications model defined data communications overview of networks introduce Internet