1. M. Dahshan - TCOM52721 TCOM 5272 Telecomm Lab Dr. Mostafa Dahshan OU-Tulsa 4W 2 nd floor 660-3713 mdahshan@ou.edu

2. M. Dahshan - TCOM52722 Acknowledgments  Most of the contents of this presentation are imported from Supplemental materials of the textbook Presentations of Dr. Anindya Das

3. M. Dahshan - TCOM52723 Introduction  Course Objectives Implementation of the theory Improve knowledge in network devices management Introduce some useful software tools  Schedule

4. M. Dahshan - TCOM52724 Network Types  Local area networks (LANs)  Metropolitan area networks (MANs)  Wide area networks (WANs)

5. M. Dahshan - TCOM52725 LAN (Local Area Network)  Interconnects computers, printers, other equipment  Consists of shared hardware and software resources in close physical proximity  Example: TCOM Department

6. M. Dahshan - TCOM52726 MAN ( Metropolitan Area Network)  Spans a greater distance than a LAN  Links multiple LANs within city or metropolitan region  Typically uses fiber- optic/wireless connections  Example: Campus LAN links to offices outside the campus

7. M. Dahshan - TCOM52727 WAN (Wide Area Network)  Composed of two or more LANs or MANs  May have constituent LANs on different continents  Example: The Internet

8. M. Dahshan - TCOM52728

9. 9 Network Topologies  Main topologies: Bus Ring Star Mesh  Hybrid topologies star-bus star-ring

10. M. Dahshan - TCOM527210 Bus Topology  Consists of cables connecting PCs or file servers  Visualizes connections as chain links  Terminator attached to each end of bus cable segment  Media type (discussed later) 10Base5 10Base2

11. M. Dahshan - TCOM527211 Bus Topology (2)  Advantages Requires less cable than other topologies Easy to extend bus with a workstation  Disadvantages High management costs  Single defective node can take down entire network Can become quickly congested with network traffic

12. M. Dahshan - TCOM527212 Ring Topology  Continuous data path Workstations attached to cable at points around ring  Transmitted data Goes around ring to reach destination Continues until ends at source node

13. M. Dahshan - TCOM527213 Ring Topology (2)  Advantages Easier to manage than bus Handles high volume network better than bus Suited to transmitting signals over long distances  Disadvantages Expensive equipment and wiring Fewer equipment options

14. M. Dahshan - TCOM527214 Star Topology  Multiple nodes attached to central device (hub, switch, router)  Cable segments radiate from center like a star  Example: workstations connected to switch

15. M. Dahshan - TCOM527215 Star Topology (2)  Advantages Easier to manage, defective nodes quickly isolated Easier to expand Better equipment and high-speed options  Disadvantages Failure of central device may cause network failure Requires more cable than bus

16. M. Dahshan - TCOM527216 Mesh Topology  Every node connected to every other node in network  Often used in MANs and WANs

17. M. Dahshan - TCOM527217 Mesh Topology (2)  Advantages Fault tolerance Alternate communication paths  Disadvantages Expensive

18. M. Dahshan - TCOM527218

19. M. Dahshan - TCOM527219 The ISO Reference Model  Fundamental network communications model  Product of two standards organizations International Organization for Standardization (ISO) American National Standards Institute (ANSI)  OSI is theoretical, not specific hardware or software  OSI guidelines analogized to a grammar

20. M. Dahshan - TCOM527220 The ISO Reference Model (2)  Accomplishments Enabling communications among LANs, MANs, WANs Standardizing network equipment Enabling backward compatibility to protect investments Enabling development of software and hardware with common interfaces

21. M. Dahshan - TCOM527221 The ISO Reference Model (3)

22. M. Dahshan - TCOM527222 Layered Model  Reduces complexity  Standardizes interfaces  Facilitates modular engineering  Ensures interoperable technology  Accelerates evolution  Simplifies teaching & learning

23. M. Dahshan - TCOM527223 Physical Layer  Transmit and receive signals  Network connectors  Signaling and encoding methods  Detection of signaling errors  Data transfer mediums wire cable fiber optics radio waves

24. M. Dahshan - TCOM527224 Data Link Layer  Format bits into frames  Frame: discrete unit of information Contains control and address information Does not contain routing information  Logical Link Control (LLC) Initiates communication between two nodes  Media Access Control (MAC) Provides physical addressing Regulates access to the media

25. M. Dahshan - TCOM527225 Network Layer  Packet logical addressing  Path determination  Route optimization  Addressing is done through routed protocols: IP, IPX, AppleTalk, DECnet  Path Selection is done using routing protocols: RIP, IGRP, EIGRP, OSPF, BGP

26. M. Dahshan - TCOM527226 Transport Layer  Provides transparent flow of data  End-to-end recovery  Flow control and error control  Data segmentation  Ensures data received in order

27. M. Dahshan - TCOM527227 Session Layer  Manages dialog between applications  Establishes, manages, terminates sessions  Determines communication type Simplex Half-duplex Full-duplex

28. M. Dahshan - TCOM527228 Presentation Layer  Provides data representation and code formatting  Translates between character codes  Compression and encryption  Example: Secure Sockets Layer (SSL)

29. M. Dahshan - TCOM527229 Application Layer  Provides network services to applications Remote access to printers Message handling for electronic mail Terminal emulation

30. M. Dahshan - TCOM527230 Internet Standards  Specifications of network technologies  Ratified by the IETF  Begins as Internet Draft (ID) Request For Comments (RFC)  Not all RFCs are standards

31. M. Dahshan - TCOM527231 Internet Standards (2)  Examples of full standard RFCs RFC 791: Internet Protocol RFC 793: Transmission Control Protocol RFC 959: File Transfer Protocol  Full List www.apps.ietf.org/rfc/stdlist.html

32. M. Dahshan - TCOM527232

33. M. Dahshan - TCOM527233 Media Types  Coaxial cable: copper wire  Twisted-pair cable: copper wire  Fiber-optic cable: glass or plastic  Wireless: radio or microwaves

34. M. Dahshan - TCOM527234 Coaxial Cables  Used in bus topologies  10Base5 (thicknet, thickwire, RG8)  10Base2 (thinnet, thinwire)

35. M. Dahshan - TCOM527235 10Base5  Transmission rate of 10 Mbps  Longest cable run 500 m  Two transmission types Baseband: single channel Broadband: multiple nodes on multiple channels

36. M. Dahshan - TCOM527236 10Base5 (2)  Has relatively large 0.4-inch diameter  Copper or copper-clad aluminum conductor at core  Conductor surrounded by insulation  Aluminum sleeve wrapped around insulation  PVC or Teflon jacket covers aluminum sleeve

37. M. Dahshan - TCOM527237 10Base5 (3) 10BASE5 vampire tap MAU transceiver Source: WikimediaWikimedia

38. M. Dahshan - TCOM527238 10Base2  Maximum speed 10Mbps  Wire up to 185 meters (almost 200)  Used for baseband data transmission

39. M. Dahshan - TCOM527239 10Base2 (2)  Attached to bayonet connector (BNC)  BNC connected to T- connector  Middle of T-connector attached to NIC  Terminator may be attached to one end of T- connector

40. M. Dahshan - TCOM527240 Twisted Pair Cables  Contains pairs of insulated copper wires  Outer insulating jacket covers wires  Communication specific properties Copper wires twisted to reduce EMI and RFI Length: up to 100 meters Transmission speed: up to 10 Gbps

41. M. Dahshan - TCOM527241 Twisted Pair Cables (2)  RJ-45 plug-in connector attaches cable to device Less expensive and more flexible than T-connectors

42. M. Dahshan - TCOM527242 Twisted Pair Cables (3)  Two Types Shielded (STP) Unshielded (UTP)

43. M. Dahshan - TCOM527243 Shielded Twisted Pair (STP)  Surrounded by braided or corrugated shielding  Shield reduces interference (EMI, RFI)  Interval of twists in each pair should differ  Connectors, wall outlets should be shielded  Have proper grounding  Used in strong interference environment  Expensive cable and equipment

44. M. Dahshan - TCOM527244 Unshielded Twisted Pair (UTP)  Consists of wire pairs within insulated outer covering  No shield between wires and encasement  Most frequently used network cable  Reducing EMI and RFI Twist interior strands (like STP) Build media filter into network equipment

45. M. Dahshan - TCOM527245 Unshielded Twisted Pair (UTP)(2)

46. M. Dahshan - TCOM527246 Unshielded Twisted Pair (UTP)(3)  Fewer points of failure  Has no shield that can tear (up through Category 5e)  Connectors and wall outlets do not need shielding  Proper grounding not as critical to purity of signal

47. M. Dahshan - TCOM527247 Fiber-Optic Cables  Glass or plastic fiber cores encased in glass tube (cladding)  Fiber cores and cladding are surrounded by PVC cover  Signal transmissions consist light (usually infrared)

48. M. Dahshan - TCOM527248 Fiber-Optic Cables (2)  Advantages Transmission speeds from 100 Mbps to over 100 Gbps No EMI or RFI problems  Data travels by light pulse Low attenuation Secure from unauthorized taps

49. M. Dahshan - TCOM527249 Fiber-Optic Cables (3)  Disadvantages Fragile Expensive Requires specialized training to install Cannot be used for analog communications

50. M. Dahshan - TCOM527250 Fiber-Optic Cables (4)  Single-mode Used for long-distance communication 8-10/125 µm cable transmits one wave at a time Communications signal is laser light  Multimode Supports multiple waves (broadband) Comes in two varieties  step index  graded index Cable diameter between 50 and 115 microns Source for multimode cable is LED

51. M. Dahshan - TCOM527251 Fiber-Optic Cables (5)  Connector types Subscriber Connector (SC) Straight Tip (ST) And others… Source: WikimediaWikimedia

52. M. Dahshan - TCOM527252

53. M. Dahshan - TCOM527253 Activity 1-6: Viewing Network Links in Windows  Time Required : 5–10 minutes  Objective: View the Windows Server 2003 and Windows XP LAN and WAN connection options.  Description: View the logical links between various types of networks— including dial-up and VPNs—joined through Windows Server 2003 and Windows XP Professional.

54. M. Dahshan - TCOM527254 Activity 1-7: Determining Network Connectivity in UNIX/Linux  Time Required: 5 minutes  Objective: Viewing LAN and WAN connectivity in UNIX/Linux.  Description: View network connectivity in Fedora or Red Hat Enterprise Linux, which is already configured with the X Window GNOME interface.

55. M. Dahshan - TCOM527255 Activity 2-3: Viewing a NIC’s Physical Address  Time Required: 5–10 minutes  Objective: Determine the physical address of the NIC in a computer.  Description: Provides an opportunity to determine the physical address of a network interface card (NIC) in a computer. You need access to a computer that is connected to a network and that runs Windows XP, Windows Server 2003, Fedora, or Red Hat Enterprise Linux. For Fedora or Red Hat Enterprise Linux, you need to use the root account.

56. M. Dahshan - TCOM527256 Activity 2-6: Viewing Network Objects Using the Windows Redirector  Time Required: 5–10 minutes  Objective: Use the Microsoft Windows redirector.  Description: The Microsoft Windows redirector is one example of the Application layer (Layer 7) at work. In this activity, you view computers, shared folders, and shared printers through a Microsoft-based network, which are made accessible, in part, through the redirector. Your network needs to have at least one workgroup (or domain) of computers, shared folders, and shared printers to fully view the work of the redirector.

57. M. Dahshan - TCOM527257 Activity 4-1: Comparing Different Cable Types  Time Required: Approximately 10 minutes  Objective: Compare coax, twisted-pair, and fiber- optic cable.  Description: You will better understand your network if you understand the physical differences among cable types. You will also be better able to design a new network or upgrade a legacy network. In this activity, you compare the flexibility and appearance of coaxial, twisted-pair, and fiber-optic cable.

58. M. Dahshan - TCOM527258 Activity 4-2: Comparing Cable Connectors  Time Required: Approximately 10 minutes  Objective: Compare connectors for different cable types.  Description: Each type of cable uses different kinds of connectors. This activity enables you to see the kinds of connectors used for different cable mediums.

59. M. Dahshan - TCOM527259 Activity 4-4: Building a UTP Cable  Time Required: Approximately 20–30 minutes  Objective: Experience building a UTP cable.  Description: In this activity, you attach 4- pair UTP cable to an RJ-45 connector. You need the cable, a crimper, a connector, and a wire stripper. These instructions and Figure 4-6 follow the EIA/TIA-568-B standard.

60. M. Dahshan - TCOM527260

61. M. Dahshan - TCOM527261 Homework  Activities Chapter 1: 1-8 Chapter 2: 2-1  Problems Chapter 2: 1,2,4,8,9,11,14,15,16,17 Chapter 4: 1,2,6,8,9,10,11,12,13,14,15,16,18,20