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Fundamentals of Telecommunications Week 5: WANs and LANs

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Title: Fundamentals of Telecommunications Week 5: WANs and LANs


1
Fundamentals of TelecommunicationsWeek 5 WANs
and LANs
  • Elizabeth Lane Lawley, Instructor

2
Review of Quiz 1
  • On a take-home test, my expectations are higher
    for both content and presentation
  • Reminder It is your responsibility to understand
    the policy on academic dishonesty and clarify
    anything you dont understand

3
Network Models
  • Helpful to have a model to understand parts of a
    network
  • Most commonly used model is OSI 7-layer model

4
OSI
  • Application
  • Presentation
  • Session
  • Transport
  • Network
  • Data Link
  • Physical
  • Open Systems Interconnection
  • Developed by ISO
  • Contains seven layers(see page 358)

5
OSI Lower Layers
  • Physical
  • Data Link
  • Network

6
OSI Physical Layer
  • Responsible for transmission of bits
  • Always implemented through hardware
  • Encompasses mechanical, electrical, and
    functional interfaces
  • e.g. RS-232

7
OSI Data Link Layer
  • Responsible for error-free, reliable transmission
    of data
  • Flow control, error correction
  • e.g. HDLC

8
OSI Network Layer
  • Responsible for routing of messages through
    network
  • Concerned with type of switching used
  • Handles routing between networks, as well as
    through packet-switching networks

9
OSI Upper Layers
  • Transport
  • Session
  • Presentation
  • Application

10
OSI Transport Layer
  • Isolates messages from lower and upper layers
  • Breaks down message size
  • Monitors quality of communications channel
  • Selects most efficient communication service
    necessary for a given transmission

11
OSI Session Layer
  • Establishes connections between systems
  • Manages log-ons, password exchange, log-offs
  • Tracks physical location of files on both sides
    of a transfer

12
OSI Presentation Layer
  • Provides format and code conversion services
  • Examples
  • File conversion from ASCII to EBDIC
  • Invoking character sequences to generate bold,
    italics, etc on a printer

13
OSI Application Layer
  • Provides access to network for end-user
  • Users capabilities are determined by what items
    are available on this layer

14
TCP/IP v. OSI
15
TCP/IP Advantages
  • Simpler model (5 layers rather than 7)
  • More widely implemented

16
OSI Lower Layer Devices
  • Provide transmission facilities over physical
    media
  • Generally sit between computers (DTEs), and
    provide data transfer functions only

17
Null Modems
  • Created from cables
  • Crossover wires within cable or connector
  • Allows direct point-to-point communication

18
Short Haul Modems
  • Inexpensive (as little as 40)
  • Can transmit at up to 19.200bps for several miles
  • Also called modem eliminators

19
CSU/DSU (Digital Modems)
  • Channel Service Units/Data Service Units
  • Used when connecting to digital leased lines,
    like 56 or T-1s
  • Ensures that digital data is properly formed into
    digital signal
  • Includes digital conversion and high-speed serial
    interface
  • Provides line equalization, filtering, error
    control, testing, and signal regeneration

20
Data Networks
  • Connect data processing devices for the purpose
    of data communication
  • WAN/Wide Area Network packet-switched networks
    that provide communication over long distances
    and among multiple sites
  • LAN/Local Area Network privately owned network
    that provides reliable, high-speed, switched
    connections between devices in a single building
    or complex

21
Packet Switching Networks
  • Data is broken up into packets that may take
    diverse routes
  • Use virtual circuits rather than dedicated
    circuits--only in place while data is being
    transferred

22
X.25 Standard
  • Defines method for connecting a node to a packet
    switching network
  • Similar to lower layers of OSI model
  • If DTE is not X.25 compatible, a PAD (packet
    assembler/disassembler) is necessary

23
Frame Relay Networks
  • Takes advantage of digital nature of IXC
    connections
  • Uses less error detection/correction because
    digital transmission is more reliable
  • Uses only Layers 1 2 of OSI (routing
    information in frame is used to relay
    information, rather than readdressing)

24
LANs
  • Provide flexible, cross-platform data
    communication and resource sharing
  • Typically covers an area of 1-10 miles (building,
    campus, industrial park)
  • Can use centralized control or distributed control

25
LAN Topologies
  • Mesh
  • Star
  • Bus
  • Star-wired bus
  • Tree
  • Ring
  • Star-wired ring

26
LAN Access Methods
  • CSMA Carrier Sense Multiple Access
  • CSMA/CD CSMA with Collision Detection
  • Token Passing

27
CSMA/CD
  • Checks for clear path prior to transmission
    attempt
  • When channel is clear of a carrier signal, it
    transmits
  • If two stations transmit simultaneously,
    monitoring picks up collision, and stations
    retransmit at randomly selected backoff times

28
LAN Standards
  • 802.x series
  • 802.3 - Ethernet (CSMA/CD)
  • 802.5 - Token Ring
  • Divided data link into two functions
  • MAC (medium access control) handles access method
  • LLC (logical link control) handles error
    checking/reliability

29
Ethernet (802.3)
  • Bus network using CSMA/CD
  • Different transmission media can be used
  • Baseband coax allows 10mbps
  • 10Base-T
  • 10mbps
  • Baseband
  • Twisted pair wires
  • Uses hubs in star-wired bus configuration

30
IBM Token Ring (802.5)
  • Star-wired ring
  • 4 or 16mbps using twisted pair

31
Fiber Distributed Data Interface (FDDI)
  • ANSI standard
  • Uses fiber optics for speeds of up to 100mpbs
  • Token ring topology similar to IEEE 802.5
  • Two rings one for traffic, one for backup

32
Internetworking
  • Connecting two or more networks together
  • Why?
  • Distance limitations reached
  • Overcrowding of LANs
  • Need for remote sites to connect

33
Repeaters
  • Layer 1 devices
  • Simply receives and retransmits all bits
  • Some repeaters provide basic error-checking
    (Layer 2 function)
  • Inexpensive, used to overcome distance limitations

34
Bridges
  • Connects two or more networks using the same
    addressing method
  • Can provide some addressing information (Layer
    2-3 functions)
  • Often used when LANs reach their capacity of nodes

35
Types of Bridges
  • Adaptive/learning bridges configure themselves by
    watching traffic, determining what addresses are
    on each side of the bridge
  • Remote bridges connect to each other via a
    digital phone circuit such as a T-1

36
Routers
  • Layer 3 devices
  • Maintain a map of the network, choose the best
    route for data
  • Translates local addresses (eg. spot) into
    network addresses (e.g. 129.21.22.12)
  • Can translate messages with different addressing
    methods
  • Can act as firewalls (many ISPs block traffic at
    the router level)

37
Gateways
  • Perform functions as high as layer 7
  • Can connect very different networks, peform
    complex conversions
  • Could be used to connect a packet-switching
    network to a LAN, convert e-mail from one format
    to another
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