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Data Communications

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Title: Chapter 1 Data Communications and Networks Overview Subject: ACOE312 Author: Dr. L. Christofi Last modified by: Louis Created Date: 9/3/1999 12:49:47 PM – PowerPoint PPT presentation

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Title: Data Communications


1
Data Communications Computer Networks
  • Assignment 1
  • Solutions
  • Fall 2004

2
Reminder for the rules for assignments (1)
  • All assignments must be done individually
  • You should NOT
  • Copy any part of another student's answers.
  • Allow another student to copy your work.
  • Present the work of another as your own. If you
    use the idea of another in your work, you MUST
    provide appropriate attribution (that is, cite
    the work and the author).

3
Reminder for the rules for assignments (2)
  • It is the students responsibility to make up for
    any missed work due to his/her absence(s).
  • Assignments should be handed-in on time
  • 10 November 2004 for assignment 1
  • However, they can be submitted up to one week
    late, but will receive a 10 mark reduction
    penalty.
  • NO credit will be given for ANY assignment
    submitted later than one week from the due date,
    since we will go over the assignment in class.

4
Answer to Problem 1
  • a) Give two reasons for using layered protocols?
    (4 marks)
  • - Smaller more manageable pieces
  • - Protocols can be changed without effecting
    higher or lower layers.
  • b) List two main disadvantages to layered
    approach to protocols (4 marks)
  • - More processing
  • - More overhead due to the headers added by the
    layers
  • c) A system has an n-layer protocol hierarchy.
    Applications generate messages of length M-bytes.
    At each of the layers, an h-byte header is added.
    What fraction of the network bandwidth is filled
    with headers? (6 marks)  
  • Each message is M-bytes long. There are n-layers
    each one adding an h-byte header, therefore, each
    message that is transmitted through the network
    is (nhM) bytes long. The fraction of the network
    bandwidth that is filled with headers is given by
    nh/(nhM)
  • If it is assumed that the bottom layer (physical)
    does not generate any header, then there shall be
    (n-1)h headers generated, so the fraction of the
    network bandwidth that is filled with headers is
    given by (n-1)h/(n-1)hM

5
Answer to Problem 2
  • a) What is the difference between a confirmed
    service and an unconfirmed service? For each of
    the following, tell whether it might be a
    confirmed service, an unconfirmed service, both
    or neither (7 marks)
  •      (i)         Connection establishment
  •      (ii)        Data transfer
  •      (iii)       Connection release
  •  
  • In a confirmed service, there is a request, an
    indication, a response and a confirmation. In an
    unconfirmed service, there is just a request and
    an indication.
  • Connection establishment Confirmed service,
    since an explicit response is required
  • Data transfer Can be confirmed or uncorfirmed,
    depending whether or not the sender needs an
    acknowledgement
  • Connection release This is a disconnect service,
    therefore it is unconfirmed since there is no
    response

6
Answer to Problem 2
  • b) What is the principal difference between
    connectionless communication and
    connection-oriented communication? Is it possible
    to have both of them in two adjacent layers?
    Discuss! (6 marks) 
  • Connection-oriented service is modelled after the
    telephone system. To use a connection-oriented
    network service, the service user first
    establishes a connection, uses the connection and
    then it releases the connection.
  • Connectionless service is modelled after the
    postal system. Each message (letter) carries the
    destination address and each one is routed
    through the system independent of all the others.
  • Yes, it is possible to have connection-oriented
    and connectionless service in adjacent layers.
    Example is TCP/IP. TCP is connection-oriented
    protocol that lies in transport layer (layer 4),
    IP is connectionless that lies in network layer
    (layer-3).
  • c) What is the main difference between TCP and
    UDP protocols? Give an example of a service these
    protocols can support? (6 marks)
  • TCP provides reliable connection-oriented
    protocol that delivers a byte stream from one
    node to another, guaranteeing delivery and
    provides flow control. TCP can be used in file
    transfer applications.
  • UDP provides unreliable connectionless protocol
    for applications. UDP can be used in applications
    for carrying voice traffic over packet-switched
    networks.
  •  

7
Answer to Problem 3
  • a) Contrast and criticize OSI and TCP reference
    models outlining their similarities and
    differences. (6 marks)
  • Both models have network, transport and
    application layers with similar functionalities.
    Both are based on the concept of a stack of
    independent protocols. However, OSI supports both
    connectionless and connection-oriented
    communication in the network layer but only
    connection-oriented communication in the
    transport layer. TCP/IP has only connectionless
    mode in the network layer but supports both
    connectionless and connection-oriented
    communication in the transport layer.
  • OSI model Has been devised before the
    corresponding protocols were invented
  • Has good definition of service,
    interface, and protocol
  • Fits well with object oriented
    programming concepts
  • Protocols are better hidden
  • TCP model the protocols came first, the
    model was just a description of the protocols
  • the model isn't good for any other
    protocols part from TCP/IP.
  • A critique of OSI model Bad Timing (TCP
    already in use by the time OSI came along)
  • Bad Technology
    (Layers don't really match. Dominated by phone
  • company
    mentality)
  • Bad
    Implementation (Huge, unwieldy, slow).
  • A critique of TCP/IP model Doesn't separate
    specification from implementation.
  • Model is
    only good for describing TCP.
  • Doesn't
    specify physical and data link layers.

8
Answer to Problem 3
  • b) Which layer of the OSI reference model is
    responsible for the following (6 marks)
  •      (i)    Negotiating data transfer syntax
    Presentation
  •      (ii)   Addressing devices and routing
    through an internetwork Network
  •      (iii)   Framing Data Link
  •      (iv)   Flow control, acknowledgement,
    windowing Transport
  •      (v)    Coordinating communications between
    systems Session
  •      (vi)    Synchronizing sending and receiving
    applications Application
  •  
  • c) At which layer of the OSI reference model are
    the following components positioned? (4 marks)
  •                   (i)        Router Layer 3 -
    Network
  •                   (ii)        Repeater Layer 1
    Physical
  •                   (iii)        Switch Layer 2
    Data Link
  •                   (iv)        Hub Layer 1 -
    Physical

9
Answer to Problem 4
  • a) A noiseless channel has a bandwidth of 10kHz.
    If digital quaternary signaling is used (i.e.
    four voltage levels per symbol)
  •  (i)   What is the maximum bit rate (capacity) of
    the channel? (4 marks)
  •  
  • The maximum bit rate for a noiseless channel of
    10kHz bandwidth with quaternary signalling is 2 x
    BW x log2n 2 x 10 kHz x 2 40kbps, using
    Nyquist equation.
  •  
  •  (ii) How would (i) change if the channel signal
    to noise ratio is 30dB? (4 marks)
  • If the channel SNRdB30 dB then we must use
    Shannons equation, that is
  • Maximum bit rate BW x log2(1SNR).
  • For a SNRdB of 30dB, the SNR ratio is 1031000
    since 10 log10(SNR)30 dB
  • So, the maximum bit rate is 10kHz x
    log2(11000)99.67kbps

10
Answer to Problem 4
  • (iii) One way to increase the maximum bit rate is
    to change the encoding and use phase modulation
    together with amplitude modulation. This will
    increase channel capacity. For the constellation
    pattern shown below, find the maximum bit rate of
    the channel, assuming that the channel is noise
    free. (4 marks)
  •  
  •  
  •  
  •  
  •  
  •  
  •  
  •  
  • Assuming a noiseless channel, the maximum bit
    rate is 2 x BW x log2(n) 2 x 10kHz x 3
    60kbps, where n8 states.
  •  

11
Answer to Problem 4
  •  
  • (b) A signal described by the following equation
    is inserted through a noisy channel of 13dB
    signal-to-noise ratio. What is the maximum
    achievable data rate? (6 marks)
  •  

    where k 1, 3, 5
  •  
  • The above equation can be expanded as follows
  • s(t)(4/p)sin(20000t)(1/3)sin(60000t)(1/5)si
    n(100000t)
  •  
  • This equation is in analogy with the general
    Fourier series equation for k1, 3, 5 i.e.
  • s(t)(4/p)sin(2pft)(1/3)sin(2p(3f)t)(1/5)sin
    (2p(5f)t)
  •  
  • Bandwidth is the highest frequency component
    minus the lowest frequency component of the
    signal. The highest frequency component is given
    by sin(2p(5f)t) and the lowest by sin(2pft). So,
  • 2pft20000t gt 2pflowestt 20000t gt
    flowest20000/2p 3.183kHz
  • 2p(5f)t100000t gt 2pfhighestt 100000t gt
    fhighest 100000/2p 15.915kHz
  • Bandwidth fhighest - flowest 15.915 3.183
    12.732kHz
  •  
  • For a SNRdB of 13dB, SNRdB10 log10(SNR)13 dB,
    so SNR ratio is 101.319.95
  • Maximum data rate as given by Shannons equation
    is
  • BW x log2(1SNR) 12732 x log2(119.95)
    55.88kbps

12
Answer to Problem 5
  • a) Briefly differentiate between copper and fiber
    optic cables for establishing a communication
    channel in terms of bandwidth, interference, flow
    of information and cost. (8 marks)
  •  
  •  
  • b) A leased line is known to have a loss of 40dB.
    The output signal power is measured as 7mW and
    the output noise level is measured as 3.5µW.
    Using this information calculate the output
    signal-to-noise ratio in dB. (6 marks)
  •  
  • SNRdB10 log10 (SNR) 10 log10(Pout/Nout)
    10log10(7x10-3/3.5x10-6) 33dB
  •  

Metric Fiber Copper Bandwidth
High Low Interference Low High Flow of
Information Uni-directional Bi-directional Cost
High Low
13
Answer to Problem 6
  • (a) By halving the transmission frequency as well
    as halving the distance between transmitting and
    receiving antennas by how many decibels is the
    received signal power improved or reduced? (8
    marks)
  •  
  • Assume that tx and rx antennas are d1 meters
    apart at a frequency f1. Then (Pt/Pr)1
    (4pd1)2/?12 (4p f1 d1)2/c2
  • If frequency is halved, i.e. f2f1/2, and
    distance is halved, i.e. d2d1/2 then
  • (Pt/Pr)2 (4pd2)2/?22 (4p f2 d2)2/c2 (4p
    (f1/2) (d1/2))2/c2
  • (1/16)(4p f1 d1)2/c2 (1/16)(Pt/Pr)1
  • Therefore, signal reduces by 10log10 (Pt/Pr)2 /
    (Pt/Pr)1 10log10 (1/16) -12dB

14
Answer to Problem 6
  • b) You are receiving television signals from a
    synchronous geostationary satellite 40,000 km
    away at 11.75 GHz using a parabolic antenna.
  •    (i) What is the free space loss in decibels?
    (5 marks)
  •  
  • The free space loss in ratio is Pt/Pr (4pd)2/?2
    (4p f d)2/c2
  • or, in decibels LdB 10 log10 (Pt/Pr)
    -20log(?) 20log(d) 21.98 dB
  •  
  •  where Pt signal power at tx antenna, ?
    carrier wavelength in m
  • Pr signal power at rx antenna, f carrier
    frequency,
  • c speed of light (3x108 m/s), d distance
    between antennas in m
  •  
  • Since f11.75GHz, then ?c/f 3x108/11.75x109
    0.02553 meters
  • Hence, LdB -20log(?) 20log(d) 21.98 dB gt
    -20log(0.02553)
    20log(40000x103) 21.98
  • 31.87 152.04 21.98
    205.9dB

15
Answer to Problem 6
  • (ii) Assuming that the antenna gain of both the
    satellite and ground-based earth station are 45dB
    and 50dB, respectively, and that the earth
    station transmits at an output power of 200W,
    what is the power received at the satellite
    antenna? (6 marks)
  •  
  • Assuming that the antenna gain of both the
    satellite and ground-based earth station are 45dB
    and 50dB the free space loss is
  • LdB 205.9 45 50 110.9dB
  • Since the Earth station transmits at an output
    power of 200W, a power of 200W translates into
    10log(200) 23dBW, so the power received at the
    receiving satellite antenna is 23-110.9 -87.9
    dB
  • PowerdB10 log10Power-87.9 dB gt

  • Power10(-87.9/10)1.62x10-9 1.62nW
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