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Title: Chapter 1 INTRODUCTION


1
Chapter 1INTRODUCTION
  • Propagation of Electromagnetic Waves
  • Information Measure
  • Channel Capacity and Ideal Communication Systems

Huseyin Bilgekul Eeng360 Communication Systems
I Department of Electrical and Electronic
Engineering Eastern Mediterranean University
2
Frequency Bands
  • Regulations specify, modulation type, bandwidth,
    power, type of information and etc. that a user
    can transmit over designed frequency bands.
  • Frequency assignments and technical standards are
    set internationally by International
    Telecommunication Union (ITU).
  • Each nation of ITU retains sovregnity over
    spectral usage and standards adopted in its
    territory.
  • Each nation is expected to abide by the overall
    frequency plan adopted by ITU.

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Propagation of Electromagnetic Waves
  • The propagation characteristics of
    electromagnetic waves used in wireless channels
    are highly dependent on the frequency.
  • Based on carrier frequency EM wave propagations
    can be classified as
  • GROUND-WAVE PROPAGATION
  • SKY-WAVE PROPAGATION
  • Line of Sight (LOS) PROPAGATION

7
Ionized Regions Above Earth.
  • Ionization of air is caused by UV rays from
    the sun.
  • Ionized air shows different properties at
    different levels (Density and pressure).
  • Speed of the wave differs with the changing
    properties.
  • Dominant regions are named as D, E, F1 and F2 .

8
GROUND-WAVE PROPAGATION
  • Dominant mode of propagation for frequencies
    below 2 MHz.
  • Diffraction of the wave causes the wave to
    propagate along the surface of the earth.
  • This propagation mode is used in AM Radio
    Broadcasting.
  • Diffraction of waves in D layer helps
    propagation along the surface of earth.

9
SKY-WAVE PROPAGATION
  • Dominant mode of propagation for EM waves in the
    frequency range of 2 MHz to 30 MHz.
  • Long coverage is obtained by reflection of wave
    at the ionosphere and at the Earths boundary.
  • This mode is used in HF band International
    Broadcasting (Shortwave Radio).
  • Sky-wave propagation is caused primarily by
    reflection from the F layer (90 to 250 miles in
    altitude).

10
SKY-WAVE PROPAGATION
  • The refraction index of the ionosphere can be
    approximated as
  • Where,
  • n -- Refractive index,
  • N -- Free electron density (number of
    electrons/m3) ( 1010/m3)
  • f -- Frequency of the wave (Hz).
  • Refractive index will change gradually with the
    altitude.
  • Traveling waves will gradually bend according to
    Snells law.
  • nr Sin fr ni Sin fi
  • Waves will be bent back to earth. Ionosphere acts
    as a reflector. Transmitting station will have
    coverage areas along the surface of earth.

11
LINE-OF SIGHT (LOS) PROPAGATION
  • Dominant mode of propagation for EM waves above
    30 MHz.
  • Since the frequency is high,
  • f2 gtgt 81 N so that n 1 ( Free Space)
  • This mode can be used in Satellite
    Communications.
  • The disadvantage of LOS is that the signal path
    has to be above the horizon and the receiver
    antennas need to be placed on tall towers so
    that they can see each other.

12
LOS Calculations
  • Lets assume
  • d Distance to the horizon
  • h Antenna height...
  • r Effective radius of earth Where h ltlt r
  • Effective radius of earth 4/3 real radius

Effective radius of earth r 4/3
3960 5280 miles Converting feet to mile
Example For a television station with an h1000
ft tower, d v(2000) 44.7
miles. The transmitter will cover an area
of 44.7 miles around.
13
Measuring Information
  • Definition Information Measure (Ij)
  • The information sent from a digital source
    (Ij) when the jth massage is transmitted is given
    by
  • where Pj is the probability of transmitting the
    jth message.
  • Messages that are less likely to occur (smaller
    value for Pj) provide more information (large
    value of Ij).
  • The information measure depends on only the
    likelihood of sending the message and does not
    depend on possible interpretation of the content.
  • For units of bits, the base 2 logarithm is used
  • if natural logarithm is used, the units are
    nats
  • if the base 10 logarithm is used, the units are
    hartley.

14
Measuring Information
  • Definition Average Information (H)
  • The average information measure of a digital
    source is,
  • where m is the number of possible different
    source messages.
  • The average information is also called Entropy.
  • Definition Source Rate (R)
  • The source rate is defined as,
  • where H is the average information
  • T is the time required to send a message.

15
Measuring Information-Example1.1
  • Find the information content of message that
    consists of a digital word 12 digits long in
    which each digit may take on one of four possible
    levels. The probability of sending any of the
    four levels is assumed to be equal, and the level
    in any digit does not depend on the values taken
    on by pervious digits.
  • Answer
  • Possible combinations of 12 digits ( of
    possible messages) 412
  • Because each level is equally likely,
  • all different words are equally likely.

16
Channel Capacity Ideal Comm. Systems
  • For digital communication systems, the Optimum
    System may defined as the system that minimize
    the probability of bit error at the system output
    subject to constraints on the energy and channel
    bandwidth.
  • Is it possible to invent a system with no error
    at the output even when we have noise introduced
    into the channel?
  • Yes under certain assumptions !.
  • According Shannon the probability of error would
    approach zero, if Rlt C
  • Where
  • R - Rate of information (bits/s)
  • C - Channel capacity (bits/s)
  • B - Channel bandwidth in Hz and
  • S/N - the signal-to-noise power ratio

Capacity is the maximum amount of information
that a particular channel can transmit. It is a
theoretical upper limit. The limit can be
approached by using Error Correction
17
Channel Capacity Ideal Comm. Systems

ANALOG COMMUNICATION SYSTEMS In analog systems,
the OPTIMUM SYSTEM might be defined as the one
that achieves the Largest signal-to-noise ratio
at the receiver output, subject to design
constraints such as channel bandwidth and
transmitted power. Question Is it possible to
design a system with infinite signal-to-noise
ratio at the output when noise is introduced by
the channel? Answer No! DIMENSIONALITY
THEOREM for Digital Signalling Nyquist showed
that if a pulse represents one bit of data,
noninterfering pulses can be sent over a channel
no faster than 2B pulses/s, where B is the
channel bandwidth.
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Problems
19
Problems
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