Communication System Overview - PowerPoint PPT Presentation

1 / 49
About This Presentation
Title:

Communication System Overview

Description:

Messages can be categorized as analog (continuous form)or digital ... Trellis code. Turbo code. 4/6. Wireless Access Tech. Lab. CCU. Wireless Access Tech. Lab. ... – PowerPoint PPT presentation

Number of Views:215
Avg rating:3.0/5.0
Slides: 50
Provided by: ray85
Category:

less

Transcript and Presenter's Notes

Title: Communication System Overview


1
Communication System Overview
  • Gwo-Ruey Lee

2
Outlines
  • Communication System
  • Digital Communication System
  • Modulation

3
Communication System
1/6
  • Input Transducer
  • Transmitter
  • Channel
  • Receiver
  • Output Transducer

4
Communication System
2/6
  • Input transducer
  • Messages can be categorized as analog (continuous
    form)or digital (discrete form).
  • The message produced by a source must be
    converted by a transducer to a form suitable for
    the particular type of communication system
    employed.

5
Communication System
3/6
  • Transmitter
  • The purpose of the transmitter is to couple the
    message to the channel.
  • Modulation
  • For ease of radiation
  • to reduce noise and interference
  • For channel assignment
  • For multiplexing or transmission of several
    message over a single channel
  • To overcome equipment limitation

6
Communication System
4/6
  • Channel
  • Different forms
  • The signal undergoes degradation from transmitter
    to receiver
  • Noise, fading, interference

7
Communication System
5/6
  • Receiver
  • The receiver is to extract the desired message
    from the received signal at the channel output
    and to convert it to a form suitable for the
    output transducer
  • Demodulation

8
Communication System
6/6
  • Output Transducer
  • The output transducer completes the
    communication system
  • The device converts the electric signal at its
    input into the form desired for the system user

9
Digital Communication System
1/6
10
Digital Communication System
2/6
  • Source Encoder/ Decoder
  • The purpose of source coding is to reduce the
    number of bits required to convey the information
    provided by the information source.
  • The task of source coding is to represent the
    source information with the minimum of symbols.
  • High compression rates (Good compression rates)
    make be achieved with source encoding with
    lossless or little loss of information.
  • Source Coding
  • Fixed-length coding
  • Pulse-code modulation (PCM)
  • Differential Pulse-code modulation (DPCM)
  • Variable-length coding
  • Huffman Coding/ entropy coding

11
Digital Communication System
3/6
  • Channel Encoder/ Decoder
  • A way of encoding data in a communications
    channel that adds patterns of redundancy into the
    transmission path in order to lower the error
    rate.
  • The task of channel coding is to represent the
    source information in a manner that minimizes the
    error probability in decoding.
  • Error Control Coding
  • Error detection coding
  • Error correct coding

12
Digital Communication System
4/6
  • Error Control Coding
  • Linear block code
  • Convolutional code
  • RS code
  • Modulation Coding
  • Trellis code
  • Turbo code

13
Digital Communication System
5/6
  • Synchronization
  • Symbol/ Timing synchronization
  • Frequency synchronization
  • Carrier frequency synchronization
  • Sampling frequency synchronization
  • Two basic types of synchronization
  • Data-aid algorithm
  • Training sequences
  • Preambles
  • Non-data-aid algorithm
  • Blind

14
Digital Communication System
6/6
  • Channel Estimation
  • A channel estimate is only a mathematical
    estimation of what is truly happening in nature.
  • Allows the receiver to approximate the effect of
    the channel on the signal.
  • The channel estimate is essential for removing
    inter symbol interference, noise rejection
    techniques etc.
  • Two basic types of channel estimation methods
  • Data-aid algorithm
  • Training sequences
  • pilots
  • Non-data-aid algorithm
  • Blind

15
Modulation
1/10
  • Analog Modulation
  • AM
  • FM
  • PM
  • Pulse Modulation
  • PAM / PPM / PCM / PWM
  • Digital Modulation
  • ASK
  • FSK
  • PSK
  • QAM

16
Modulation
2/10
  • Mapping
  • The process of mapping the information bits onto
    the signal constellation plays a fundamental role
    in determining the properties of the modulation
  • Modulation type
  • Phase shift keying (PSK)
  • Quadrature Amplitude Modulation (QAM)

17
Modulation
3/10
  • M-ary Phase Shift Keying
  • Consider M-ary phase-shift keying (M-PSK) for
    which the signal set is
  • where is the signal energy per symbol,
    is the symbol duration, and is the
    carrier frequency.
  • This phase of the carrier takes on one of the M
    possible values, namely,
    , where .

18
Modulation
4/10
  • An example of signal-space diagram for 8-PSK

19
Modulation
5/10
  • Phase shift keying
  • BPSK
  • QPSK with Gray code
  • M-ary PSK
  • where

20
Modulation
6/10
  • BER versus SNR curves in AWGN channel using BPSK,
    QPSK, 8-PSK,16-PSK .

21
Modulation
7/10
  • Quadrature Amplitude Modulation
  • The transmitted M-ary QAM signal for symbol n can
    be expressed as
  • where E is the energy of the signal with the
    lowest amplitude, and , and
    are amplitudes taking on the values
  • Note that M is assumed to be a power of 4.
  • The parameter a can be related to the average
    signal energy ( ) by

22
Modulation
8/10
  • An example of signal-space diagram for 16-square
    QAM.

23
Modulation
9/10
  • QAM

24
Modulation
10/10
  • BER versus SNR curves in AWGN channel using
    BPSK/QPSK, 16QAM, 64QAM, 256QAM.

25
Communication System Overview
  • Readings
  • Any book about communications

26
Random Process/ Stochastic Process
27
Outlines
1/10
  • Basic Concepts
  • Stationary Process
  • Transmission over Linear Time-Invariant (LTI)
    Systems

28
Basic Concepts
2/10
  • Why study random processes?
  • Due to the uncertainty of 1. noise and 2. the
    unpredictable nature of information itself.
  • Information signal usually is randomlike
  • We can not predict the exact value of the signal
  • Signal must be distributed by its statistical
    properties.
  • Ex mean, variance..

29
Basic Concepts
3/10
  • Random Variable (r.v.)
  • Consider an experiment with sample space . The
    element of are the random outcomes, , of
    the experiment. If to every , we assign a
    real value , such a rule is
    called a random variable (r.v.)

30
Basic Concepts
4/10
  • Random Process (r.p.)
  • A random process is the mapping of the outcomes
    in into a set of real valued functions of
    time, called sample function .

31
Basic Concepts
5/10
  • Classification of random process
  • From the perspective of time
  • Random process
  • for , t has a continuous of values
  • Random sequence
  • for , t can take on a finite or
    countably infinite number of values ?
  • From the perspective of the value of
  • Continuous
  • can take on a continuous of values
  • Discrete
  • Values of are countable

32
Basic Concepts
6/10
  • Classification of random process
  • Continuous random process
  • Discrete random process
  • Continuous random sequence
  • Discrete random sequence

33
Basic Concepts
7/10
  • 1st-order distributions function
  • It describes the instantaneous amplitude
    distribution of a random process
  • Mean
  • 2nd-order distributions function
  • It distributes the structure of the signal in
    the time domain
  • Autocorrelation Function (A.F.)

34
Basic Concepts
8/10
  • Autocovariance
  • Cross-correlation
  • If and are orthogonal ?
  • If and are statistically
    uncorrelated ?

35
Basic Concepts
9/10
  • Crosscovariance
  • The autocorrelation function of a real WSS
    process is

36
Basic Concepts
10/10
  • The cross-correlation function of two real WSS
    process
  • and is
  • If and are orthogonal ?
  • If and are statistically
    uncorrelated ?
  • Power Spectral Density (PSD)
  • PSD represents the distribution of signal
    strength (ie, energy or power) with frequency
  • The PSD of WSS process is the Fourier
    transform (FT) of the A.F.

37
Stationary Process
1/9
  • Stationary
  • A random process whose statistical properties do
    not change over time
  • Stationary Process
  • Strictly-Sense Stationary (SSS)
  • Wide-Sense Stationary (WSS)
  • Strictly-Sense Cyclostationary
  • Wide-Sense Cyclostationary

38
Stationary Process
2/9
  • Strictly-Sense Stationary (SSS)
  • A nth-order strictly-sense stationary process is
    a process in which for all , all
    , and all
  • Note Mth-order stationary of the above equation
    holds for all .
  • Example 2nd-order SSS process ? 1st-order SSS
    process

39
Stationary Process
3/9
  • A example of 2nd-order stationary

40
Stationary Process
4/9
  • Wide-Sense Stationary (WSS)
  • A random process is wide-sense
    stationary process (WSS) if
  • Its mean is constant
  • Its A.F. depends only on the time difference.

41
Stationary Process
5/9
  • The relationship between SSS and WSS
  • SSS ? WSS (True)
  • SSS ? WSS (Fault)
  • 1st-order SSS ?
  • 2nd-order SSS ?
  • For Gaussian process SSS ? WSS
  • Since the joint-Gaussian pdf is completely
    specified by its mean and A.F.

42
Stationary Process
6/9
  • Strictly-Sense Cyclostationary
  • A nth-order strictly-sense cyclostationary
    process is a process in which for all , all
    , and integer m
  • ( mT is integer multiples of period T )

43
Stationary Process
7/9
  • Wide-Sense Cyclostationary
  • A random process with and
    is wide-sense cyclostationary if
  • Its mean satisfies
  • Its A.F. satisfies

44
Stationary Process
8/9
  • Ergodic Process
  • A random process is strictly ergodic process if
    all time and ensemble (statistical) average are
    interchangeable including mean, A.F. PSD, etc.
  • A random process is wise-sense ergodic if it it
    ergodic in the mean and the A.F.
  • mean ergodic
  • A.F. ergodic

45
Stationary Process
9/9
  • The relationship between ergodic and stationary
  • Ergodic ? stationary (True)
  • Ergodic ? stationary (Fault)

46
Transmission over LTI Systems
1/3
  • Linear Time-Invariant (LTI) Systems

47
Transmission over LTI Systems
2/3
  • Assumptions
  • and are real-valued and
    is WSS.
  • The mean of the output
  • The cross-correlation function

48
Transmission over LTI Systems
3/3
  • The A.F. of the output
  • The PSD of the output

49
Random Process/ Stochastic Process
  • Readings
  • Communication Systems, 4th edition, Simon Haykin,
    Wiley
  • Chapter 1 1.1 1.7, 1.8
Write a Comment
User Comments (0)
About PowerShow.com