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Title: Introduction to Analog And Digital Communications


1
Introduction to Analog And Digital Communications
  • Second Edition
  • Simon Haykin, Michael Moher

2
Chapter 10 Noise in Digital Communications
  • 10.1 Bit Error Rate
  • 10.2 Detection of a Single Pulse in Noise
  • 10.3 Optimum Detection of Binary PAM in Noise
  • 10.4 Optimum Detection of BPSK
  • 10.5 detection of QPSK and QAM in Noise
  • 10.6 Optimum Detection of Binary FSK
  • 10.7 Differential Detection in Noise
  • 10.8 Summary of Digital Performance
  • 10.9 Error Detection and Correction
  • 10.10 Summary and Discussion

3
  • Two strong external reasons for the increased
    dominance of digital communication
  • The rapid growth of machine-to-machine
    communications.
  • Digital communications gave a greater noise
    tolerance than analog
  • Broadly speaking, the purpose of detection is to
    establish the presence of an information-bearing
    signal in noise.

4
  • Lesson 1 the bit error rate is the primary
    measure of performance quality of digital
    communication systems, and it is typically a
    nonlinear function of the signal-to-noise ratio.
  • Lesson 2 Analysis of single-pulse detection
    permits a simple derivation of the principle of
    matched filtering. Matched filtering may be
    applied to the optimum detection of many linear
    digital modulation schemes.
  • Lesson 3 The bit error rate performance of
    binary pulse-amplitude modulation (PAM) improves
    exponentially with the signal-to-noise ratio in
    additive white Gaussian noise.
  • Lesson 4 Receivers for binary and quaternary
    band-pass linear modulation schemes are
    straightforward to develop from matched-filter
    principles and their performance is similar to
    binary PAM.
  • Lesson 5 Non-coherent detection of digital
    signals results in a simpler receiver structure
    but at the expense of a degradation in bit error
    rate performance.
  • Lesson 6 The provision of redundancy in the
    transmitted signal through the addition of
    parity-check bits may be used for forward-error
    correction. Forward-error correction provides a
    powerful method to improve the performance of
    digital modulation schemes.

5
10.1 Bit Error Rate
  • Average bit error rate (BER)
  • Let n denote the number of bit errors observed
    in a sequence of bits of length N then the
    relative frequency definition of BER is
  • Packet error rate (PER)
  • For vocoded speech, a BER of to is often
    considered sufficient.
  • For data transmission over wireless channels, a
    bit error rate of to is often the
    objective.
  • For video transmission, a BER of to is often the
    objective, depending upon the quality desired and
    the encoding method.
  • For financial data, a BER of or better is
    often the requirement.

6
  • SNR
  • The ratio of the modulated energy per information
    bit to the one-sided noise spectral density
    namely,
  • The analog definition was a ratio of powers. The
    digital definition is a ratio of energies, since
    the units of noise spectral density are watts/Hz,
    which is equivalent to energy. Consequently, the
    digital definition is dimensionless, as is the
    analog definition.
  • The definition uses the one-sided noise spectral
    density that is, it assumes all of the noise
    occurs on positive frequencies. This assumption
    is simply a matter of convenience.
  • The reference SNR is independent of transmission
    rate. Since it is a ratio of energies, it has
    essentially been normalized by the bit rate.

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10.2 Detection of a Single Pulse in Noise
  • The received signal consists solely
    of white Gaussian noise
  • The received signal consists of
    plus a signal of known form.
  • For the single-pulse transmission scheme
  • The received signal
  • The first integral on the right-hand side of Eq.
    (10.5) is the signal term, which will be zero if
    the pulse is absent, and the second integral is
    the noise term which is always there.

Fig. 10.1
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Fig. 10.1
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  • The variance of the output noise

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  • The noise sample at the output of the linear
    receiver has
  • A mean of zero.
  • A variance of
  • A Gaussian distribution, since a filtered a
    Gussian process is also Gaussian (see Section
    8.9).
  • The signal component of Eq.(10.5)
  • Schwarz inequality for integrals is

12
  • With defined by Eq.(10.1), the signal
    component of this correlation is maximized at
    This emphasizes the importance of
    synchronization when performing optimum detection.

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10.3 Optimum Detection of Binary PAM in Noise
  • Consider binary PAM transmission with on-off
    signaling
  • The output of the matched filter receiver at the
    end of the kth symbol interval is
  • Since the matched filter wherever it is
    nonzero, we have

Fig. 10.2
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Fig. 10.2
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  • BER performance
  • Consider the probability of making an error with
    this decision rule based on conditional
    probabilities. If a 1 is transmitted, the
    probability of an error is

Fig. 10.3
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Fig. 10.3
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  • Type II error.
  • An error can also occur if a 0 is transmitted and
    a 1 is detected
  • The probability regions associated with Type I
    and Type II errors are illustrated in Fig. 10.5.
    The combined probability of error is given by
    Bayes rule (see Section 8.1)

Fig. 10.4
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Fig. 10.4
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  • A priori probability
  • The average probability of error is given
  • Average probability of error

Fig. 10.5
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Fig. 10.5
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  • Our next step is to express this probability of
    bit error in terms of the digital reference
    model.
  • To express the variance in terms of the noise
    spectral density, we have, from Eq.(10.9), that
  • To express the signal amplitude A in terms of the
    energy per bit , we assume that 0 and 1 are
    equally likely to be transmitted. Then the
    average energy per bit at the receiver input is

22
  • Nonrectangular pulse shapes
  • The received signal
  • P(t) is a normalized root-raised cosine pulse
    shape

23
  • Applying the matched filter for the kth symbol
    of to Eq.(10.31), we get
  • Under these conditions, and the BER
    performance es the same as with rectangular pulse
    shaping

Fig. 10.6
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Fig. 10.6
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10.4 Optimum Detection of BPSK
  • One of the simplest forms of digital band-pass
    connunications is binary phase-shift keying. With
    BPSK, the transmitted signal is

Fig. 10.7
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Fig. 10.7
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  • Detection of BPSK in noise
  • The signal plus band-pass noise at the input to
    the coherent BPSK detector
  • The output of the product modulator
  • The matched filter

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  • The output of the integrate-and-dump detector in
    this
  • The noise term in Eq.(10.40) is given by

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  • In digital communications, the objective is to
    recover the information, 0s and1s, as possible.
    Unlike analog communications, there is no
    requirement that the transmitted waveform should
    be recovered be recovered with minimum
    distortion.
  • Performance analysis
  • If we assume a 1 was transmitted and then the
    probability of error is
  • The bit error rate

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  • The analysis of BPSK can be extended to
    nonrectangular pulse shaping in a manner similar
    to what occurred at baseband. For nonrectangular
    pulse shaping, we represent the transmitted
    signal as

31
10.5 detection of QPSK and QAM in Noise
  • Detection of QPSK in niose
  • That QPSKmodulated signal

32
  • Using in-phase and quadrature representation for
    the band-pass noise, we find that the QPSK input
    to the coherent detector of Fig.10.8 is described
    by
  • The intermediate output of the upper branch of
    Fig.10.8 is
  • The output of the lower branch of the quadrature
    detector is

Fig. 10.8
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Fig. 10.8
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  • For the in-phase component, then the mean output
    is
  • The first bit of the dibit is a 1 then
  • The probability of error on the in-phase branch
    of the QPSK signal is

35
  • The average energy by bit may be determined from
  • The bit error rate with after matched filtering
    is given by

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  • In terms of energy per bit, the QPSK performance
    is exactly the same as BPSK
  • Double-sideband and single-sideband transmission,
    we found that we could obtain the same quality of
    performance but with half of the transmission
    bandwidth. With QPSK modulation, we use the same
    transmission bandwidth as BPSK but transmit twice
    as many bits with the same reliability.
  • Offset-QPSK or OQPSK is a variant of QPSK
    modulation
  • The OQPSK and QPSK, the bit error rate
    performance of both schemes is identical if the
    transmission path does not distort the single.
  • One advantage of OQPSK is its reduced phase
    variations and potentially less distortion if the
    transmission path includes nonlinear components
    such as an amplifier operating near or at
    saturation. Under such nonlinear conditions,
    OQPSK may perform better than QPSK.

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  • Detection of QAM in noise
  • The baseband modulated signal be represented by

Fig. 10.9
Fig. 10.10
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Fig. 10.9
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Fig. 10.10
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  • There are two important differences that should
    be noted
  • Equation (10.57) represents a symbol error rate.
  • With binary transmission with levels of A and
    A, the average transmitted power is
  • The probability of symbol error in terms of the
    digital reference SBR is
  • We may use independent PAM schemes on the
    in-phase and quadrature components. That is to
    say, one PAM signal modulates the
    in-phase carrier and the second
    PAM signal modulates the quadrature carrier
  • Due to the orthogonality of the in-phase and
    quadrature components, the error rate is the same
    on both and the same as the baseband PAM system.

Fig. 10.11
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Fig. 10.11
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10.6 Optimum Detection of Binary FSK
  • The transmitted signal for is
  • The two matched filters are
  • The corresponding waveforms are orthogonal

Fig. 10.12
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Fig. 10.12
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  • Let the received signal be
  • Then the output of the matched filter
    corresponding to a 0 is
  • The noise component at the output of the matched
    filter for a 0 is

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  • The output of the filter matched to a 1 is
  • The noise component of Eq.(10.65)
  • By analogy with bipolar PAM in Section 10.3, the
    probability of error for binary FSK is

46
  • The BER in terms of the digital reference model
    is
  • In general, we see that antipodal signaling
    provides a dB advantage over orthogonal
    signaling in bit error rate performance.

47
10.7 Differential Detection in Noise
  • band-pass signal at the output of this filter
  • The output of the delay-and-multiply circuit is

Fig. 10.13
Fig. 10.14
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Fig. 10.13
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Fig. 10.14
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  • Since in a DPSK receiver decisions are made on
    the basis of the signal received in two
    successive bit intervals, there is a tendency for
    bit errors to occur in pairs.

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10.8 Summary of Digital Performance
  • Gray encoding
  • Gray encoding of symbols where there is only a
    one-bit difference between adjacent symbols.
  • Performance comparison

Fig. 10.15
Table. 10.1
Fig. 10.16
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Fig. 10.15
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Table. 10.1
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Fig. 10.16
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  • Noise in signal-space models
  • QPSK may be represented
  • The basis functions are

Fig. 10.17
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Fig. 10.17
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  • The remaining two orthonormal functions are given
    by
  • Under the band-pass assumption, the functions
    and are clearly orthogonal with each other
    and, since they are zero whenever and
    are nonzero, they are also orthogonal to these
    functions.

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10.9 Error Detection and Correction
  • In radio (wireless) channels, the received signal
    strength may vary with time due to fading.
  • In satellite applications, the satellite has
    limited transmitter power.
  • In some cable transmission systems, cables may be
    bundled together so closely that there may be
    crosstalk between the wires.
  • We can achieve the goal of improved bit error
    rate performance by adding some redundancy into
    the transmitted sequence. The purpose of this
    redundancy is to allow the receiver to detect
    and/or correct errors that are introduced during
    transmission.
  • Forward-error correction (FEC)
  • The incoming digital message (information bits)
    are encoded to produce the channel bits. The
    channel bits include the information bits,
    possibly in a modified form, plus additional bits
    that are used for error correction.
  • The channel bits are modulated and transmitted
    over the channel.
  • The received signal plus noise is demodulated to
    produce the estimated channel bits.
  • The estimated channel bits are then decoded to
    provide an estimate of the original digital
    message.

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  • Let bits be represented by 0 and 1 values.
  • Let represent mudulo-2 addition. When this
    operation is applied to pairs of bits we obtain
    the results and
  • The operator may also be applied to blocks
    of bits, where it means the modulo-2 sum of the
    respective elements of the blocks. For example,
  • Suppose we add the parity-check bit p such that
  • The error detection capability of a code as the
    maximum number of errors that the receiver can
    always detect in the transmitted code word.

Fig. 10.18
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Fig. 10.18
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  • Error detection with block codes
  • Hamming weight of a binary block as the number of
    1s in the block.
  • Hamming distance between any two binary blocks is
    the number of places in which they differ.
  • The single parity check code can always detect a
    single bit error in the received binary block.

Table. 10.2
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Table. 10.2
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  • Error correction
  • The objective when designing a forward
    error-correction code is to add parity bits to
    increase the minimum Hamming distance, as this
    improves both the error detection and
    error-correction capabilities of the code.
  • Hamming codes
  • Hamming coeds are a family of codes with block
    lengths
  • There are parity bits and information bits.

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  • The first step
  • The encoding that occurs at the transmitter this
    requires the calculation of the parity bits based
    on the information bits. The second step is the
    decoding that occurs at the receiver this
    requires the evaluation of the parity checksums
    to determine if, and where, the parity equations
    have been violated.
  • K-by-n generator matrix

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  • The elements of C are given by
  • Hamming code we may define the (n - k)-by-n
    parity check matrix H as

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  • We compute the product of the received vector and
    the parity-check matrix
  • It satisfies the parity-check equations and
  • More powerful codes
  • Reed-Solomon and Bose-Chaudhuri-Hocquenghem (BCH)
    block codes.
  • These are (n, k) codes where there are k
    information bits and a total of n bits including
    n - k parity bits.
  • Convolutional codes.
  • the result of the convolution of one or more
    parity-check equations with the information bits.
  • Turbo codes
  • Block codes but use a continuous encoding
    strategy similar to convolutional codes.

Table. 10.4
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Table. 10.4
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Fig. 10.19
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Fig. 10.19
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  • Signal-space interpretation of forward-error-corre
    ction codes
  • We could construct a four-dimensional vector with
    a signal-space representation of
  • We can explain some of the concepts of coding
    theory geometrically as shown in Fig.10.20.
  • For a linear code we defined the minimum Hamming
    distance as the number of locations where the
    binary code words differ.
  • Euclidean distance

Fig. 10.20
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Fig. 10.20
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10.10 Summary and Discussion
  • Analysis of the detection of a single pulse in
    noise shows the optimality of matched filtering.
    We showed that the bit error rate performance
    using matched filtering was closely related to
    the Q-function that was defined in Chapter 8.
  • We showed how the principle of matched filtering
    may be extended to the detection of
    pulse-amplitude modulation, and that bit error
    rate performance may be determined in a manner
    similar to single-pulse detection.
  • We discussed how the receiver structure for the
    coherent detection of band-pass modulation
    strategies such as BPSK, QPSK, and QAM was
    similar to coherent detection of corresponding
    analog signals.

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  • We showed how quadrature modulation schemes such
    as QPSK and QAM provide the same performance as
    their one-dimensional counterparts of BPSK and
    PAM, due to the orthogonality of the in-phase and
    quadrature components of the modulated signals.
  • Antipodal strategies such as BPSK are more power
    efficient than orthogonal transmission strategies
    such as on-off signaling and FSK.
  • We introduced the concept of non-coherent
    detection when we illustrated that BPSK could be
    detected using a new approach where the
    transmitted bits are differentially encoded. The
    simplicity of this detection technique results in
    a small BER performance penalty.
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