1. Chapter 3 Pulse Modulation
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2. Haykin/Communication Systems, 4th Ed
Chapter Outline
Sampling: is basic to all forms of pulse modulation.
Pulse-amplitude modulation (PAM): is the simplest form of modulation.
Quantization: when combined with sampling, permits to digitize analog signals.
Pulse-code modulation (PCM): is the standard method used to transmit analog signals by digital means.
Time-division multiplexing: provides for the time sharing by a common channel.
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3. Chapter Outline (Continued)
Digital multiplexers: combines many slow bit streams into a single faster stream.
Other forms of PCM: delta modulation (DM) and differential PCM (DPCM).
Linear prediction: is a basic form of encoding analog message signals at low bit rates as in DPCM.
Adaptive forms of DPCM and DM.
The MPEG-1/audio coding standard: is a transpa-rent, perceptually loss-less compression system for audio signals.
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4. Haykin/Communication Systems, 4th Ed
Sampling Process
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5. Sampling Process (Continued)
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6. Sampling Process (Continued)
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7. Haykin/Communication Systems, 4th Ed
Figure 3.1 The sampling process. (a) Analog signal. (b) Instantaneously sampled version of the analog signal.
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8. Haykin/Communication Systems, 4th Ed
Figure 3.2 (a) Spectrum of a strictly band-limited signal g(t). (b) Spectrum of the sampled version of g(t) for a sampling period Ts = 1/2 W.
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9. Signal Reconstruction
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10. Signal Reconstruction (Cont’d)
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11. Haykin/Communication Systems, 4th Ed
Sampling Theorem
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12. Haykin/Communication Systems, 4th Ed
Aliasing Effect
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13. Haykin/Communication Systems, 4th Ed
Figure 3.3 (a) Spectrum of a signal. (b) Spectrum of an undersampled version of the signal exhibiting the aliasing phenomenon.
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14. Haykin/Communication Systems, 4th Ed
Figure 3.4 (a) Anti-alias filtered spectrum of an information-bearing signal. (b) Spectrum of instantaneously sampled version of the signal, assuming the use of a sampling rate greater than the Nyquist rate. (c) Magnitude response of reconstruction filter.
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15. Haykin/Communication Systems, 4th Ed
Example
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16. Haykin/Communication Systems, 4th Ed
Example (Continued)
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17. Pulse-Amplitude Modulation
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18. Figure 3.5 Flat-top samples, representing an analog signal.
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19. Haykin/Communication Systems, 4th Ed
PAM (Continued)
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20. Haykin/Communication Systems, 4th Ed
PAM (Continued)
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21. Haykin/Communication Systems, 4th Ed
Figure 3.6 (a) Rectangular pulse h(t). (b) Spectrum H(f), made up of the magnitude |H(f)|, and phase arg[H(f)].
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22. Haykin/Communication Systems, 4th Ed
Figure 3.7 System for recovering message signal m(t) from PAM signal s(t).
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23. Other Forms of Pulse Modulation
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24. Haykin/Communication Systems, 4th Ed
Figure 3.8 Illustrating two different forms of pulse-time modulation for the case of a sinusoidal modulating wave. (a) Modulating wave. (b) Pulse carrier. (c) PDM wave. (d) PPM wave.
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25. Bandwidth-Noise Trade-off
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26. Haykin/Communication Systems, 4th Ed
Quantization Process
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27. Quantization Process (Cont’d)
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28. Quantization Process (Cont’d)
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29. Figure 3.9 Description of a memoryless quantizer.
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30. Figure 3.10 Two types of quantization: (a) midtread and (b) midrise.
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31. Haykin/Communication Systems, 4th Ed
Figure 3.11 Illustration of the quantization process. (Adapted from Bennett, 1948, with permission of AT&T.)
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32. Haykin/Communication Systems, 4th Ed
Figure 3.12 Illustrating the partitioning of the dynamic range A  m  A of a message signal m(t) into a set of L cells.
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33. Haykin/Communication Systems, 4th Ed
Example
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34. Haykin/Communication Systems, 4th Ed
Example (Continued)
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35. Pulse-Code Modulation
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36. Pulse-Code Modulation (Cont’d)
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37. Figure 3.13 The basic elements of a PCM system.
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38. Figure 3.14 Compression laws. (a) m -law. (b) A-law.
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39. Pulse-Code Modulation (Cont’d)
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40. Haykin/Communication Systems, 4th Ed
Figure 3.15 Line codes for the electrical representations of binary data. (a) Unipolar NRZ signaling. (b) Polar NRZ signaling. (c) Unipolar RZ signaling. (d) Bipolar RZ signaling. (e) Split-phase or Manchester code.
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41. Haykin/Communication Systems, 4th Ed
Figure 3.16a Power spectra of line codes: (a) Unipolar NRZ signal. The frequency is normalized with respect to the bit rate 1/Tb, and the average power is normalized to unity.
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42. Haykin/Communication Systems, 4th Ed
Figure 3.16b Power spectra of line codes: (b) Polar NRZ signal. The frequency is normalized with respect to the bit rate 1/Tb, and the average power is normalized to unity.
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43. Haykin/Communication Systems, 4th Ed
Figure 3.16c Power spectra of line codes: (c) Unipolar RZ signal. The frequency is normalized with respect to the bit rate 1/Tb, and the average power is normalized to unity.
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44. Haykin/Communication Systems, 4th Ed
Figure 3.16d Power spectra of line codes: (d) Bipolar RZ signal. The frequency is normalized with respect to the bit rate 1/Tb, and the average power is normalized to unity.
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45. Haykin/Communication Systems, 4th Ed
Figure 3.16e Power spectra of line codes: (e) Manchester-encoded signal. The frequency is normalized with respect to the bit rate 1/Tb, and the average power is normalized to unity.
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46. Pulse-Code Modulation (Cont’d)
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47. Haykin/Communication Systems, 4th Ed
Noise in PCM Systems
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48. Haykin/Communication Systems, 4th Ed
Figure 3.17 (a) Original binary data. (b) Differentially encoded data, assuming reference bit 1. (c) Waveform of differentially encoded data using unipolar NRZ signaling.
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49. Figure 3.18 Block diagram of regenerative repeater.
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50. Time-Division Multiplexing
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51. Figure 3.19 Block diagram of TDM system.
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52. Haykin/Communication Systems, 4th Ed
Digital Multiplexers
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53. Figure 3.20 Conceptual diagram of multiplexing-demultiplexing.
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54. Digital Multiplexers (Continued)
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55. Digital Multiplexers (Continued)
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56. Figure 3.21 Signal format of AT&T M12 multiplexer.
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57. Virtues and Limitations of PCM
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58. Haykin/Communication Systems, 4th Ed
Delta Modulation (DM)
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59. Delta Modulation (Cont’d)
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60. Delta Modulation (Cont’d)
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61. Figure 3.22 Illustration of delta modulation.
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62. Figure 3.23 DM system. (a) Transmitter. (b) Receiver.
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63. Haykin/Communication Systems, 4th Ed
Figure 3.24 Illustration of the two different forms of quantization error in delta modulation.
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64. Delta-Sigma Modulation
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65. Figure 3.25 Two equivalent versions of delta-sigma modulation system.
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66. Haykin/Communication Systems, 4th Ed
Linear Prediction
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67. Linear Prediction (Continued)
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68. Linear Prediction (Continued)
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69. Figure 3.26 Block diagram of a linear prediction filter of order p.
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70. Haykin/Communication Systems, 4th Ed
Figure 3.27 Block diagram illustrating the linear adaptive prediction process.
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71. Differential PCM (DPCM)
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72. Differential PCM (Continued)
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73. Figure 3.28 DPCM system. (a) Transmitter. (b) Receiver.
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74. Haykin/Communication Systems, 4th Ed
Adaptive DPCM
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75. Adaptive DPCM (Continued)
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76. Figure 3.29 Adaptive quantization with backward estimation (AQB).
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77. Figure 3.30 Adaptive prediction with backward estimation (APB).
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78. Computer Experiment: Adaptive delta Modulation
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79. Haykin/Communication Systems, 4th Ed
Figure 3.31 Adaptive delta modulation system: (a) Transmitter. (b) Receiver.
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80. Haykin/Communication Systems, 4th Ed
Figure 3.32 Waveforms resulting from the computer experiment on delta modulation: (a) Linear delta modulation. (b) Adaptive delta modulation.
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81. MPEG/Audio Coding System
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82. MPEG/Audio Coding System (Continued)
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83. Haykin/Communication Systems, 4th Ed
Figure 3.33 Illustrating the definitions of masking threshold and related parameters. The high-level signal (masker) lies inside the darker-shaded critical band, hence the masking is more effective in this band than in the neighboring band shown in lighter shading. (Adapted from Noll (1998) with permission of the CRC Press.)
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84. Figure 3.34 MPEG/Audio coding system. (a) Transmitter. (b) Receiver.
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85. Haykin/Communication Systems, 4th Ed
Figure P3.5
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86. Haykin/Communication Systems, 4th Ed
Figure P3.22
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87. Haykin/Communication Systems, 4th Ed
Figure P3.37
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