Digital Communication
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DIGITAL COMMUNICATION ; 1. INTRODUCTION ; 1.1 INTRODUCTION ; 1.2 TYPICAL DIGITAL COMMUNICATION SYSTEM ; 1.3 ADVANTAGES OF DIGITAL COMMUNICATION ; 1.3.1 REGENERATION OF DIGITAL SIGNALS ; 1.3.2 POWER EFFICIENCY OF DIGITAL MODULATORS ; 1.3.3 BANDWIDTH COMPRESSION ; 1.3.4 MULTIMEDIA: UNIFICATION OF SIGNALS ; 1.3.5 PERFORMANCE ; 1.3.6 TECHNOLOGY ; 2. COMMUNICATION SIGNALS AND SYSTEMS ; 2.1 INTRODUCTION ; 2.2 TIME AND FREQUENCY REPRESENTATION ; 2.1.1 FOURIER SERIES ; 2.1.2 FOURIER TRANSFORM ; 2.1.3 DISCRETE-TIME FOURIER TRANSFORM ; 2.1.4 DISCRETE FOURIER TRANSFORM ; 2.3 CONVOLUTION ; 2.4 CORRELATION ; 2.5 HILBERT TRANSFORM ; 2.6 BANDPASS AND LOWPASS REPRESENTATIONS ; 2.6.1 BANDPASS SIGNALS AND SYSTEMS ; 2.6.2 ANALYTIC SIGNAL ; 2.6.3 LOWPASS EQUIVALENT SIGNALS ; 2.7 SIGNAL SPACE REPRESENTATIONS ; 2.7.1 VECTOR SPACE ; 2.7.2 SIGNAL SPACE ; 2.7.3 ORTHONORMAL REPRESENTATION OF SIGNALS ; 2.7.4 GRAM-SCHMIDT PROCEDURE ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 3. PROBABILITY AND RANDOM PROCESSES ; 3.1 INTRODUCTION ; 3.2 PROBABILITY ; 3.2.1 SET THEORY ; 3.2.2 PROBABILITY SPACE ; 3.2.3 PROPERTIES OF PROBABILITY ; 3.2.4 PROBABILITY OF JOINT EVENTS ; 3.2.5 CONDITIONAL PROBABILITY ; 3.2.6 BAYES' RULE ; 3.2.7 INDEPENDENCE ; 3.3 RANDOM VARIABLES ; 3.3.1 PROBABILITY DISTRIBUTION FUNCTION ; 3.3.2 PROBABILITY DENSITY FUNCTION ; 3.3.3 PROBABILITY MASS FUNCTION ; 3.3.4 MEAN AND VARIANCE ; 3.3.5 SOME COMMON DISTRIBUTIONS ; 3.3.6 FUNCTIONS OF RANDOM VARIABLES ; 3.3.7 MULTIPLE RANDOM VARIABLES ; 3.3.8 SUM OF RANDOM VARIABLES ; 3.3.9 CENTRAL LIMIT THEOREM ; 3.3.10 LINEAR MEAN SQUARE ESTIMATION ; 3.4 RANDOM PROCESSES ; 3.4.1 PROPERTIES OF RANDOM PROCESSES ; 3.4.2 SOME EXAMPLES OF RANDOM PROCESSES ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 4. INFORMATION THEORY ; 4.1 INTRODUCTION ; 4.2 INFORMATION MEASURE ; 4.2.1 SELF-INFORMATION ; 4.2.2 ENTROPY ; 4.2.3 DISCRETE MEMORYLESS SOURCE (DMS) ; 4.2.4 JOINT AND CONDITIONAL ENTROPY ; 4.2.5 MUTUAL INFORMATION ; 4.3 DISCRETE CHANNEL ; 4.3.1 STATISTICS OF THE DISCRETE CHANNEL ; 4.3.2 CHANNEL CAPACITY ; 4.4 CONTINUOUS RANDOM VARIABLE ; 4.4.1 DIFFERENTIAL ENTROPY ; 4.4.2 CAPACITY OF CONTINUOUS CHANNEL ; 4.5 SOURCE CODING ; 4.5.1 SOURCE EFFICIENCY AND REDUNDANCY ; 4.5.2 KRAFT INEQUALITY ; 4.5.3 SOURCE CODING THEOREM ; 4.5.4 SHANNON-FANO ENCODING ; 4.5.5 HUFFMAN CODING ; 4.5.6 NON-BINARY HUFFMAN CODING ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 5. DIGITAL CODING ; 5.1 INTRODUCTION ; 5.2 DIGITIZING ANALOG SIGNALS ; 5.2.1 SAMPLING ; 5.2.1.1 SAMPLING WITH IDEAL IMPULSES ; 5.2.1.2 SPECTRA OF SAMPLED WAVEFORM ; 5.2.1.3 SAMPLING RATE AND ALIASING NOISE ; 5.2.1.4 SAMPLING OF BANDPASS SIGNALS ; 5.2.1.5 SAMPLE AND HOLD ; 5.2.1.6 SPECTRAL DISTORTION DUE TO SAMPLE AND HOLD ; 5.2.2 QUANTIZATION ; 5.2.2.1 QUANTIZER CHARACTERISTICS ; 5.2.2.2 QUANTIZATION ERROR ; 5.2.3 ENCODING ; 5.2.3.1 ANALOG TO DIGITAL CONVERSION ; 5.2.3.2 SIGMA-DELTA A-D CONVERTER ; 5.2.3.3 PULSE CODE MODULATION (PCM) ; 5.3 SIGNAL COMPRESSION ; 5.3.1 SIGNAL STATISTICS AND REDUNDANCY ; 5.3.2 COMPANDED PCM ; 5.3.2.1 A-LAW COMPANDING ; 5.3.2.2 -LAW COMPANDING ; 5.3.2.3 SEGMENTED COMPANDERS ; 5.3.2.4 PERFORMANCE OF A PCM SYSTEM ; 5.3.3 PREDICTIVE CODING ; 5.3.3.1 DELTA MODULATION (DM) ; 5.3.3.2 ADAPTIVE DIFFERENTIAL PCM (ADPCM) ; 5.3.4 TRANSFORM CODING ; 5.3.4.1 DISCRETE COSINE TRANSFORM ; 5.3.4.2 2-D DCT ; 5.3.4.3 DISCRETE WAVELET TRANSFORM ; 5.3.5 PARAMETRIC CODERS ; 5.3.5.1 ANALYSIS-BY-SYNTHESIS CODER ; 5.3.6 PERCEPTUAL CODING ; 5.3.6.1 PSYCHOACOUSTICS ; 5.3.6.2 PERCEPTUAL CODER ; 5.4 APPLICATION OF DIGITAL CODING ; 5.4.1 DIGITAL SPEECH ; 5.4.1.1 VOICE CODECS AND COMBO CHIPS ; 5.4.2 DIGITAL AUDIO ; 5.4.2.1 MP3 CODING ; 5.4.2.2 AC-3 CODING ; 5.4.2.3 ADVANCED AUDIO CODING (AAC) ; 5.4.3 DIGITAL VIDEO ; 5.4.3.1 RUN-LENGTH CODING (RLC) ; 5.4.3.2 VARIABLE LENGTH CODING ; 5.4.3.3 MPEG-1 ; 5.4.3.4 MPEG-2 ; 5.4.3.5 MPEG4 ; 5.4.3.6 H.264 ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 6. MULTIPLEXING AND MULTIPLE ACCESS ; 6.1 INTRODUCTION ; 6.2 MULTIPLEXING ; 6.2.1 FREQUENCY DIVISION MULTIPLEXING ; 6.2.2 CONCEPT OF TIME DIVISION MULTIPLEXING ; 6.2.3 FRAME SYNCHRONIZATION ; 6.2.4 PRIMARY MULTIPLEXING IN DIGITAL TELEPHONY ; 6.2.4.1 E-1 CARRIER MULTIPLEX SYSTEM ; 6.2.4.2 SIGNALING IN E-1 CARRIER ; 6.2.4.3 FRAME SYNCHRONIZATION IN E-1 CARRIER ; 6.2.4.4 T-1 CARRIER MULTIPLEX SYSTEM ; 6.2.4.5 SIGNALING AND FRAME SYNCHRONIZATION IN T-1 CARRIER ; 6.2.4.6 COMPARISON OF THE PRIMARY MULTIPLEX STANDARDS ; 6.2.5 HIGHER ORDER MULTIPLEXING ; 6.2.5.1 CEPT PLESIOCHRONOUS DIGITAL HIERARCHY ; 6.2.5.2 NORTH AMERICAN DIGITAL HIERARCHY ; 6.3 MULTIPLE ACCESS ; 6.3.1 FREQUENCY DIVISION MULTIPLE ACCESS (FDMA) ; 6.3.1.1 SCPC AND MCPC SYSTEMS ; 6.3.1.2 CAPACITY IN FDMA ; 6.3.1.3 ADVANTAGES AND DISADVANTAGES OF FDMA ; 6.3.1.4 APPLICATIONS OF FDMA ; 6.3.2 TIME DIVISION MULTIPLE ACCESS (TDMA) ; 6.3.2.1 TDMA CONCEPT ; 6.3.2.2 TDMA FRAME ; 6.3.2.3 FRAME EFFICIENCY ; 6.3.2.4 BURST SYNCHRONIZATION ; 6.3.3 CODE DIVISION MULTIPLE ACCESS (CDMA) ; 6.3.3.1 PN SEQUENCES ; 6.3.3.2 PROCESSING GAIN AND CAPACITY IN CDMA ; 6.3.4 RANDOM ACCESS ; 6.3.4.1 PURE ALOHA ; 6.3.4.2 SLOTTED ALOHA (S-ALOHA) ; 6.3.4.3 RESERVATION ALOHA (R-ALOHA) ; 6.3.5 CARRIER SENSE MULTIPLE ACCESS-COLLISION DETECTION (CSMA-CD) ; 6.3.6 FIXED ASSIGNMENT AND DEMAND ASSIGNMENT MULTIPLE ACCESS ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 7. DIGITAL MODULATION ; 7.1 INTRODUCTION ; 7.2 BASEBAND MODULATION ; 7.2.1 PULSE MODULATION SYSTEMS ; 7.2.1.1 PULSE AMPLITUDE MODULATION ; 7.2.1.2 PULSE WIDTH MODULATION ; 7.2.1.3 PULSE POSITION MODULATION ; 7.2.2 BASEBAND SIGNALING ; 7.2.2.1 LINE CODES ; 7.2.2.2 LINE CODES FOR PCM TRANSMISSION ; 7.2.3 CORRELATIVE CODING ; 7.2.3. INTER-SYMBOL INTERFERENCE (ISI) ; 7.2.3.2 RAISED-COSINE FILTER ; 7.2.3.3 CORRELATIVE CODING ; 7.2.3.4 DUO-BINARY CODING ; 7.2.3.5 MODIFIED DUO-BINARY CODING ; 7.3 BANDPASS MODULATION ; 7.3.1 BANDPASS PAM ; 7.3.2 QUADRATURE AMPLITUDE MODULATION (QAM) ; 7.3.3 DIGITAL PHASE MODULATION (PHASE SHIFT KEYING) ; 7.3.3.1 BPSK MODULATION ; 7.3.3.2 QPSK AND OFFSET QPSK (OQPSK) ; 7.3.4 DIGITAL FREQUENCY MODULATION (FREQUENCY SHIFT KEYING) ; 7.3.4.1 FSK GENERATION ; 7.3.4.2 CONTINUOUS PHASE FSK (CPFSK) ; 7.3.5 MINIMUM SHIFT KEYING (MSK) ; 7.3.5.1 MSK MODULATOR ; 7.3.5.2 GAUSSIAN MINIMUM SHIFT KEYING (GMSK) ; 7.3.5.3 CONTINUOUS PHASE MODULATION (CPM) ; 7.4 POWER SPECTRAL DENSITY ; 7.4.1 POWER SPECTRAL DENSITY OF BASEBAND SIGNALS ; 7.4.1.1 METHOD I: FINDING MPSDF FROM THE DEFINITION ; 7.4.1.2 METHOD II: FINDING MPSDF BY STATIONARIZING THE SIGNAL ; 7.4.2 POWER SPECTRAL DENSITY OF BANDPASS SIGNALS ; 7.4.2.1 PSD OF PAM SIGNAL ; 7.4.2.2 PSD OF A CORRELATIVE CODED SIGNAL ; 7.4.2.3 PSD OF BPSK SIGNAL ; 7.4.2.4 BANDWIDTH OF QPSK SIGNAL ; 7.5 COMPARISON OF BASIC MODULATIONS ; 7.6 SOME SPECIAL MODULATION TECHNIQUES ; 7.6.1 OFDM ; 7.6.1.1 OFDM CONCEPT ; 7.6.1.2 FFT IMPLEMENTATION OF OFDM ; 7.6.1.3 APPLICATIONS OF OFDM ; 7.6.2 TRELLIS CODED MODULATION ; 7.6.2.1 PARTITIONING OF SIGNAL SPACE ; 7.6.2.2 PERFORMANCE OF TCM ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 8. DEMODULATION AND DETECTION ; 8.1 INTRODUCTION ; 8.2 OPTIMUM RECEIVER ; 8.2.1 CORRELATION DEMODULATOR ; 8.2.2 MATCHED FILTER ; 8.2.3 MATCHED FILTER DEMODULATOR ; 8.3 BINARY DETECTION ; 8.3.1 PROBABILITY OF ERROR ; 8.3.2 DECISION RULES ; 8.3.3 SUFFICIENT STATISTICS ; 8.3.4 PERFORMANCE OF AN OPTIMAL RECEIVER ; 8.4 GENERAL BINARY DETECTION ; 8.4.1 IMPLEMENTATION OF A GENERAL BINARY RECEIVER ; 8.4.2 PERFORMANCE OF A GENERAL BINARY RECEIVER ; 8.4.3 SIGNALS WITH EQUAL ENERGY ; 8.4.4 DETECTION OF BANDPASS SIGNALS ; 8.5 M-ARY DETECTION ; 8.5.1 4-PAM SIGNAL ; 8.5.2 GRAY CODING ; 8.5.3 QPSK SIGNALS ; 8.5.4 M-ARY PAM SIGNALS ; 8.5.5 PERFORMANCE BOUNDS ; 8.6 NON COHERENT DETECTION ; 8.6.1 NON-COHERENT DETECTION OF BINARY SIGNALS ; 8.6.2 PERFORMANCE OF NON-COHERENT RECEIVER ; 8.6.3 DIFFERENTIAL PSK ; 8.7 EQUALIZATION ; 8.7.1 LINEAR TRANSVERSAL FILTER EQUALIZER ; 8.7.2 NON-LINEAR EQUALIZERS ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 9. ERROR CONTROL CODING ; 9.1 INTRODUCTION ; 9.1.1 TYPES AND MEASURES OF ERROR ; 9.1.2 SHANNON-HARTLEY CAPACITY THEOREM ; 9.1.3 CONCEPTS BEHIND ERROR DETECTION AND CORRECTION -A BIGGER PICTURE ; 9.1.4 METHODS OF ERROR CONTROL ; 9.1.5 CLASSIFICATION OF ERROR CORRECTING CODES ; 9.2 LINEAR BLOCK CODES ; 9.2.1 HAMMING DISTANCE ; 9.2.2 HAMMING WEIGHT ; 9.2.3 ERROR DETECTION AND CORRECTION CAPABILITIES OF A CODE ; 9.2.4 CODEWORD ERROR PROBABILITY COMPUTATION ; 9.2.5 GENERATOR MATRIX ; 9.2.6 SYSTEMATIC CODES ; 9.2.7 PARITY CHECK MATRIX ; 9.2.8 SYNDROME ; 9.2.9 STANDARD ARRAY ; 9.2.10 IMPLEMENTING THE DECODER ; 9.3 CYCLIC CODES ; 9.3.1 GENERATOR POLYNOMIAL FOR CYCLIC CODE ; 9.3.2 SYSTEMATIC CYCLIC CODE ; 9.3.3 POLYNOMIAL MULTIPLICATION AND DIVISION ; 9.4 IMPORTANT BLOCK CODES ; 9.4.1 HAMMING CODES ; 9.4.2 BCH CODES ; 9.4.3 GOLAY CODES ; 9.4.4 REED-SOLOMON CODES ; 9.5 CONVOLUTIONAL CODES ; 9.5.1 CONVOLUTIONAL ENCODER ; 9.6 CONVOLUTIONAL DECODING ; 9.6.1 MAXIMUM LIKELIHOOD DECODING AND VITERBI ALGORITHM ; 9.6.2 SEQUENTIAL DECODING AND FANO ALGORITHM ; 9.7 TURBO CODING ; 9.7.1 TURBO CODER ; 9.7.2 TURBO DECODER ; 9.8 LDPC ; 9.7 PRACTICAL APPLICATION OF ERROR CORRECTING CODES ; 9.7.1 DEEP SPACE COMMUNICATION ; 9.7.2 SATELLITE COMMUNICATION ; 9.7.3 DATA TRANSMISSION ; 9.7.4 DATA STORAGE ; 9.7.5 DAB/DVB ; 9.7.6 MOBILE AND WIRELESS SYSTEMS ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 10. SPREAD SPECTRUM COMMUNICATION ; 10.1 INTRODUCTION ; 10.2 PSEUDO NOISE SEQUENCE ; 10.2.1 PROPERTIES OF PN SEQUENCES ; 10.2.2 GOLD SEQUENCES ; 10.3 PROCESSING GAIN AND CAPACITY IN CDMA ; 10.4 DIRECT SEQUENCE SPREAD SPECTRUM ; 10.4.1 DSSS TRANSMITTER AND RECEIVER ; 10.4.2 INTERFERENCE REJECTION ; 10.4.3 SHORT AND LONG CODES ; 10.5 FREQUENCY HOPPING SPREAD SPECTRUM ; 10.5.1 FHSS TRANSMITTER AND RECEIVER ; 10.5.2 SLOW AND FAST HOPPING ; 10.6 ACQUISITION AND SYNCHRONIZATION ; 10.6.1 PARALLEL ACQUISITION ; 10.6.2 SEQUENTIAL ACQUISITION ; 10.6.3 SEQUENTIAL ACQUISITION WITH SEEDING ; 10.7 SPREAD SPECTRUM APPLICATIONS ; 10.7.1 MOBILE COMMUNICATION ; 10.7.2 LOW POWER COMMUNICATION ; 10.7.3 RANGING ; 10.7.4 MULTIUSER COMMUNICATION ; SUMMARY ; REVIEW QUESTIONS ; PROBLEMS ; 11. APPLICATIONS OF DIGITAL COMMUNICATION ; 11.1 INTRODUCTION ; 11.2 CELLULAR COMMUNICATION ; 11.2.1 CELLULAR CONCEPT ; COCHANNEL INTERFERENCE ; 11.2.2 CELLULAR STANDARDS ; 11.2.2.1 GROUPE SPECIAL MOBILE (GSM) ; 11.2.2.2 ; IS-95 ; 11.2.2.3 ; IMT-2000 ; 11.3 DIGITAL SATELLITE COMMUNICATIONS ; 11.3.1 ELEMENTS OF A SATELLITE COMMUNICATION SYSTEM ; 11.3.2 LINK ANALYSIS ; 11.3.2.1 ; LINK EQUATION ; 11.3.2.2 ; RECEIVER NOISE TEMPERATURE ; 11.3.2.3 ; G/T RATIO FOR EARTH STATIONS ; 11.3.3 MULTIPLE ACCESS ; 11.3.3.1 ; FDMA ; 11.3.3.2 ; SPADE ; 11.3.3.3 ; SATELLITE TDMA ; 11.3.4 SPECIAL TECHNIQUES IN SATELLITE COMMUNICATION ; 11.3.4.1 ; DIGITAL SPEECH INTERPOLATION ; 11.3.4.2 ; ECHO CANCELLATION ; 11.3.5 DIGITAL SATELLITE SYSTEMS ; 11.3.5.1 ; VSAT SYSTEMS ; 11.3.5.2 ; DTH SYSTEMS ; 11.3.5.3 ; DAB SYSTEMS ; 11.3.5.4 ; MOBILE COMMUNICATION SYSTEMS ; 11.3.5.5 ; SEARCH AND RESCUE SYSTEM ; 11.3.5.6 ; GLOBAL POSITIONING SYSTEM ; 11.4 OPTICAL COMMUNICATION ; 11.4.1 ADVANTAGES OF OPTICAL COMMUNICATION ; 11.4.2 SIGNAL TRANSMISSION IN AN OPTICAL FIBER ; 11.4.2.1 ; PROPAGATION BY TOTAL INTERNAL REFLECTION ; 11.4.2.2 ; STEP-INDEX AND GRADED-INDEX FIBERS ; 11.4.2.3 ; NUMERICAL APERTURE ; 11.4.2.4 ; MULTIPATH DISPERSION ; 11.4.2.5 ; INFORMATION RATE ; 11.4.3 OPTICAL TRANSMISSION SYSTEMS ; 11.4.3.1 ; MODULATION ; 11.3.2 WAVELENGTH DIVISION MULTIPLEXING (WDM) ; 11.4.4 OPTICAL TELECOMMUNICATION NETWORKS ; 11.4.4.1 ; SYNCHRONOUS OPTICAL NETWORK (SONET) ; 11.4.4.2 ; SYNCHRONOUS DIGITAL HIERARCHY (SDH) ; 11.4.5 APPLICATIONS OF OPTICAL FIBERS ; 11.5 WIFI AND WIMAX ; REVIEW QUESTIONS ; PROBLEMS ; APPENDIX A USEFUL TRIGONOMETRICAL IDENTITIES ; APPENDIX B TABLE OF Q FUNCTIONS. ; APPENDIX C MATLAB CODES ; APPENDIX D LABORATORY MANUAL. ; APPENDIX E RANDOM ERROR GENERATOR ; APPENDIX F MODEL QUESTION PAPERS. ; APPENDIX G HINTS

About the Author

R. N. Mutagi is currently Professor and Head, Department of Electronics and Communication Engineering, Indus Institute of Technology and Engineering, Ahmedabad. He is a Senior Member of IEEE (Communication Society and Signal Processing Society), Fellow of Broadcast Engineering Society (BES) and Fellow of the Institute of Electronics and Telecommunication Engineers (IETE). He has four decades of experience in R&D in space industry, technology development, systems engineering, technical management, project and people management and teaching in India and Canada. As the Head of Baseband Processing Division at ISRO he has developed satellite communication systems for the major satellite communication programs of ISRO including SITE, STEP, AUP and, GSAT.

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