Contemporary Communication Systems Using MATLAB

ISBN-10: 0534406173

ISBN-13: 9780534406172

Edition: 2nd 2004 (Revised)

List price: $157.95
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Description:

Featuring a variety of applications that motivate students, this book serves as a companion or supplement to any of the comprehensive textbooks in communication systems. The book provides a variety of exercises that may be solved on the computer using MATLAB? (The authors assume that the student is familiar with the fundamentals of MATLAB). By design, the treatment of the various topics is brief. The authors provide the motivation and a short introduction to each topic, establish the necessary notation, and then illustrate the basic concepts by means of an example.
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Book details

List price: $157.95
Edition: 2nd
Copyright year: 2004
Publisher: Course Technology
Publication date: 7/7/2003
Binding: Paperback
Pages: 487
Size: 7.25" wide x 9.00" long x 0.75" tall
Weight: 1.628
Language: English

Gerhard Bauch received the Dipl.-Ing. and Dr.-Ing. degree in Electrical Engineering from Munich University of Technology (TUM) in 1995 and 2001, respectively, and the Diplom-Volkswirt degree from FernUniversitaet Hagen in 2001. In 1996, he was with the German Aerospace Center (DLR), Oberpfaffenhofen, Germany. From 1996-2001 he was member of scientific staff at Munich University of Technology (TUM). In 1998 and 1999 he was visiting researcher at AT&T Labs Research, Florham Park, NJ, USA. In 2002 he joined DoCoMo Euro-Labs, Munich, Germany, where he has been managing the Advanced Radio Transmission Group. In 2007 he was additionally appointed Research Fellow of DoCoMo Euro-Labs. From 2003-2008 he was an adjunct professor at Munich University of Technology. In 2007 he was a visiting professor teaching courses at the University of Udine in Italy and at the Alpen-Adria-University Klagenfurt in Austria. Since February 2009 he has been a full professor at the Universit�t der Bundeswehr Munich.

Signals and Linear Systems
Preview
Fourier Series
Periodic Signals and LTI Systems
Fourier Transforms
Sampling Theorem
Frequency-Domain Analysis of LTI Systems
Power and Energy
Lowpass Equivalent of Bandpass Signals
Random Processes
Preview
Generation of Random Variables
Gaussian and Gauss-Markov Processes
Power Spectrum of Random Processes and White Processes
Linear Filtering of Random Processes
Lowpass and Bandpass Processes
Monte Carlo Simulation of Digital Communication Systems
Analog Modulation
Preview
Amplitude Modulation (AM)
DSB-AM
Conventional AM
SSB-AM
Demodulation of AM Signals
DSB-AM Demodulation
SSB-AM Demodulation
Conventional AM Demodulation
Angle Modulation
Analog-to-Digital Conversion
Preview
Measure of Information
Noiseless Coding
Quantization
Scalar Quantization
Vector Quantization
Pulse-Code Modulation
Uniform PCM
Baseband Digital Transmission
Preview
Binary Signal Transmission
Optimum Receiver for the AWGN Channel
Other Binary Signal Transmission Methods
Signal Constellation Diagrams for Binary Signals
Multiamplitude Signal Transmission
Signal Waveforms with Four Amplitude Levels
Optimum Receiver for the AWGN Channel
Signal Waveforms with Multiple Amplitude Levels
Multidimensional Signals
Multidimensional Orthogonal Signals
Biorgthogonal Signals
Digital Transmission Through Bandlimited Channels
Preview
The Power Spectrum of a Digital PAM Signal
Characterization of Bandlimited Channels and Channel Distortion
Characterization of Intersymbol Interference
Communication System Design for Bandlimited Channels
Signal Design for Zero ISI
Signal Design for Controlled ISI
Precoding for Detection of Partial Response Signals
Linear Equalizers
Adaptive Linear Equalizers
Nonlinear Equalizers
Digital Transmission via Carrier Modulation
Preview
Carrier-Amplitude Modulation
Demodulation of PAM Signals
Carrier-Phase Modulation
Phase Demodulation and Detection
Differential Phase Modulation and Demodulation
Quadrature Amplitude Modulation
Demodulation and Detection of QAM
Probability of Error for QAM in an AWGN Channel
Carrier-Frequency Modulation
Frequency-Shift Keying
Demodulation and Detection of FSK Signals
Probability of Error for Noncoherent Detection of FSK
Multicarrier Modulation and OFDM
Synchronization in Communication Systems
Carrier Synchronization
Clock Synchronization
Channel Capacity and Coding
Preview
Channel Model and Channel Capacity
Channel Model
Channel Capacity
Channel Coding
Linear Block Codes
Convolutional Codes
Spread Spectrum Communication Systems
Preview
Direct-Sequence Spread Spectrum Systems
Signal Demodulation
Probability of Error
Two Applications of DS Spread Spectrum Signals
Generation of PN Sequences
Frequency-Hopped Spread Spectrum
Probability of Error for FH Signals
Use of Signal Diversity to Overcome Partial-Band Interference
Simulink Tutorial on Digital Modulation Methods
Preview
Short Introduction to Simulink
Example: BPSK Transmission
Start the Tutorial
Pulse Shaping
Theory
Experiments
Binary Phase-Shift Keying (BPSK)
Binary Phase Shift Keying with NRZ Rectangular Pulses
Binary Phase Shift Keying with Raised-Cosine Pulses
Binary Phase Shift Keying with Square-Root Raised-Cosine Pulses
Quadrature Phase-Shift Keying (QPSK)
Quadrature Phase-Shift Keying with Square-Root Raised-Cosine Pulses
Phase and Frequency Offset
Offset-QPSK
Theory
Experiments
Minimum Shift Keying (MSK)
Theory
Experiments
16-ary Quadrature Amplitude-Shift Keying (16-QAM)
16-QAM with Square-Root Raised-Cosine Pulses
16-QAM with Raised-Cosine Pulses
Bibliography
Index
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