UID:
almahu_9949697598902882
Format:
1 online resource (251 p.)
Edition:
1st ed.
ISBN:
1-280-70745-3
,
9786610707454
,
0-08-046555-2
Content:
Since the 1970's, there has been a great deal of research effort spent on studying chaotic systems and the properties of the chaotic signals generated. Characterized by their wideband, impulse-like autocorrelation and low cross-correlation properties, chaotic signals are useful spread-spectrum signals for carrying digital information. Spectrum spreading has become one of the most popular modulation techniques for high-speed wireless communications. It makes use of signals of very wide bandwidth to carry information at relatively low data rates, and possesses advantages such as low probabi
Note:
Description based upon print version of record.
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Front cover; Title page; Copyright page; Preface; Contents; 1. Introduction; 1.1 Chaos; 1.2 Spread-Spectrum Communication Systems; 1.3 Application of Chaos to Spread-Spectrum Communication Systems; 1.4 Motivation; 1.5 Book Organization; 2 Chaos-Based Digital Communication Systems; 2.1 Chaos-Based Digital Modulation and Demodulation Schemes; 2.2 Application to the Multiple-Access Systems; 2.3 Summary; 3 Multiple-Access Coherent Antipodal Chaos-Shift-Keying Systems; 3.1 Introduction; 3.2 Multiple-Access Antipodal Chaos-Shift-Keying (MA-ACSK) System
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3.3 Analysis of the MA-ACSK System Based on Gaussian Approximation3.4 Exact Bit Error Rate Analysis of the MA-ACSK System; 3.5 Results and Discussions; 3.6 Summary; Appendix 3A. Derivation of the statistical properties for the chaotic sequences generated by the Chebyshev map; 4 Multiuser Detection Techniques for Multiple-Access Coherent Antipodal Chaos-Shift-Keying Systems; 4.1 Introduction; 4.2 Linear Multiuser Detection Techniques; 4.3 Nonlinear Multiuser Detection Techniques; 4.4 Summary
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Appendix 4A. Derivation of means and variances relevant to the analyses of the decorrelating detector and MMSE detectorAppendix 4B. Derivation of means, variances and covariances relevant to the analysis of the decorrelating detector; Appendix 4C. Derivation of covariances and mean relevant to the analysis of the MMSE detector; Appendix 4D. Calculation of the probability of occurrence of Ne(n-1)(j) for the PIC detector; 5 Multiple-Access Generalized Correlation Delay-Shift-Keying Systems; 5.1 Review of Correlation-Delay-Shift-Keying (CDSK) Scheme
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5.2 Generalized Correlation-Delay-Shift-Keying (GCDSK) Scheme5.3 Multiple-Access GCDSK Scheme; 5.4 Summary; Appendix 5A. Expressions for the variables in the GCDSK system; Appendix 5B. Derivation of bit error rates for GCDSK system based on simple Gaussian approximation; Appendix 5C. Derivation of bit error rates for CDSK system based on simple Gaussian approximation; Appendix 5D. Expressions for the variables in the MA-GCDSK system; Appendix 5E. Derivation of bit error rates for MA-GCDSK system; 6 Enhancements of Correlation-Delay-Shift-Keying Scheme
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6.1 Enhanced Correlation-Delay-Shift-Keying System with Method One6.2 Enhanced Correlation-Delay-Shift-Keying System with Method Two; 6.3 Permutation-Based Multiple-Access CDSK Systems; 6.4 Results and Discussions; 6.5 Summary; 7 Multiple-Access Scheme Utilizing Transmitted References And Training Sequences; 7.1 Transmitter Structure; 7.2 Receiver Structures; 7.3 Results and Discussions; 7.4 Summary; 8 Near-Optimum Communication Schemes; 8.1 Near-Optimum Coherent (NOC) and Noncoherent (NON) Systems; 8.2 Near-Optimum Noncoherent System with Transmitted Reference; 8.3 Results and Discussions
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8.4 Summary
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English
Additional Edition:
ISBN 0-08-045151-9
Language:
English