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Chaos-Based Digital Communication Systems: Operating Principles, Analysis Methods, and Performance Evaluation Softcover reprint of hardcover 1st ed. 2003 [Mīkstie vāki]

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  • Formāts: Paperback / softback, 228 pages, height x width: 235x155 mm, weight: 454 g, 70 Illustrations, black and white; XII, 228 p. 70 illus., 1 Paperback / softback
  • Sērija : Signals and Communication Technology
  • Izdošanas datums: 15-May-2011
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3642056164
  • ISBN-13: 9783642056161
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Chaos-Based Digital Communication Systems: Operating Principles, Analysis Methods, and Performance Evaluation Softcover reprint of hardcover 1st ed. 2003Palielināt
  • Formāts: Paperback / softback, 228 pages, height x width: 235x155 mm, weight: 454 g, 70 Illustrations, black and white; XII, 228 p. 70 illus., 1 Paperback / softback
  • Sērija : Signals and Communication Technology
  • Izdošanas datums: 15-May-2011
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3642056164
  • ISBN-13: 9783642056161
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9783642056161.html
Keywords:
In the 1970's and 1980's, we saw phenomenal advancement in nonlinear sci­ ence, which had led to many important discoveries that greatly improve our understanding of the physical world. Among them, the discovery of chaos in deterministic systems is unarguably one of the most revolutionary scientific findings. We are now able to explain the apparent complexity and subtle or­ der exhibited by many physical systems under the unified framework of chaos theory. The past decade has seen heightened interest in the exploitation of chaos for useful applications in engineering systems. One application area that has attracted a great deal of attention is communications. Chaotic signals, by virtue of their wide band characteristic, are natural candidates for carrying information in a spread-spectrum communication environment. The use of chaotic signals in communications thus naturally inherits the advantages that are currently being offered by conventional spread-spectrum communication systems, such as robustness in multi path environments, resistance to jam­ ming, low probability of interception, etc. In addition, chaotic signals are easy to generate and hence offer a potentially low-cost solution to spread­ spectrum communications. Although many practical problems need to be solved before chaos-based communications can be realized in practice, the field has advanced rapidly during the past few years and it now reaches a point where abstract concepts from physics and mathematics have been fruitfully ported to techniques that allow information to be carried by chaotic signals.

Recenzijas

From the reviews:









"The book points to enhancement of data security as a motivation for the use of chaos in communications. The book, which includes a useful index, is targeted to graduate students, researchers, communications engineers and technology developers who wish to exploit chaos for communications applications." (K. Alan Shore, Optics and Photonics News, October, 2004)



"In this book equivalent discrete-time base-band models are used to assess the performance evaluation of chaos-based digital communication systems. An analytical approach has been used to study these systems. All chapters are provided with a large number of simulation and numerical results that are represented by graphics." (Telman Aliev, Zentralblatt MATH, Vol. 1030, 2004)

Papildus informācija

Springer Book Archives
1 Introduction
1(16)
1.1 Overview of Communication Systems
1(1)
1.2 Spread-Spectrum Communications
2(4)
1.2.1 Direct-Sequence Spread-Spectrum Technique
3(1)
1.2.2 Frequency-Hopping Spread-Spectrum Technique
4(2)
1.3 Advantages of Spread-Spectrum Systems
6(3)
1.3.1 Mitigation of Multipath Effects
6(1)
1.3.2 Averaging of Signal Quality in Multiple-User Environments
7(1)
1.3.3 Reduction of Frequency Planning Effort
7(2)
1.3.4 Increase in System Capacity
9(1)
1.4 Applications of Spread-Spectrum Communications
9(1)
1.5 Chaos-Based Communications
10(5)
1.5.1 Chaos
10(1)
1.5.2 Application of Chaos to Communications
11(4)
1.6 Benefits and Challenges
15(1)
1.7 What Is This Book About?
16(1)
2 Chaos-Based Digital Modulation and Demodulation Techniques
17(24)
2.1 From Conventional to Chaos-Based Digital Communications
17(1)
2.2 Classifications of Chaos-Based Communication Systems
18(2)
2.3 Chaos Shift Keying
20(5)
2.3.1 Coherent Demodulation Based on Correlation
21(1)
2.3.2 Non-Coherent Demodulation Based on Bit Energy Calculation
22(3)
2.4 Differential Chaos Shift Keying
25(5)
2.5 Other Modulation Schemes
30(5)
2.5.1 Chaotic On-Off-Keying
30(1)
2.5.2 Frequency-Modulated DCSK
30(2)
2.5.3 Correlation Delay Shift Keying
32(1)
2.5.4 Symmetric Chaos Shift Keying
32(2)
2.5.5 Quadrature Chaos Shift Keying
34(1)
2.6 Discrete-Time Baseband Equivalent Models
35(6)
2.6.1 Bandpass System
35(1)
2.6.2 Lowpass Equivalent Model
36(1)
2.6.3 Discrete-Time Lowpass Equivalent Model
37(1)
2.6.4 Derivation of Average Bit-Energy-to-Noise-Power-Spectral-Density Ratio
38(3)
3 Performance Analysis Methods for Coherent Chaos-Shift-Keying Systems
41(22)
3.1 Review of the Chaos-Shift-Keying (CSK) System
42(2)
3.2 Analysis of the CSK System with Multiple Access
44(7)
3.2.1 Transmitter Structure
44(1)
3.2.2 Receiver Structure
44(2)
3.2.3 Derivation of Bit Error Rate
46(5)
3.3 Simulations and Evaluation
51(12)
3.3.1 Users Using Distinct Chaotic Maps
53(1)
3.3.2 Same Chaotic Map Used by All Users
53(5)
Appendix 3A Derivation of variances relevant to the analysis of multiple access CSK system
58(2)
Appendix 3B Derivation of the statistical properties for the chaotic sequences generated by the logistic map and the cubic map
60(3)
4 Performance Analysis Methods for Non-Coherent Differential Chaos-Shift-Keying Systems
63(34)
4.1 Review of the Differential Chaos-Shift-Keying (DCSK) System
63(2)
4.2 Multiple Access DCSK System
65(2)
4.3 Time-Delay-Based Multiple Access DCSK System
67(17)
4.3.1 Frame Structure of the Transmitted Signal
67(3)
4.3.2 Receiver Structure
70(1)
4.3.3 Derivation of Bit Error Rate
71(7)
4.3.4 Simulations and Evaluation
78(6)
4.4 Permutation-Based Multiple Access DCSK System
84(13)
4.4.1 System Description
84(3)
4.4.2 Derivation of Bit Error Rate
87(4)
4.4.3 Simulations and Evaluation
91(3)
Appendix 4 Derivation of variances and covariances relevant to the analysis of time-delay-based multiple access DCSK system
94(3)
5 Anti-Jamming Performance of Chaos-Based Digital Communication Systems Under Narrowband Sine-Wave Jammers
97(22)
5.1 Systems Subject to Narrowband Sine-Wave Jammers
97(2)
5.2 Analysis of Anti-jamming Performance
99(13)
5.2.1 Coherent CSK System
99(7)
5.2.2 Non-Coherent DCSK System
106(6)
5.3 Simulations and Evaluation
112(7)
6 Anti-Jamming Performance of Chaos-Based Digital Communication Systems Under Wideband Pulsed-Noise Jammers
119(30)
6.1 Systems Subject to Wideband Pulse-Noise Jammers
119(1)
6.2 Analysis of Performance Under Pulsed-Noise Jammer
120(11)
6.2.1 Slowly Switching Jammer
122(6)
6.2.2 Fast Switching Jammer
128(3)
6.3 Simulations and Evaluation
131(18)
6.3.1 Slowly Switching Jammer
131(1)
6.3.2 Fast Switching Jammer
132(11)
Appendix 6A Derivation of covariances
143(1)
Appendix 6B Derivation of variances
144(1)
Appendix 6C Derivation of the statistical properties for the chaotic sequences generated by Chebyshev maps of degree larger than one
145(4)
7 Coexistence of Chaos-Based and Conventional Narrowband Digital Communication Systems
149(34)
7.1 Overview of the Problem
149(1)
7.2 System Description
150(1)
7.3 Performance Analysis of Combined CSK-BPSK System
151(10)
7.3.1 Performance of the CSK System in Combined CSK-BPSK System
152(6)
7.3.2 Performance of the BPSK System in Combined CSK-BPSK System
158(3)
7.4 Performance Analysis of Combined DCSK-BPSK System
161(9)
7.4.1 Performance of the DCSK System in Combined DCSK-BPSK System
161(6)
7.4.2 Performance of the BPSK System in Combined DCSK-BPSK System
167(3)
7.5 Simulations and Evaluation
170(13)
Appendix 7A Derivation of covariances and variances relevant to the analysis of combined CSK-BPSK system
178(3)
Appendix 7B Derivation of E for chaotic sequences generated by the logistic map
181(2)
8 Coexistence of Chaos-Based and Conventional Spread-Spectrum Systems
183(22)
8.1 System Overview
183(1)
8.2 Analysis of Bit Error Performance
184(10)
8.2.1 Coherent CSK System
184(6)
8.2.2 Non-Coherent DCSK System
190(4)
8.3 Simulations and Evaluation
194(11)
Appendix 8 Derivation of covariances and variances relevant to the analysis of CSK system
200(5)
9 Techniques for Non-Coherent Detection in Chaos-Based Digital Communication Systems
205(14)
9.1 Basic Requirements of Non-Coherent Detection
205(1)
9.2 Review of the CSK System
206(3)
9.3 Non-Coherent Detection Based on Return Maps
209(4)
9.3.1 Regression Approach
209(3)
9.3.2 Probability Approach
212(1)
9.4 Simulations and Evaluation
213(6)
9.4.1 Regression Approach
213(1)
9.4.2 Probability Approach
214(3)
Appendix 9 Least squares estimate of parameter
217(2)
References 219(6)
Index 225