Verfügbarkeit: Optical communication with chaotic lasers

Optical communication with chaotic lasers: applications of nonlinear dynamics and synchronization

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Bibliographische Detailangaben
1. Verfasser:	Uchida, Atsushi (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Weinheim Wiley-VCH 2012
Schlagworte:	Nichtlineare Dynamik Optische Nachrichtentechnik Laser Synchronisierung Chaotisches System
Online-Zugang:	Inhaltstext Inhaltsverzeichnis
Beschreibung:	XXVIII, 640 S. Ill., graph. Darst.
ISBN:	352740869X 9783527408696 9783527640331

Internformat

MARC


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245	1	0	\|a Optical communication with chaotic lasers \|b applications of nonlinear dynamics and synchronization \|c Atsushi Uchida
264		1	\|a Weinheim \|b Wiley-VCH \|c 2012
300			\|a XXVIII, 640 S. \|b Ill., graph. Darst.
336			\|b txt \|2 rdacontent
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689	0	2	\|a Nichtlineare Dynamik \|0 (DE-588)4126141-0 \|D s
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Datensatz im Suchindex

_version_	1805145929567698944
adam_text	IMAGE 1 XI CONTENTS FOREWORD VII PREFACE XXVII PART ONE BASIC PHYSICS OF CHAOS AND SYNCHRONIZATION IN LASERS 1 INTRODUCTION 3 1.1 LASERS AND CHAOS 6 1.1.1 LASERS 6 1.1.2 CHAOS 6 1.1.3 CONNECTION BETWEEN LASERS AND CHAOS 7 1.1.4 CHAOS AND NOISE 8 1.2 SYNCHRONIZATION OF CHAOS AND OPTICAL COMMUNICATION 8 1.2.1 SYNCHRONIZATION OF CHAOS 8 1.2.2 OPTICAL COMMUNICATION WITH SYNCHRONIZED CHAOTIC LASERS 9 1.3 RANDOM NUMBER GENERATION WITH CHAOTIC LASERS AND OTHER APPLICATIONS 11 1.3.1 RANDOM NUMBER GENERATION 11 1.3.2 CONTROLLING CHAOS AND OTHER APPLICATIONS 12 1.4 RESEARCH DIRECTIONS FOR ENGINEERING APPLICATIONS WITH CHAOTIC LASERS 12 1.5 OUTLINE OF THIS BOOK 13 1.5.1 CONTENTS OF CHAPTERS: FIRST PARTS FOR THE BASICS 14 1.5.2 CONTENTS OF CHAPTERS: SECOND PART FOR THE APPLICATIONS 16 2 BASICS OF CHAOS AND LASER 19 2.1 HISTORY OF INSTABILITIES OF LASER OUTPUT 19 2.1.1 EXAMPLES OF LASER INSTABILITIES 19 2.1.1.1 FIRST OBSERVATION OF LASER INSTABILITIES IN A RUBY LASER 19 2.1.1.2 GREEN PROBLEM IN A SOLID-STATE LASER FOR SECOND- HARMONIC GENERATION 20 2.1.1.3 FEEDBACK-INDUCED INSTABILITY IN A SEMICONDUCTOR LASER FOR OPTICAL DISKS AND OPTICAL COMMUNICATION SYSTEMS 21 2.1.2 INHERENT NOISE-INDUCED INSTABILITIES 23 2.1.3 DETERMINISTIC CHAOS IN LASERS AND LORENZ-HAKEN EQUATIONS 24 BIBLIOGRAFISCHE INFORMATIONEN HTTP://D-NB.INFO/1013143922 DIGITALISIERT DURCH IMAGE 2 XII CONTENTS 2.2 BASIC CHAOS THEORY 26 2.2.1 LOGISTIC MAP IN DISCRETE-TIME SYSTEM 26 2.2.1.1 RECURRENCE FORMULA 26 2.2.1.2 CHAOTIC SEQUENCE 27 2.2.1.3 BIFURCATION DIAGRAM 28 2.2.1.4 LYAPUNOV EXPONENT 30 2.2.2 LORENZ MODEL IN A CONTINUOUS-TIME SYSTEM 31 2.2.2.1 LORENZ EQUATIONS 31 2.2.2.2 TEMPORAL WAVEFORM AND ATTRACTOR 32 2.2.2.3 SENSITIVE DEPENDENCE ON INITIAL CONDITIONS 32 2.2.2.4 BIFURCATION DIAGRAM 33 2.2.2.5 LYAPUNOV EXPONENT 33 2.2.3 RECONSTRUCTION OF ATTRACTOR IN TIME-DELAYED PHASE SPACE 35 2.2 A TYPES OF BIFURCATION AND ROUTE TO CHAOS 36 2.2.4.1 PERIOD-DOUBLING ROUTE TO CHAOS 36 2.2.4.2 QUASIPERIODICITY ROUTE TO CHAOS 37 2.2.4.3 INTERMITTENCY ROUTE TO CHAOS 37 2.3 BASIC LASER THEORY 38 2.3.1 LIGHT-MATTER INTERACTION FOR LASER RADIATION 38 2.3.1.1 ELEMENTS OF A LASER 38 2.3.1.2 TWO-ATOMIC-LEVEL DESCRIPTION AND MECHANISM OF LASER OSCILLATION 39 2.3.2 RADIATIVE RECOMBINATION OF ELECTRON-HOLE PAIRS IN SEMICONDUCTOR LASERS 40 2.3.3 RATE EQUATIONS FOR LASER DYNAMICS 41 2.3.4 RELAXATION OSCILLATION FREQUENCY 44 2.3.5 MECHANISM OF CHAOTIC INSTABILITY IN LASERS 45 2.4 CONNECTION BETWEEN CHAOS AND LASERS 46 2.4.1 SINGLE-MODE LASER MODEL BASED ON MAXWELL-BLOCH EQUATIONS 46 2.4.2 CLASSIFICATION OF LASER MODELS BASED ON DECAY RATES 48 2.4.2.1 CLASS C LASERS (THREE VARIABLES) 48 2.4.2.2 CLASS B LASERS (TWO VARIABLES) 48 2.4.2.3 CLASS A LASERS (ONE VARIABLE) 49 APPENDIX 2. A.I GENERAL FORMULA OF THE LINEARIZED EQUATIONS AND THE DERIVATION OF THE LINEARIZED EQUATIONS IN THE LORENZ MODEL 51 2. A.2 GENERAL FORMULA FOR THE CALCULATION OF THE LYAPUNOV EXPONENT IN NONLINEAR DYNAMICAL SYSTEMS WITHOUT TIME DELAY 53 2.A.3 ROESSLER MODEL 54 2.A.4 DERIVATION OF THE RELAXATION OSCILLATION FREQUENCY 55 GENERATION OF CHAOS IN LASERS 59 3.1 BASICS OF GENERATION OF CHAOS IN LASERS 59 3.1.1 CLASSIFICATION OF GENERATION TECHNIQUES OF CHAOS IN LASERS 59 IMAGE 3 CONTENTS XIII 3.1.1.1 OPTICAL FEEDBACK 60 3.1.1.2 OPTICAL COUPLING AND INJECTION 62 3.1.1.3 EXTERNAL MODULATION 62 3.1.1.4 INSERTION OF NONLINEAR ELEMENT 62 3.1.1.5 MULTIMODE LASERS AND HIGH-DIMENSIONAL LASER SYSTEMS 63 3.1.1.6 CLASS C LASERS SATISFYING THE CONDITION FOR LORENZ-HAKEN CHAOS 63 3.1.1.7 IKEDA-TYPE PASSIVE OPTICAL SYSTEMS 63 3.1.2 CHARACTERISTICS OF CHAOS IN LASERS 64 3.1.2.1 HIGH-FREQUENCY CHAOS 64 3.1.2.2 EXISTENCE OF TWO OSCILLATION FREQUENCIES IN DIFFERENT ORDERS OF MAGNITUDE 64 3.1.2.3 MIDDLE DEGREES OF FREEDOM 65 3.1.2.4 PHYSICAL VARIABLES 65 3.1.2.5 TRANSMISSION OF CHAOS 65 3.1.2.6 VARIETY OF LASER MODELS 65 3.1.3 HOW TO DISTINGUISH BETWEEN CHAOS AND NOISE FROM EXPERIMENTAL DATA? 66 3.1.3.1 EXPERIMENTAL APPARATUS FOR MEASUREMENT OF INSTABILITY IN LASER INTENSITY 66 3.1.3.2 EXAMPLES OF CHAOS AND NOISE FROM REAL EXPERIMENTAL DATA 66 3.1.3.3 OBSERVATION OF BIFURCATION 67 3.1.3.4 COMPARISON WITH LASER MODEL 68 3.2 CHAOS IN SEMICONDUCTOR LASERS 69 3.2.1 SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 69 3.2.1.1 DYNAMICAL REGIME AND L-I CHARACTERISTICS 69 3.2.1.2 COHERENCE COLLAPSE AND CHAOS IN EXPERIMENT 71 3.2.1.3 NUMERICAL RESULTS AND BIFURCATION DIAGRAM 73 3.2.1.4 LOW-FREQUENCY FLUCTUATIONS (LFFS) 75 3.2.1.5 SHORT-CAVITY REGIME 78 3.2.2 SEMICONDUCTOR LASER WITH POLARIZATION-ROTATED OPTICAL FEEDBACK 79 3.2.3 SEMICONDUCTOR LASER WITH OPTOELECTRONIC FEEDBACK 83 3.2.4 SEMICONDUCTOR LASER WITH OPTICAL INJECTION AND COUPLING 88 3.2.4.1 TEMPORAL DYNAMICS AND BIFURCATION DIAGRAM 88 3.2.4.2 BANDWIDTH ENHANCEMENT OF CHAOS BY OPTICAL INJECTION 91 3.2.5 SEMICONDUCTOR LASER WITH INJECTION CURRENT MODULATION 92 3.2.6 VERTICAL-CAVITY SURFACE-EMITTING LASER (VCSEL) 93 3.2.6.1 BASIC CHARACTERISTICS 93 3.2.6.2 OPTICAL FEEDBACK 96 3.2.6.3 OPTICAL INJECTION 97 IMAGE 4 XIV CONTENTS 3.3 CHAOS IN ELECTRO-OPTIC SYSTEMS 98 3.3.1 IKEDA-TYPE NONLINEAR DELAY DYNAMICS 98 3.3.2 WAVELENGTH CHAOS IN ELECTRO-OPTIC SYSTEM 101 3.3.3 INTENSITY CHAOS IN ELECTRO-OPTIC SYSTEM 103 3.3.4 PHASE CHAOS IN ELECTRO-OPTIC SYSTEM 105 3.4 CHAOS IN FIBER LASERS 107 3.4.1 EXTERNAL MODULATION 109 3.4.2 MULTIMODE (DUAL-WAVELENGTH) DYNAMICS 112 3.4.3 FAST POLARIZATION DYNAMICS 114 3.5 CHAOS IN SOLID-STATE LASERS 115 3.5.1 EXTERNAL MODULATION 116 3.5.2 FREQUENCY-SHIFTED OPTICAL FEEDBACK 117 3.5.3 ANTIPHASE DYNAMICS IN MULTIMODE LASER 120 3.5.4 INSERTION OF NONLINEAR CRYSTAL 122 3.6 CHAOS IN GAS LASERS 124 3.6.1 LORENZ-HAKEN CHAOS 124 3.6.2 INSERTION OF SATURABLE ABSORBERS 128 3.6.3 EXTERNAL MODULATION 130 3.6.4 OPTICAL INJECTION 130 3.6.5 MULTIMODE LASER 132 3.6.6 LOW-FREQUENCY DYNAMICS WITH OPTICAL FEEDBACK 134 APPENDIX 3.A.1 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN A SEMICONDUCTOR LASER 135 3.A.1.1 COHERENT OPTICAL FEEDBACK 135 3.A.1.2 POLARIZATION-ROTATED OPTICAL FEEDBACK 135 3.A.1.3 OPTOELECTRONIC FEEDBACK (INCOHERENT FEEDBACK) 136 3.A.2 MECHANISM OF LOW-FREQUENCY FLUCTUATIONS (LFFS) IN SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 137 3.A.3 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN A VERTICAL-CAVITY SURFACE-EMITTING LASER (VCSEL) 139 3.A.4 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN AN ELECTRO-OPTIC SYSTEM 139 3.A.5 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN A FIBER LASER 140 3.A.6 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN A SOLID-STATE LASER 140 3.A.6.1 SINGLE-MODE LASER MODEL 140 3.A.6.2 MULTIMODE LASER MODEL WITH SPATIAL HOLE BURNING (TANG-STATZ-DEMARS EQUATIONS) 141 3.A.7 NUMERICAL MODEL FOR CHAOTIC DYNAMICS IN A GAS LASER 142 ANALYSIS OF CHAOTIC LASER DYNAMICS: EXAMPLE OF SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 145 4.1 EXPERIMENTAL ANALYSIS OF SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 145 IMAGE 5 CONTENTS XV 4.1.1 EXPERIMENTAL SETUP 146 4.1.2 LIGHT POWER VERSUS INJECTION CURRENT (L-I) CHARACTERISTICS 147 4.1.3 TEMPORAL WAVEFORMS, RF SPECTRA, AUTOCORRELATIONS, AND OPTICAL SPECTRA 149 4.1.4 TWO-DIMENSIONAL MAP 155 4.2 MODEL FOR SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 156 4.2.1 LANG-KOBAYASHI EQUATIONS 156 4.2.2 DERIVATION OF THE ELECTRIC-FIELD AMPLITUDE AND PHASE OF THE LANG-KOBAYASHI EQUATIONS FROM THE COMPLEX ELECTRIC-FIELD EQUATIONS 158 4.2.3 DERIVATION OF THE REAL AND IMAGINARY ELECTRIC FIELDS OF THE LANG-KOBAYASHI EQUATIONS FROM THE COMPLEX ELECTRIC-FIELD EQUATIONS 160 4.3 ANALYTICAL APPROACH OF SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 161 4.3.1 STEADY-STATE SOLUTIONS WITHOUT OPTICAL FEEDBACK 161 4.3.2 LINEAR STABILITY ANALYSIS FOR STEADY-STATE SOLUTIONS WITHOUT OPTICAL FEEDBACK 162 4.3.2.1 EIGENVALUES OF JACOBIAN MATRIX 162 4.3.2.2 RELAXATION OSCILLATION FREQUENCY 165 4.3.3 STEADY-STATE SOLUTIONS WITH OPTICAL FEEDBACK 166 4.3.4 LINEAR STABILITY ANALYSIS FOR STEADY STATE SOLUTIONS WITH OPTICAL FEEDBACK 169 4.4 NUMERICAL ANALYSIS OF SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK 172 4.4.1 NUMERICAL RESULTS OF CHAOTIC DYNAMICS 173 4.4.1.1 TEMPORAL WAVEFORMS, FFTS, AND ATTRACTORS 173 4.4.1.2 BIFURCATION DIAGRAM AND TWO-DIMENSIONAL DYNAMICAL MAP 176 4.4.2 LINEAR STABILITY ANALYSIS FOR OSCILLATORY TRAJECTORY 179 4.4.3 MAXIMUM LYAPUNOV EXPONENT 181 4.5 DIMENSIONLESS EQUATIONS AND FURTHER NONLINEAR ANALYSIS 184 4.5.1 DIMENSIONLESS EQUATIONS 184 4.5.2 NUMERICAL RESULTS OF CHAOTIC DYNAMICS 187 4.5.3 LINEAR STABILITY ANALYSIS FOR OSCILLATORY TRAJECTORY IN DIMENSIONLESS EQUATIONS AND MAXIMUM LYAPUNOV EXPONENT 188 4.5.4 LYAPUNOV SPECTRUM 190 4.5.5 KOLMOGOROV-SINAI ENTROPY AND KAPLAN-YORKE DIMENSION 392 4.6 LANG-KOBAYASHI EQUATIONS WITH GAIN SATURATION 394 4.6.1 LANG-KOBAYASHI EQUATIONS WITH GAIN SATURATION 194 4.6.2 NUMERICAL RESULTS AND HISTOGRAM 195 4.6.3 LINEAR STABILITY ANALYSIS FOR OSCILLATORY TRAJECTORY AND MEASUREMENT OF COMPLEXITY 196 IMAGE 6 XVI CONTENTS APPENDIX 4.A.1 DERIVATION OF THE RATE EQUATIONS OF SEMICONDUCTOR LASERS 199 4.A.2 DERIVATION OF THE RATE EQUATIONS OF SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 205 4.A.3 ANALYTICAL APPROACH OF THE STABILITY OF STEADY STATE SOLUTIONS FOR SEMICONDUCTOR LASER WITH OPTICAL FEEDBACK UNDER THE LIMITS OF WEAK AND SHORT FEEDBACK 206 4.A.4 RUNGE-KUTTA METHOD FOR THE INTEGRATION OF ORDINARY DIFFERENTIAL EQUATIONS 208 4.A.5 GRAM-SCHMIDT ORTHOGONALIZATION 210 5 SYNCHRONIZATION OF CHAOS IN LASERS 211 5.1 CONCEPT OF SYNCHRONIZATION OF CHAOS IN LASERS 211 5.1.1 INTRODUCTION 211 5.1.2 WHAT IS SYNCHRONIZATION? 212 5.1.3 WHY SHOULD CHAOS BE SYNCHRONIZED? 213 5.1.4 CHARACTERISTICS OF SYNCHRONIZATION OF CHAOS IN LASER SYSTEMS 215 5.1.5 SYNCHRONIZATION OF CHAOS FOR COMMUNICATION APPLICATIONS 216 5.2 HISTORY OF SYNCHRONIZATION OF CHAOS IN LASERS 217 5.2.1 SYNCHRONIZATION OF CHAOS IN ELECTRONIC CIRCUITS 217 5.2.1.1 PECORA-CARROLL METHOD 217 5.2.1.2 PYRAGAS METHOD 218 5.2.2 SYNCHRONIZATION OF CHAOS IN LASERS 219 5.3 COUPLING SCHEMES AND SYNCHRONIZATION TYPES 223 5.3.1 IDENTICAL SYNCHRONIZATION 224 5.3.2 GENERALIZED SYNCHRONIZATION (WITH HIGH CORRELATION) 225 5.3.3 SYNCHRONIZATION OF CHAOS IN FEEDBACK SYSTEMS 225 5.3.3.1 OPEN-LOOP CONFIGURATION 225 5.3.3.2 CLOSED-LOOP CONFIGURATION 227 5.3.4 MUTUAL COUPLING 228 5.3.5 LINEAR STABILITY ANALYSIS AND CONDITIONAL LYAPUNOV EXPONENT 229 5.4 EXAMPLES OF SYNCHRONIZATION OF CHAOS IN SEMICONDUCTOR LASERS 230 5.4.1 SEMICONDUCTOR LASERS WITH COHERENT OPTICAL FEEDBACK 231 5.4.2 SEMICONDUCTOR LASERS WITH POLARIZATION-ROTATED OPTICAL FEEDBACK 236 5.4.3 SEMICONDUCTOR LASERS WITH OPTOELECTRONIC FEEDBACK 237 5.4.4 SEMICONDUCTOR LASERS WITH OPTICAL INJECTION 239 5.4.5 SEMICONDUCTOR LASERS WITH MUTUAL COUPLING 240 5.4.5.1 SYMMETRY BREAKING AND LEADER-LAGGARD RELATIONSHIP 240 5.4.5.2 ZERO-LAG SYNCHRONIZATION 242 5.4.6 VERTICAL-CAVITY SURFACE-EMITTING LASERS (VCSELS) 243 5.5 EXAMPLES OF SYNCHRONIZATION OF CHAOS IN ELECTRO-OPTIC SYSTEMS AND OTHER LASERS 245 5.5.1 ELECTRO-OPTIC SYSTEMS 245 IMAGE 7 CONTENTS XVII 5.5.2 FIBER LASERS 248 5.5.3 SOLID-STATE LASERS 250 5.5.4 GAS LASERS 253 5.6 SPECIFIC TYPES OF SYNCHRONIZATION 254 5.6.1 PHASE SYNCHRONIZATION 254 5.6.2 GENERALIZED SYNCHRONIZATION (WITH LOW CORRELATION) 258 5.7 CONSISTENCY 263 5.7.1 WHAT IS CONSISTENCY? 263 5.7.2 EXAMPLES OF CONSISTENCY IN LASER SYSTEMS 265 5.7.3 APPLICATION OF CONSISTENCY 269 5.7.3.1 NONINVASIVE TESTING 269 5.7.3.2 ANALYSIS OF BRAIN DYNAMICS AND LEARNING PROCESS IN THE BRAIN 269 5.7.3.3 PHYSICAL ONE-WAY FUNCTION 269 5.7.3.4 TEACHING-LEARNING METHODOLOGIES 270 5.7.3.5 DESIGN OF DRUG DELIVERY 270 APPENDIX 5.A.1 PECORA-CARROLL METHOD FOR SYNCHRONIZATION OF CHAOS 270 5.A.2 GENERAL FORMULA OF LINEARIZED EQUATIONS FOR COUPLED DIFFERENTIAL EQUATIONS 271 5.A.3 PROCEDURE FOR THE CALCULATION OF THE CONDITIONAL LYAPUNOV EXPONENT 273 5.A.4 NUMERICAL MODEL FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS 274 5.A.4.1 COHERENT OPTICAL FEEDBACK 274 5.A.4.2 POLARIZAITON-ROTATED OPTICAL FEEDBACK 275 5.A.4.3 OPTOELECTRONIC FEEDBACK (INCOHERENT FEEDBACK) 276 5.A.5 NUMERICAL MODEL FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED ELECTRO-OPTIC SYSTEMS 277 5.A.6 NUMERICAL MODEL FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED FIBER LASERS 278 5.A.7 NUMERICAL MODEL FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED SOLID-STATE LASERS 279 5.A.7.1 SINGLE-MODE LASER MODEL 279 5.A.7.2 MULTIMODE LASER MODEL WITH SPATIAL HOLE BURNING (TANG-STATZ-DEMARS EQUATIONS) 280 5.A.8 NUMERICAL MODEL FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED GAS LASERS 281 5.A.9 DEFINITION OF PHASE IN CHAOTIC TEMPORAL WAVEFORM BY THE HUBERT TRANSFORM 282 ANALYSIS OF SYNCHRONIZATION OF CHAOS: EXAMPLE OF UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 285 6.1 EXPERIMENTAL ANALYSIS ON SYNCHRONIZATION OF CHAOS IN TWO SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 285 IMAGE 8 XVIII CONTENTS 6.1.1 EXPERIMENTAL SETUP FOR SYNCHRONIZATION OF CHAOS 285 6.1.2 EXPERIMENTAL RESULTS OF SYNCHRONIZATION OF CHAOS 287 6.1.3 PARAMETER DEPENDENCE OF SYNCHRONIZATION OF CHAOS 290 6.2 MODEL FOR SYNCHRONIZATION OF CHAOS IN TWO COUPLED SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 293 6.2.1 LANG-KOBAYASHI EQUATIONS FOR SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 293 6.2.1.1 COUPLED LANG-KOBAYASHI EQUATIONS 293 6.2.1.2 IDENTICAL SYNCHRONOUS SOLUTION 295 6.2.2 DERIVATION OF THE ELECTRIC-FIELD AMPLITUDE AND PHASE OF THE COUPLED LANG-KOBAYASHI EQUATIONS FROM THE COMPLEX ELECTRIC-FIELD EQUATIONS 296 6.2.3 DERIVATION OF THE REAL AND IMAGINARY ELECTRIC FIELDS OF THE COUPLED LANG-KOBAYASHI EQUATIONS FROM THE COMPLEX ELECTRIC- FIELD EQUATIONS 299 6.3 NUMERICAL ANALYSIS ON SYNCHRONIZATION OF CHAOS IN UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 300 6.3.1 MEASURES FOR SYNCHRONIZATION OF CHAOS 300 6.3.1.1 TWO TYPES OF SYNCHRONIZATION AND CROSS-CORRELATION VALUES 300 6.3.1.2 OPTICAL FREQUENCY DETUNING 302 6.3.2 NUMERICAL RESULTS OF TEMPORAL WAVEFORMS AND CORRELATION PLOTS 303 6.3.3 PARAMETER DEPENDENCE OF THE TWO TYPES OF SYNCHRONIZATION 305 6.3.4 LINEAR STABILITY ANALYSIS OF SYNCHRONOUS OSCILLATORY SOLUTIONS FOR IDENTICAL SYNCHRONIZATION 308 6.3.4.1 LINEARIZED EQUATIONS 308 6.3.4.2 CONDITIONAL LYAPUNOV EXPONENT 309 6.3.4.3 NUMERICAL RESULTS OF CONDITIONAL LYAPUNOV EXPONENT 310 6.3.5 OPEN- VERSUS CLOSED-LOOP CONFIGURATIONS 312 6.4 EXPERIMENTAL ANALYSIS ON GENERALIZED SYNCHRONIZATION WITH LOW CORRELATION IN THREE SEMICONDUCTOR LASERS IN THE AUXILIARY SYSTEM APPROACH 313 6.4.1 EXPERIMENTAL SETUP FOR GENERALIZED SYNCHRONIZATION WITH LOW CORRELATION IN THE AUXILIARY SYSTEM APPROACH 314 6.4.2 EXPERIMENTAL RESULTS OF GENERALIZED SYNCHRONIZATION 316 6.4.3 PARAMETER DEPENDENCE OF GENERALIZED SYNCHRONIZATION 320 6.4.4 DEPENDENCE OF GENERALIZED SYNCHRONIZATION ON OPTICAL PHASE OF FEEDBACK LIGHT 322 6.5 MODEL FOR GENERALIZED SYNCHRONIZATION WITH LOW CORRELATION IN THREE SEMICONDUCTOR LASERS IN THE AUXILIARY SYSTEM APPROACH 324 6.5.1 COUPLED LANG-KOBAYASHI EQUATIONS FOR GENERALIZED SYNCHRONIZATION IN THE AUXILIARY SYSTEM APPROACH 325 IMAGE 9 CONTENTS XIX 6.5.2 SYNCHRONOUS SOLUTIONS FOR GENERALIZED SYNCHRONIZATION IN THE AUXILIARY SYSTEM APPROACH 327 6.6 NUMERICAL ANALYSIS ON GENERALIZED SYNCHRONIZATION OF CHAOS IN THREE SEMICONDUCTOR LASERS IN THE AUXILIARY SYSTEM APPROACH 327 6.6.1 TEMPORAL WAVEFORMS 329 6.6.2 PARAMETER DEPENDENCE OF GENERALIZED SYNCHRONIZATION 329 6.6.3 LINEAR STABILITY ANALYSIS OF SYNCHRONOUS OSCILLATORY SOLUTIONS FOR GENERALIZED SYNCHRONIZATION 331 6.6.3.1 LINEARIZED EQUATIONS 331 6.6.3.2 CONDITIONAL LYAPUNOV EXPONENT 333 6.6.3.3 NUMERICAL RESULTS OF CONDITIONAL LYAPUNOV EXPONENT 334 6.6.4 TWO-DIMENSIONAL MAP 334 6.6.5 DEPENDENCE OF SYNCHRONIZATION QUALITY ON OPTICAL PHASE OF FEEDBACK LIGHT IN THE CLOSED-LOOP CONFIGURATION 336 APPENDIX 6.A.I RATE EQUATIONS FOR IDENTICAL SYNCHRONIZATION IN UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK IN THE CLOSED-LOOP CONFIGURATION 337 PART TWO APPLICATION OF CHAOTIC LASERS TO OPTICAL COMMUNICATION AND INFORMATION TECHNOLOGY 7 BASIC CONCEPT OF OPTICAL COMMUNICATION WITH CHAOTIC LASERS 343 7.1 HISTORY OF SECRET COMMUNICATION 343 7.1.1 CRYPTOGRAPHY 343 7.1.2 STEGANOGRAPHY 344 7.1.3 NOISE COMMUNICATION 346 7.2 CONCEPT OF CHAOS COMMUNICATION 346 7.2.1 BASIC IDEA OF CHAOS COMMUNICATION 346 7.2.2 FEATURES OF CHAOS COMMUNICATION 348 7.2.3 HARDWARE KEYS 348 7.2.4 SYNCHRONIZATION FOR CHAOS COMMUNICATION 349 7.3 CHARACTERISTICS OF CHAOS COMMUNICATION 351 7.3.1 HARDWARE-BASED COMMUNICATION 351 7.3.2 CHAOS-SYNCHRONIZATION-BASED COMMUNICATION 351 7.3.3 PRIVACY 352 7.3.4 COMPATIBILITY 352 7.3.5 ANALOG COMMUNICATION 353 7.3.6 SUBCARRIER COMMUNICATION 353 7.3.7 COHERENT COMMUNICATION 353 7.3.8 MULTIPLEXING AND NOISE TOLERANCE 353 7.4 ENCODING AND DECODING TECHNIQUES 354 7 A.I CHAOS MASKING 354 7.4.2 CHAOS MODULATION 357 7A.3 CHAOS SHIFT KEYING 360 IMAGE 10 XX CONTENTS 7.5 TOOLS FOR QUANTITATIVE EVALUATION OF PERFORMANCE OF CHAOS COMMUNICATION 362 7.5.1 BIT ERROR RATE, Q FACTOR, AND SIGNAL-TO-NOISE RATIO 362 7.5.2 MODULATION FORMAT AND EYE DIAGRAM 365 IMPLEMENTATION OF OPTICAL COMMUNICATION WITH CHAOTIC LASERS 369 8.1 HISTORY OF CHAOS COMMUNICATION 369 8.1.1 CHAOS COMMUNICATION IN ELECTRONIC CIRCUITS 369 8.1.2 CHAOS COMMUNICATION IN OPTICAL SYSTEMS 370 8.1.3 EUROPEAN PROJECT FOR CHAOS COMMUNICATION 375 8.2 EXAMPLES OF COMMUNICATION SYSTEMS WITH VARIOUS CHAOTIC LASERS 377 8.2.1 SEMICONDUCTOR LASERS WITH OPTICAL FEEDBACK 377 8.2.1.1 FIELD EXPERIMENT OF CHAOS COMMUNICATION 377 8.2.1.2 TRANSMISSION OF TV VIDEO SIGNAL 381 8.2.2 SEMICONDUCTOR LASERS WITH OPTOELECTRONIC FEEDBACK 383 8.2.3 ELECTRO-OPTIC SYSTEMS 384 8.2.4 FIBER LASERS 386 8.3 PERFORMANCE EVALUATION OF OPTICAL COMMUNICATION WITH CHAOTIC LASERS 390 8.3.1 SUBCARRIER MODULATION 390 8.3.2 PHOTONIC INTEGRATED CIRCUIT AND FORWARD ERROR CORRECTION FOR HIGH-PERFORMANCE CHAOS COMMUNICATION 394 8.3.2.1 PHOTONIC INTEGRATED CIRCUIT 394 8.3.2.2 CHAOS COMMUNICATION EXPERIMENT 396 8.3.2.3 FORWARD ERROR CORRECTION TECHNIQUE 397 8.3.2.4 BIT-ERROR-RATE (BER) PERFORMANCE 397 8.3.2.5 ANALYSIS FOR UNAUTHORIZED USERS 399 8.3.3 OPTICAL PHASE CHAOS FOR 10-GB/S CHAOS COMMUNICATION 400 8.3.4 COMPARISON OF THE ENCODING AND DECODING SCHEMES FOR CHAOS COMMUNICATION 403 8.4 PRIVACY ISSUES IN OPTICAL COMMUNICATION WITH CHAOTIC LASERS 405 8.4.1 INTRODUCTION 405 8.4.2 RECONSTRUCTION OF MODEL AND PARAMETER SETTINGS BY TIME-SERIES ANALYSIS 406 8.4.3 PARAMETER ESTIMATION BY USING SIMILAR HARDWARE 406 8.4.4 PARAMETER ESTIMATION BY TIME-SERIES ANALYSIS 408 8.4.5 DIRECT DETECTION OF PRESENCE OF MESSAGE FROM TIME-SERIES ANALYSIS 409 8.4.6 SUMMARY OF PRIVACY ISSUES 410 8.5 PHOTONIC INTEGRATED CIRCUIT FOR OPTICAL COMMUNICATION WITH CHAOTIC LASERS 410 8.5.1 PHOTONIC INTEGRATED CIRCUIT FOR A SEMICONDUCTOR LASER WITH ALL-OPTICAL FEEDBACK 411 8.5.2 PHOTONIC INTEGRATED CIRCUIT FOR TWO MUTUALLY COUPLED SEMICONDUCTOR LASERS 413 IMAGE 11 CONTENTS XXI 8.5.3 PHOTONIC INTEGRATED CIRCUIT FOR COLLIDING-PULSE MODE-LOCKED LASERS 415 8.6 OTHER ENCODING AND DECODING TECHNIQUES 417 8.6.1 SPATIOTEMPORAL ENCODING 417 8.6.2 POLARIZATION ENCODING 419 8.6.3 MULTIPLEXING COMMUNICATIONS 421 8.7 NEW PERSPECTIVE OF OPTICAL COMMUNICATION WITH CHAOTIC LASERS 423 8.7.1 ANALOGY TO BIOLOGICAL COMMUNICATION SYSTEMS 423 8.7.2 TOWARDS THE WORLD OF SCIENTIFIC FICTION 424 9 SECURE KEY DISTRIBUTION BASED ON INFORMATION-THEORETIC SECURITY WITH CHAOTIC LASERS 427 9.1 INTRODUCTION 427 9.1.1 SECURE KEY DISTRIBUTION 427 9.1.2 COMPUTATIONAL SECURITY AND INFORMATION-THEORETIC SECURITY 428 9.2 CONCEPT OF INFORMATION-THEORETIC SECURITY 429 9.2.1 HISTORY OF INFORMATION-THEORETIC SECURITY AND MAURER'S SATELLITE SCENARIO 429 9.2.2 BOUNDED OBSERVABILITY 430 9.3 IMPLEMENTATION OF INFORMATION-THEORETIC SECURITY WITH CHAOTIC LASERS 431 9.3.1 BOUNDED OBSERVABILITY WITH CHAOTIC SEMICONDUCTOR LASERS 431 9.3.2 PUBLIC-CHANNEL CRYPTOGRAPHY WITH COUPLED CHAOTIC SEMICONDUCTOR LASERS 435 9.3.3 BIDIRECTIONAL MESSAGE TRANSMISSION WITH MUTUALLY COUPLED SEMICONDUCTOR LASERS 439 9.4 INFORMATION-THEORETIC SECURITY WITH OPTICAL NOISE 441 9.4.1 ULTRALONG FIBER-LASER SYSTEM 441 10 RANDOM NUMBER GENERATION WITH CHAOTIC LASERS 445 10.1 INTRODUCTION 445 10.1.1 NEEDS FOR RANDOM NUMBER GENERATION 445 10.1.2 EXTRACTION OF RANDOMNESS FROM CHAOTIC LASERS 447 10.2 TYPES OF RANDOM NUMBER GENERATORS 447 10.2.1 WHAT ARE RANDOM NUMBERS? 447 10.2.1.1 INDEPENDENCE 448 10.2.1.2 UNPREDICTABILITY 449 10.2.2 TWO TYPES OF RANDOM NUMBER GENERATORS 449 10.2.2.1 PHYSICAL RANDOM NUMBER GENERATORS (RNG) 449 10.2.2.2 PSEUDORANDOM NUMBER GENERATORS (PRNG) 453 10.2.3 ISSUES OF CONVENTIONAL RANDOM NUMBER GENERATORS 453 10.3 EXAMPLES OF RANDOM NUMBER GENERATORS WITH CHAOTIC LASERS 452 10.3.1 MONOBIT GENERATION WITH TWO LASERS 452 10.3.1.1 SCHEME 452 10.3.1.2 PARAMETER DEPENDENCE 457 IMAGE 12 XXII CONTENTS 10.3.2 MONOBIT GENERATION WITH ONE LASER 460 10.3.3 MULTIBIT GENERATION WITH ONE LASER 461 10.3.4 POSTPROCESSING FOR HIGH-SPEED RANDOM NUMBER GENERATION 463 10.3.5 BANDWIDTH ENHANCEMENT OF CHAOTIC LASERS FOR HIGH-SPEED RANDOM NUMBER GENERATION 465 10.3.6 PHOTONIC INTEGRATED CIRCUIT FOR RANDOM BIT GENERATORS 469 10.4 APPLICATION OF CHAOTIC-LASER-BASED RANDOM NUMBER GENERATORS TO HIGH-SPEED QUANTUM KEY DISTRIBUTION 472 10.5 NUMERICAL EVALUATION OF RANDOM NUMBER GENERATOR AS ENTROPY SOURCE 475 10.5.1 ENTROPY GENERATION FROM INTERNAL NOISE BY CHAOTIC DYNAMICS 475 10.5.2 ESTIMATION OF ENTROPY 477 10.5.3 ENTROPY RATE AND NONDETERMINISTIC BIT GENERATION 478 10.6 CONVENTIONAL METHODS FOR PHYSICAL RANDOM NUMBER GENERATORS 480 10.6.1 THERMAL NOISE 480 10.6.1.1 DIRECT AMPLIFICATION OF THERMAL NOISE 480 10.6.1.2 METASTABILITY 481 10.6.1.3 TWO OSCILLATORS WITH FREQUENCY JITTER 482 10.6.2 QUANTUM NOISE 484 10.6.3 OPTICAL NOISE (SPONTANEOUS EMISSION NOISE) 485 10.6.4 RADIATION FROM RADIOACTIVE NUCLIDE 486 10.6.5 CHAOTIC DYNAMICS IN ELECTRONIC CIRCUITS 487 10.6.6 TRADITIONAL PHYSICAL DEVICES 487 10.6.7 OTHER METHODS 488 10.6.8 COMMERCIAL PHYSICAL RANDOM NUMBER GENERATORS 488 10.6.8.1 INTEL CHIP (INTEL) 488 10.6.8.2 RANDOM MASTER (TOSHIBA) 489 10.6.8.3 RANDOM STREAMER (FDK) 490 10.6.8.4 QUANTIS (ID QUANTIQUE) 490 10.7 POSTPROCESSING TECHNIQUES FOR IMPROVEMENT OF RANDOMNESS 490 10.7.1 VON NEUMANN METHOD 491 10.7.2 EXDUSIVE-OR (XOR) METHOD 492 10.8 PSEUDORANDOM NUMBER GENERATORS 493 10.8.1 LINEAR CONGRUENTIAL METHOD 493 10.8.2 M SEQUENCE AND GENERALIZED FEEDBACK SHIFT REGISTER (GFSR) 494 10.8.3 COMBINED TAUSWORTHE METHOD 496 10.8.4 MERSENNE TWISTER 496 10.9 STATISTICAL EVALUATION OF RANDOM NUMBERS WITH NIST SPECIAL PUBLICATION 800-22 TEST SUITE 497 10.9.1 STRATEGIES FOR STATISTICAL ANALYSIS OF RANDOM NUMBER GENERATORS 497 10.9.2 EVALUATION OF P-VALUES 499 IMAGE 13 CONTENTS XXIII 10.9.3 INTERPRETATION OF EMPIRICAL RESULTS 501 10.9.3.1 PROPORTION OF P-VALUES 501 10.9.3.2 UNIFORMITY OF DISTRIBUTION OF P-VALUES 501 10.9.4 TENDENCY OF PASSED/FAILED NIST SP 800-22 TESTS IN LASER-CHAOS-BASED RANDOM NUMBER GENERATORS 502 10.9.5 OTHER STATISTICAL TESTS OF RANDOMNESS 503 APPENDIX 10.A.1 RECIPE FOR HIGH-QUALITY RANDOM NUMBER GENERATORS 503 10.A.2 DICHTL METHOD FOR POSTPROCESSING OF RANDOM NUMBER GENERATORS 504 10.A.3 ALGORITHM OF MERSENNE TWISTER PSEUDORANDOM NUMBER GENERATOR 505 10.A.4 DETAILED DESCRIPTION OF NIST SPECIAL PUBLICATION 800-22 506 10.A.4.1 FREQUENCY (MONOBIT) TEST 506 10.A.4.2 FREQUENCY TEST WITHIN A BLOCK 506 10.A.4.3 CUMULATIVE SUMS (CUSUMS) TEST 506 10.A.4.4 RUNS TEST 507 10.A.4.5 TESTS FOR THE LONGEST-RUN-OF-ONES IN A BLOCK 507 10.A.4.6 BINARY MATRIX RANK TEST 507 10.A.4.7 DISCRETE FOURIER TRANSFORM (SPECTRAL) TEST 507 10.A.4.8 NON-OVERLAPPING TEMPLATE MATCHING TEST 507 10.A.4.9 OVERLAPPING TEMPLATE MATCHING TEST 507 10.A.4.10 MAURER'S "UNIVERSAL STATISTICAL" TEST 508 10.A.4.11 APPROXIMATE ENTROPY TEST 508 10.A.4.12 RANDOM EXCURSIONS TEST 508 10.A.4.13 RANDOM EXCURSIONS VARIANT TEST 508 10.A.4.14 SERIAL TEST 508 10.A.4.15 LINEAR COMPLEXITY TEST 508 11 CONTROLLING CHAOS IN LASERS 511 11.1 CLASSIFICATION OF CONTROLLING CHAOS 511 11.1.1 FEEDBACK CONTROL METHOD 513 11.1.1.1 OGY METHOD 511 11.1.1.2 OCCASIONAL PROPORTIONAL FEEDBACK (OPF) METHOD 512 11.1.1.3 CONTINUOUS FEEDBACK CONTROL METHOD 513 11.1.2 NONFEEDBACK CONTROL METHOD 514 11.2 EXAMPLES OF CONTROLLING CHAOS IN LASERS 515 11.2.1 FEEDBACK CONTROL METHOD FOR CONTROLLING CHAOS IN LASERS 535 11.2.1.1 OCCASIONAL PROPORTIONAL FEEDBACK (OPF) METHOD 515 11.2.1.2 CONTINUOUS FEEDBACK CONTROL METHOD 518 11.2.2 NONFEEDBACK CONTROL METHOD FOR CONTROLLING CHAOS IN LASERS 521 11.2.2.1 LOSS MODULATION 523 IMAGE 14 XXIV CONTENTS 11.2.2.2 HIGH-FREQUENCY INJECTION (HFI) METHOD FOR SEMICONDUCTOR LASERS 523 11.2.2.3 STABILIZATION TO HIGH-PERIODIC OSCILLATIONS 525 11.3 APPLICATIONS OF CONTROLLING CHAOS IN LASERS 525 11.3.1 SUPPRESSION OF RELATIVE INTENSITY NOISE (RIN) 525 11.3.2 CHAOTIC SEARCH AND ADAPTIVE MODE SELECTION 527 11.3.3 DYNAMICAL MEMORY 528 11.3.4 COMMUNICATION WITH CHAOS BY CONTROLLING CHAOS 529 APPENDIX 11.A.1 OGY METHOD FOR CONTROLLING CHAOS 530 12 OTHER APPLICATIONS WITH CHAOTIC LASERS 533 12.1 REMOTE SENSING WITH CHAOTIC LASERS 533 12.1.1 CHAOTIC LIDAR 533 12.1.2 CHAOTIC RADAR 536 12.1.3 CHAOTIC CORRELATION OPTICAL TIME-DOMAIN REFLECTOMETER 539 12.2 BLIND SOURCE SEPARATION OF CHAOTIC SIGNALS BY USING INDEPENDENT COMPONENT ANALYSIS 542 12.2.1 MOTIVATION FOR BLIND SOURCE SEPARATION 542 12.2.2 PRINCIPLE OF INDEPENDENT COMPONENT ANALYSIS 543 12.2.3 EXAMPLES OF BLIND-SOURCE SEPARATION WITH CHAOTIC LASERS 544 12.3 FRACTAL OPTICS 547 12.3.1 CHAOS MIRROR FOR WIRELESS OPTICAL COMMUNICATIONS 548 12.3.2 FRACTAL PATTERNS IN REGULAR POLYHEDRAL MIRROR-BALL STRUCTURES 550 REFERENCES 557 GLOSSARY 575 G.I LIST OF ACRONYMS 575 G.I.I ACRONYMS OF TECHNICAL TERMS 575 G.I.2 ACRONYMS OF UNITS 578 G.2 SOURCE CODES OF C PROGRAMMING LANGUAGE FOR NUMERICAL SIMULATIONS 579 G.2.1 LOGISTIC MAP (CHAPTER 2) 579 G.2.1.1 C SOURCE CODE FOR SEQUENCE OF LOGISTIC MAP (FIGURE 2.5A) 579 G.2.1.2 C SOURCE CODE FOR BIFURCATION DIAGRAM OF LOGISTIC MAP (FIGURE 2.8) 580 G.2.1.3 C SOURCE CODE FOR LYAPUNOV EXPONENT OF LOGISTIC MAP (FIGURE 2.9) 581 G.2.2 LORENZ EUATIONS (CHAPTER 2) 582 G.2.2.1 C SOURCE CODE FOR TIME SERIES OF LORENZ EQUATIONS (FIGURE 2.10) 582 IMAGE 15 CONTENTS XXV G.2.2.2 C SOURCE CODE FOR BIFURCATION DIAGRAM OF LORENZ EQUATIONS (FIGURE 2.12A) 584 G.2.2.3 C SOURCE CODE FOR LYAPNOV SPECTRUM (ALL THE LYAPUNOV EXPONENTS) OF LORENZ EQUATIONS (FIGURE 2.12B) 586 G.2.2.4 C SOURCE CODE FOR SYNCHRONIZATION OF CHAOS IN LORENZ EQUATIONS (DIFFUSIVE COUPLING, SECTION 5.2.1.2) 590 G.2.3 LANG-KOBAYASHI EQUATIONS FOR A SEMICONDUCTOR LASER WITH TIME-DELAYED OPTICAL FEEDBACK (CHAPTER 4) 592 G.2.3.1 C SOURCE CODE FOR TIME SERIES OF LANG-KOBAYASHI EQUATIONS (FIGURE 4.13E) 592 G.2.3.2 C SOURCE CODE FOR BIFURCATION DIAGRAM OF LANG- KOBAYASHI EQUATIONS (FIGURE 4.16) 595 G.2.3.3 C SOURCE CODE FOR MAXIMUM LYAPUNOV EXPONENT OF LANG-KOBAYASHI EQUATIONS (FIGURE 4.19) 599 G.2.4 SYNCHRONIZATION OF CHAOS IN COUPLED LANG-KOBAYASHI EQUATIONS FOR UNIDIRECTIONALLY COUPLED SEMICONDUCTOR LASERS WITH TIME-DELAYED OPTICAL FEEDBACK (CHAPTER 6) 604 G.2.4.1 C SOURCE CODE FOR TIME SERIES OF SYNCHRONIZATION OF CHAOS IN COUPLED LANG-KOBAYASHI EQUATIONS IN OPEN-LOOP CONFIGURATION (FIGURE 6.9) 604 G.2.4.2 C SOURCE CODE FOR TIME SERIES OF SYNCHRONIZATION OF CHAOS IN COUPLED LANG-KOBAYASHI EQUATIONS IN CLOSED-LOOP CONFIGURATION (APPENDIX 6.A.1) 609 G.2.4.3 C SOURCE CODE FOR CROSS-CORRELATION CALCULATION OF SYNCHRONIZATION OF CHAOS IN COUPLED LANG-KOBAYASHI EQUATIONS IN OPEN-LOOP CONFIGURATION (FIGURES 6.10A AND C) 614 G.2.4.4 C SOURCE CODE FOR CONDITIONAL LYAPUNOV EXPONENT OF SYNCHRONIZATION OF CHAOS IN COUPLED LANG-KOBAYASHI EQUATIONS IN OPEN-LOOP CONFIGURATION (FIGURE 6.12) 620 INDEX 627
any_adam_object	1
author	Uchida, Atsushi
author_GND	(DE-588)1019246618
author_facet	Uchida, Atsushi
author_role	aut
author_sort	Uchida, Atsushi
author_variant	a u au
building	Verbundindex
bvnumber	BV039826348
classification_rvk	UH 5755 ZN 6280
ctrlnum	(OCoLC)757148934 (DE-599)DNB1013143922
dewey-full	621.3827
dewey-hundreds	600 - Technology (Applied sciences)
dewey-ones	621 - Applied physics
dewey-raw	621.3827
dewey-search	621.3827
dewey-sort	3621.3827
dewey-tens	620 - Engineering and allied operations
discipline	Physik Elektrotechnik / Elektronik / Nachrichtentechnik
format	Book
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id	DE-604.BV039826348
illustrated	Illustrated
indexdate	2024-07-21T00:21:48Z
institution	BVB
isbn	352740869X 9783527408696 9783527640331
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-024686364
oclc_num	757148934
open_access_boolean
owner	DE-11 DE-92 DE-1043 DE-29T DE-83 DE-20
owner_facet	DE-11 DE-92 DE-1043 DE-29T DE-83 DE-20
physical	XXVIII, 640 S. Ill., graph. Darst.
publishDate	2012
publishDateSearch	2012
publishDateSort	2012
publisher	Wiley-VCH
record_format	marc
spelling	Uchida, Atsushi Verfasser (DE-588)1019246618 aut Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization Atsushi Uchida Weinheim Wiley-VCH 2012 XXVIII, 640 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Nichtlineare Dynamik (DE-588)4126141-0 gnd rswk-swf Optische Nachrichtentechnik (DE-588)4035624-3 gnd rswk-swf Laser (DE-588)4034610-9 gnd rswk-swf Synchronisierung (DE-588)4130847-5 gnd rswk-swf Chaotisches System (DE-588)4316104-2 gnd rswk-swf Laser (DE-588)4034610-9 s Optische Nachrichtentechnik (DE-588)4035624-3 s Nichtlineare Dynamik (DE-588)4126141-0 s Chaotisches System (DE-588)4316104-2 s Synchronisierung (DE-588)4130847-5 s DE-604 Erscheint auch als Online-Ausgabe, EPUB 978-3-527-64034-8 Erscheint auch als Online-Ausgabe, MOBI 978-3-527-64036-2 Erscheint auch als Online-Ausgabe, PDF 978-3-527-64035-5 X:MVB text/html http://deposit.dnb.de/cgi-bin/dokserv?id=3847396&prov=M&dok_var=1&dok_ext=htm Inhaltstext DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024686364&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Uchida, Atsushi Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization Nichtlineare Dynamik (DE-588)4126141-0 gnd Optische Nachrichtentechnik (DE-588)4035624-3 gnd Laser (DE-588)4034610-9 gnd Synchronisierung (DE-588)4130847-5 gnd Chaotisches System (DE-588)4316104-2 gnd
subject_GND	(DE-588)4126141-0 (DE-588)4035624-3 (DE-588)4034610-9 (DE-588)4130847-5 (DE-588)4316104-2
title	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization
title_auth	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization
title_exact_search	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization
title_full	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization Atsushi Uchida
title_fullStr	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization Atsushi Uchida
title_full_unstemmed	Optical communication with chaotic lasers applications of nonlinear dynamics and synchronization Atsushi Uchida
title_short	Optical communication with chaotic lasers
title_sort	optical communication with chaotic lasers applications of nonlinear dynamics and synchronization
title_sub	applications of nonlinear dynamics and synchronization
topic	Nichtlineare Dynamik (DE-588)4126141-0 gnd Optische Nachrichtentechnik (DE-588)4035624-3 gnd Laser (DE-588)4034610-9 gnd Synchronisierung (DE-588)4130847-5 gnd Chaotisches System (DE-588)4316104-2 gnd
topic_facet	Nichtlineare Dynamik Optische Nachrichtentechnik Laser Synchronisierung Chaotisches System
url	http://deposit.dnb.de/cgi-bin/dokserv?id=3847396&prov=M&dok_var=1&dok_ext=htm http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024686364&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT uchidaatsushi opticalcommunicationwithchaoticlasersapplicationsofnonlineardynamicsandsynchronization

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