In Chaos in Electric Drive Systems: Analysis, Control and Application authors Chau and Wang systematically introduce an emerging technology of electrical engineering that bridges abstract chaos theory and practical electric drives. The authors consolidate all important information in this interdisciplinary technology, including the fundamental concepts, mathematical modeling, theoretical analysis, computer simulation, and hardware implementation. The book provides comprehensive coverage of chaos in electric drive systems with three main parts: analysis, control and application. Corresponding drive systems range from the simplest to the latest types: DC, induction, synchronous reluctance, switched reluctance, and permanent magnet brushless drives. The first book to comprehensively treat chaos in electric drive systemsReviews chaos in various electrical engineering technologies and drive systemsPresents innovative approaches to stabilize and stimulate chaos in typical drivesDiscusses practical application of chaos stabilization, chaotic modulation and chaotic motionAuthored by well-known scientists in the fieldLecture materials available from the book's companion website This book is ideal for researchers and graduate students who specialize in electric drives, mechatronics, and electric machinery, as well as those enrolled in classes covering advanced topics in electric drives and control. Engineers and product designers in industrial electronics, consumer electronics, electric appliances and electric vehicles will also find this book helpful in applying these emerging techniques. Lecture materials for instructors available at www.wiley.com/go/chau_chaos
Les mer
The first book to systematically cover chaos in electric drive systems, this book consolidates all important information in this emerging interdisciplinary field, including basic concepts, modeling, analysis, simulation, and hardware implementation.
Les mer
Preface xi Organization of this Book xiii Acknowledgments xv About the Authors xvii Part I Introduction 1 Overview of Chaos 3 1.1 What is Chaos? 3 1.2 Development of Chaology 4 1.3 Chaos in Electrical Engineering 8 1.3.1 Chaos in Electronic Circuits 9 1.3.2 Chaos in Telecommunications 10 1.3.3 Chaos in Power Electronics 11 1.3.4 Chaos in Power Systems 12 1.3.5 Chaos in Electric Drive Systems 13 References 16 2 Introduction to Chaos Theory and Electric Drive Systems 23 2.1 Basic Chaos Theory 23 2.1.1 Basic Principles 23 2.1.2 Criteria for Chaos 28 2.1.3 Bifurcations and Routes to Chaos 29 2.1.4 Analysis Methods 37 2.2 Fundamentals of Electric Drive Systems 45 2.2.1 General Considerations 45 2.2.2 DC Drive Systems 50 2.2.3 Induction Drive Systems 56 2.2.4 Synchronous Drive Systems 61 2.2.5 Doubly Salient Drive Systems 68 References 77 Part II Analysis of Chaos in Electric Drive Systems 3 Chaos in DC Drive Systems 81 3.1 Voltage-Controlled DC Drive System 81 3.1.1 Modeling 81 3.1.2 Analysis 83 3.1.3 Simulation 87 3.1.4 Experimentation 94 3.2 Current-Controlled DC Drive System 96 3.2.1 Modeling 96 3.2.2 Analysis 98 3.2.3 Simulation 102 3.2.4 Experimentation 108 References 110 4 Chaos in AC Drive Systems 113 4.1 Induction Drive Systems 113 4.1.1 Modeling 113 4.1.2 Analysis 116 4.1.3 Simulation 117 4.1.4 Experimentation 118 4.2 Permanent Magnet Synchronous Drive Systems 119 4.2.1 Modeling 120 4.2.2 Analysis 122 4.2.3 Simulation 125 4.2.4 Experimentation 127 4.3 Synchronous Reluctance Drive Systems 129 4.3.1 Modeling 130 4.3.2 Analysis 133 4.3.3 Simulation 136 4.3.4 Experimentation 139 References 143 5 Chaos in Switched Reluctance Drive Systems 145 5.1 Voltage-Controlled Switched Reluctance Drive System 146 5.1.1 Modeling 146 5.1.2 Analysis 149 5.1.3 Simulation 151 5.1.4 Experimentation 153 5.2 Current-Controlled Switched Reluctance Drive System 155 5.2.1 Modeling 155 5.2.2 Analysis 157 5.2.3 Simulation 159 5.2.4 Phenomena 163 References 166 Part III Control of Chaos in Electric Drive Systems 6 Stabilization of Chaos in Electric Drive Systems 171 6.1 Stabilization of Chaos in DC Drive System 171 6.1.1 Modeling 171 6.1.2 Analysis 175 6.1.3 Simulation 178 6.1.4 Experimentation 179 6.2 Stabilization of Chaos in AC Drive System 181 6.2.1 Nonlinear Feedback Control 182 6.2.2 Backstepping Control 183 6.2.3 Dynamic Surface Control 186 6.2.4 Sliding Mode Control 189 References 192 7 Stimulation of Chaos in Electric Drive Systems 193 7.1 Control-Oriented Chaoization 193 7.1.1 Time-Delay Feedback Control of PMDC Drive System 193 7.1.2 Time-Delay Feedback Control of PM Synchronous Drive System 199 7.1.3 Proportional Time-Delay Control of PMDC Drive System 201 7.1.4 Chaotic Signal Reference Control of PMDC Drive System 204 7.2 Design-Oriented Chaoization 207 7.2.1 Doubly Salient PM Drive System 209 7.2.2 Shaded-Pole Induction Drive System 219 References 231 Part IV Application of Chaos in Electric Drive Systems 8 Application of Chaos Stabilization 235 8.1 Chaos Stabilization in Automotive Wiper Systems 235 8.1.1 Modeling 236 8.1.2 Analysis 238 8.1.3 Stabilization 240 8.2 Chaos Stabilization in Centrifugal Governor Systems 246 8.2.1 Modeling 247 8.2.2 Analysis 248 8.2.3 Stabilization 248 8.3 Chaos Stabilization in Rate Gyro Systems 250 8.3.1 Modeling 251 8.3.2 Analysis 253 8.3.3 Stabilization 253 References 255 9 Application of Chaotic Modulation 257 9.1 Overview of PWM Schemes 257 9.1.1 Voltage-Controlled PWM Schemes 257 9.1.2 Current-Controlled PWM Schemes 260 9.2 Noise and Vibration 261 9.3 Chaotic PWM 263 9.3.1 Chaotic Sinusoidal PWM 265 9.3.2 Chaotic Space Vector PWM 269 9.4 Chaotic PWM Inverter Drive Systems 271 9.4.1 Open-Loop Control Operation 272 9.4.2 Closed-Loop Vector Control Operation 273 References 280 10 Application of Chaotic Motion 283 10.1 Chaotic Compaction 283 10.1.1 Compactor System 285 10.1.2 Chaotic Compaction Control 286 10.1.3 Compaction Simulation 287 10.1.4 Compaction Experimentation 290 10.2 Chaotic Mixing 292 10.2.1 Mixer System 293 10.2.2 Chaotic Mixing Control 294 10.2.3 Chaotic Mixing Simulation 295 10.2.4 Chaotic Mixing Experimentation 298 10.3 Chaotic Washing 301 10.3.1 Chaotic Clothes-Washer 302 10.3.2 Chaotic Dishwasher 304 10.4 Chaotic HVAC 306 10.5 Chaotic Grinding 309 References 312 Index 315
Les mer
CHAOS IN ELECTRIC DRIVE SYSTEMS Analysis, Control and Application In Chaos in Electric Drive Systems: Analysis, Control and Application, authors Chau and Wang systematically introduce an emerging technology of electrical engineering that bridges abstract chaos theory and practical electric drives. The authors consolidate all important information in this interdisciplinary technology, including the fundamental concepts, mathematical modeling, theoretical analysis, computer simulation, and hardware implementation. The book provides comprehensive coverage of chaos in electric drive systems with three main parts: analysis, control and application. Corresponding drive systems range from the simplest to the latest types: DC, induction, synchronous reluctance, switched reluctance, and permanent magnet brushless drives. The first book to comprehensively treat chaos in electric drive systemsReviews chaos in various electrical engineering technologies and drive systemsPresents innovative approaches to stabilize and stimulate chaos in typical drivesDiscusses practical application of chaos stabilization, chaotic modulation and chaotic motionAuthored by well-known scientists in the fieldLecture materials available from the book's companion website This book is ideal for researchers and graduate students who specialize in electric drives, mechatronics, and electric machinery, as well as those enrolled in classes covering advanced topics in electric drives and control. Engineers and product designers in industrial electronics, consumer electronics, electric appliances and electric vehicles will also fi nd this book helpful in applying these emerging techniques.
Les mer

Produktdetaljer

ISBN
9780470826331
Publisert
2011-05-17
Utgiver
Vendor
Wiley-IEEE Press
Vekt
724 gr
Høyde
248 mm
Bredde
175 mm
Dybde
22 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Innbundet
Antall sider
288

Biographical note

K. T. Chau, The University of Hong Kong, Hong Kong, China

Zheng Wang, Southeast University, China