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This book is devoted to resonant energy conversion in power
electronics. It is a practical, systematic guide to the analysis
and design of various dc-dc resonant inverters, high-frequency
rectifiers, and dc-dc resonant converters that are building blocks
of many of today's high-frequency energy processors. Designed to
function as both a superior senior-to-graduate level textbook for
electrical engineering courses and a valuable professional
reference for practicing engineers, it provides students and
engineers with a solid grasp of existing high-frequency technology,
while acquainting them with a number of easy-to-use tools for the
analysis and design of resonant power circuits. Resonant power
conversion technology is now a very hot area and in the center of
the renewable energy and energy harvesting technologies.
Auteur
Marian K. Kazimierczuk, PhD, DSci, is the Robert J.
Kegerreis Distinguished Professor of Teaching and was Brage Golding
Distinguished Professor of Research Award at Wright State
University. D. Kazimierczuk has taught graduate courses in
high-frequency power electronics for more than twenty years in the
Department of Electrical Engineering. He has won the Board of
Trustees' Award for Faculty Excellence, several Excellence in
Teaching and Research Awards from Wright State University, the
Outstanding Teaching Award from the American Society for
Engineering Education, and the National Professorship of Technical
Sciences awarded by the President of Poland. He holds seven patents
and is the author of six books, 145 peer-reviewed journal papers,
and 190 conference papers. Dr. Kazimierczuk is an IEEE Fellow and
also an Associate Editor of the IEEE Transactions on Industrial
Electronics and International Journal of Circuit Theory and
Application.
Dariusz Czarkowski, PhD, is an Associate Professor in the
Department of Electrical and Computer Engineering at the
Polytechnic Institute of New York University. His research focuses
on power electronics and power systems.
Résumé
This book is devoted to resonant energy conversion in power electronics. It is a practical, systematic guide to the analysis and design of various dc-dc resonant inverters, high-frequency rectifiers, and dc-dc resonant converters that are building blocks of many of today's high-frequency energy processors. Designed to function as both a superior senior-to-graduate level textbook for electrical engineering courses and a valuable professional reference for practicing engineers, it provides students and engineers with a solid grasp of existing high-frequency technology, while acquainting them with a number of easy-to-use tools for the analysis and design of resonant power circuits. Resonant power conversion technology is now a very hot area and in the center of the renewable energy and energy harvesting technologies.
Contenu
PREFACE xxi
ABOUT THE AUTHORS xxv
LIST OF SYMBOLS xxvii
I Introduction 1
1.1 References 5
PART I RECTIFIERS 7
2 Class D Current-Driven Rectifiers 9
2.1 Introduction 9
2.2 Assumptions 10
2.3 Class D Half-Wave Rectifier 10
2.4 Class D Transformer Center-Tapped Rectifier 20
2.5 Class D Bridge Rectifier 28
2.6 Effects of Equivalent Series Resistance and Equivalent Series Inductance 34
2.7 Synchronous Rectifiers 38
3 Class D Voltage-Driven Rectifiers 47
3.1 Introduction 47
3.2 Assumptions 47
3.3 Class D Half-Wave Rectifier 48
3.4 Class D Transformer Center-Tapped Rectifier 56
3.5 Class D Bridge Rectifier 62
3.6 Synchronous Rectifiers 66
4 Class E Low dv/dt Rectifiers 72
4.1 Introduction 72
4.2 Low dv/dt Rectifier with a Parallel Capacitor 72
4.3 Resonant Low dv/dt Rectifier 90
5 Class E Low di/dt Rectifiers 109
5.1 Introduction 109
5.2 Low di/dt Rectifier with a Parallel Inductor 109
5.3 Low di/dt Rectifier with a Series Inductor 125
PART II INVERTERS 141
6 Class D Series-Resonant Inverter 143
6.1 Introduction 143
6.2 Circuit Description 144
6.3 Principle of Operation 146
6.4 Topologies of Class D Voltage-Source Inverters 152
6.5 Analysis 155
6.6 Voltage Transfer Function 166
6.7 Efficiency 170
6.8 Design Example 177
6.9 Class D Full-Bridge Series-Resonant Inverter 180
6.10 RelationshipsAmong Inverters and Rectifiers 187
7 Class D Parallel-Resonant Inverter 193
7.1 Introduction 193
7.2 Principle of Operation 193
7.3 Analysis 197
7.4 Short-Circuit and Open-Circuit Operation 219
7.5 Electronic Ballast for Fluorescent Lamps 223
7.6 Design Example 225
7.7 Full-Bridge Parallel-Resonant Inverter 227
8 Class D Series-Parallel-Resonant Inverter 235
8.1 Introduction 235
8.2 Principle of Operation 235
8.3 Analysis 237
8.4 Design Example 254
8.5 Full-Bridge Series-Parallel-Resonant Inverter 257
9 Class D CLL Resonant Inverter 262
9.1 Introduction 262
9.2 Principle of Operation 262
9.3 Analysis 264
9.4 Design Example 282
9.5 Full-Bridge CLL Resonant Inverter 285
10 Class D Current-Source-Resonant Inverter 290
10.1 Introduction 290
10.2 Principle of Operation 291
10.3 Analysis of the Parallel-Resonant Circuit 295
10.4 Analysis of the Inverter 297
10.5 Design Example 307
11 Phase-Controlled Resonant Inverters 311
11.1 Introduction 311
11.2 Phase-Controlled Current-Source Inverters 312
11.3 Phase-Controlled Voltage-Source Inverters 316
11.4 Single-Capacitor Phase-Controlled Series-Resonant Inverter 320
11.5 Design Example 328
12 Class E Zero-Voltage-Switching Resonant Inverter 334
12.1 Introduction 334
12.2 Principle of Operation 335
12.3 Analysis 340
12.4 Parameters at D=0.5 349
12.5 Efficiency 351
12.6 Matching Resonant Circuits 354
12.7 Design Example 359
12.8 Push-Pull Class E ZVS Inverter 362
13 Class E Zero-Current-Switching Resonant Inverter 369
13.1 Introduction 369
13.2 Circuit Description 369
13.3 Principle of Operation 370
13.4 Analysis 373
13.5 Power Relationships 378 13.6...