PREFACE xi

CHAPTER 1 INTRODUCTION 1

1.1 Introduction 1

1.2 Background 3

1.3 History of Power Switches and Power Converters 4

1.4 Applications of Power Electronics Converters 6

1.5 Summary 9

References 9

CHAPTER 2 POWER SWITCHES AND OVERVIEW OF BASIC POWER CONVERTERS 10

2.1 Introduction 10

2.2 Power Electronics Devices as Ideal Switches 11

2.2.1 Static Characteristics 12

2.2.2 Dynamic Characteristics 12

2.3 Main Real Power Semiconductor Devices 16

2.3.1 Spontaneous Conduction/Spontaneous Blocking 17

2.3.2 Controlled Conduction/Spontaneous Blocking Devices 18

2.3.3 Controlled Conduction/Controlled Blocking Devices 19

2.3.4 Spontaneous Conduction/Controlled Blocking Devices 22

2.3.5 List of Inventors of the Major Power Switches 24

2.4 Basic Converters 25

2.4.1 dc dc Conversion 28

2.4.2 dc ac Conversion 33

2.4.3 ac dc Conversion 43

2.4.4 ac dc Conversion 49

2.5 Summary 50

References 52

CHAPTER 3 POWER ELECTRONICS CONVERTERS PROCESSING ac VOLTAGE AND POWER BLOCKS GEOMETRY 56

3.1 Introduction 56

3.2 Principles of Power Blocks Geometry (PBG) 58

3.3 Description of Power Blocks 62

3.4 Application of PBG in Multilevel Configurations 67

3.4.1 Neutral–Point–Clamped Configuration 68

3.4.2 Cascade Configuration 72

3.4.3 Flying Capacitor Configuration 75

3.4.4 Other Multilevel Configurations 79

3.5 Application of PBG in ac dc ac Configurations 81

3.5.1 Three–Phase to Three–Phase Configurations 82

3.5.2 Single–Phase to Single–Phase Configurations 85

3.6 Summary 85

References 87

CHAPTER 4 NEUTRAL–POINT–CLAMPED CONFIGURATION 88

4.1 Introduction 88

4.2 Three–Level Configuration 89

4.3 PWM Implementation (Half–Bridge Topology) 93

4.4 Full–Bridge Topologies 95

4.5 Three–Phase NPC Converter 98

4.6 Nonconventional Arrangements by Using Three–Level Legs 101

4.7 Unbalanced Capacitor Voltage 108

4.8 Four–Level Configuration 112

4.9 PWM Implementation (Four–Level Configuration) 115

4.10 Full–Bridge and Other Circuits (Four–Level Configuration) 118

4.11 Five–Level Configuration 119

4.12 Summary 124

References 124

CHAPTER 5 CASCADE CONFIGURATION 125

5.1 Introduction 125

5.2 Single H–Bridge Converter 126

5.3 PWM Implementation of A Single H–Bridge Converter 129

5.4 Three–Phase Converter One H–Bridge Converter Per Phase 140

5.5 Two H–Bridge Converters 144

5.6 PWM Implementation of Two Cascade H–Bridges 146

5.7 Three–Phase Converter Two Cascade H–Bridges Per Phase 149

5.8 Two H–Bridge Converters (Seven– and Nine–Level Topologies) 162

5.9 Three H–Bridge Converters 164

5.10 Four H–Bridge Converters and Generalization 169

5.11 Summary 169

References 170

CHAPTER 6 FLYING–CAPACITOR CONFIGURATION 172

6.1 Introduction 172

6.2 Three–Level Configuration 173

6.3 PWM Implementation (Half–Bridge Topology) 177

6.4 Flying Capacitor Voltage Control 179

6.5 Full–Bridge Topology 181

6.6 Three–Phase FC Converter 183

6.7 Nonconventional FC Converters with Three–Level Legs 186

6.8 Four–Level Configuration 189

6.9 Generalization 196

6.10 Summary 197

References 198

CHAPTER 7 OTHER MULTILEVEL CONFIGURATIONS 199

7.1 Introduction 199

7.2 Nested Configuration 200

7.3 Topology with Magnetic Element at the Output 205

7.4 Active–Neutral–Point–Clamped Converters 211

7.5 More Multilevel Converters 214

7.6 Summary 218

References 219

CHAPTER 8 OPTIMIZED PWM APPROACH 221

8.1 Introduction 221

8.2 Two–Leg Converter 222

8.2.1 Model 222

8.2.2 PWM Implementation 223

8.2.3 Analog and Digital Implementation 228

8.2.4 Influence of for PWM Implementation 231

8.3 Three–Leg Converter and Three–Phase Load 233

8.3.1 Model 233

8.3.2 PWM Implementation 235

8.3.3 Analog and Digital Implementation 236

8.3.4 Influence of for PWM Implementation in a Three–Leg Converter 236

8.3.5 Influence of the Three–Phase Machine Connection over Inverter Variables 238

8.4 Space Vector Modulation (SVPWM) 243

8.5 Other Configurations with CPWM 247

8.5.1 Three–Leg Converter Two–Phase Machine 247

8.5.2 Four–Leg Converter 249

8.6 Nonconventional Topologies with CPWM 252

8.6.1 Inverter with Split–Wound Coupled Inductors 252

8.6.2 Z–Source Converter 254

8.6.3 Open–End Winding Motor Drive System 257

8.7 Summary 261

References 261

CHAPTER 9 CONTROL STRATEGIES FOR POWER CONVERTERS 264

9.1 Introduction 264

9.2 Basic Control Principles 265

9.3 Hysteresis Control 271

9.3.1 Application of the Hysteresis Control for dc Motor Drive 275

9.3.2 Hysteresis Control for Regulating an ac Variable 278

9.4 Linear Control dc Variable 279

9.4.1 Proportional Controller: RL Load 279

9.4.2 Proportional Controller: dc Motor Drive System 280

9.4.3 Proportional–Integral Controller: RL Load 283

9.4.4 Proportional–Integral Controller: dc Motor 285

9.4.5 Proportional–Integral–Derivative Controller: dc Motor 286

9.5 Linear Control ac Variable 288

9.6 Cascade Control Strategies 289

9.6.1 Rectifier Circuit: Voltage–Current Control 289

9.6.2 Motor Drive: Speed–Current Control 290

9.7 Summary 293

References 293

CHAPTER 10 SINGLE–PHASE TO SINGLE–PHASE BACK–TO–BACK CONVERTER 295

10.1 Introduction 295

10.2 Full–Bridge Converter 296

10.2.1 Model 296

10.2.2 PWM Strategy 297

10.2.3 Control Approach 298

10.2.4 Power Analysis 299

10.2.5 dc–link Capacitor Voltage 301

10.2.6 Capacitor Bank Design 304

10.3 Topology with Component Count Reduction 307

10.3.1 Model 307

10.3.2 PWM Strategy 308

10.3.3 dc–link Voltage Requirement 309

10.3.4 Half–Bridge Converter 310

10.4 Topologies with Increased Number of Switches (Converters in Parallel) 310

10.4.1 Model 311

10.4.2 PWM Strategy 315

10.4.3 Control Strategy 316

10.5 Topologies with Increased Number of Switches (Converters in Series) 318

10.6 Summary 321

References 321

CHAPTER 11 THREE–PHASE TO THREE–PHASE AND OTHER BACK–TO–BACK CONVERTERS 324

11.1 Introduction 324

11.2 Full–Bridge Converter 325

11.2.1 Model 325

11.2.2 PWM Strategy 327

11.2.3 Control Approach 328

11.3 Topology with Component Count Reduction 330

11.3.1 Model 330

11.3.2 PWM Strategies 331

11.3.3 dc–link Voltage Requirement 332

11.3.4 Half–Bridge Converter 332

11.4 Topologies with Increased Number of Switches (Converters in Parallel) 332

11.4.1 Model 333

11.4.2 PWM 338

11.4.3 Control Strategies 339

11.5 Topologies with Increased Number of Switches (Converters in Series) 340

11.6 Other Back–To–Back Converters 340

11.7 Summary 344

References 344

INDEX 347

Euzeli Cipriano dos Santos Jr. is an assistant professor at Indiana University–Purdue University, Indianapolis. He teaches an electromechanical motion devices course, as well as energy conversion. Previously, he served as a research scholar at Texas A&M University.

Edison Roberto Cabral da Silva is an Emeritus Professor within the Department of Electrical Engineering at the Federal University of Campina Grande, and also a visiting professor at the Federal University of Paraiba, Brazil. He was the director of the research laboratory on industrial electronics and machine drives for 30 years and has been teaching over 38 years. He has published over 270 papers on Power Electronics. He is a researcher from the National Council for Research (CNPq), Brazil.

This book deals with a new methodology to present an important class of electric devices, i.e., power converters. Since the text focuses primarily on converters, it is able to provide extensive detail of each topology and its conception.

This book focuses on the PWM power converters operating in conjunction with the AC utility. The topic is important and contemporary in modern power electronics as the utility–interfacing power conversion becomes increasingly dominant in the power conversion applications. Since this book specifically covers subjects related to converters, it has allowed for additional room to explore the details of each topology, conception, and conceptual construction of power electronics converters. Stability, dynamic performance, compensation design of power converters, as well as broader topics such as control strategies, are among the important topics that are discussed.

Some of the other unique features of the book are as follows:

• Introduces a new method to present power electronics converters called Power Blocks Geometry (PBG)
• Applicable for courses focusing on power electronics, power electronics converters, and advanced power converters
• Chapter 2 supplies prerequisite knowledge of power devices and basic concepts of converters, which will help undergraduate level students studying power electronics and power electronics converters follow the text
• Offers a comprehensive set of simulation results to help understand the circuits presented throughout the book

Advanced Power Electronics Converters PWM Converters Processing AC Voltages deals with a new methodology to present an important class of electronics converters. dos Santos and da Silva provide a unique approach to the topic by considering the origins and development of power electronics converters, which will enable students to construction new topologies from the conventional ones.