Impedance Source Matrix Converters and Control
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portes grátis
Impedance Source Matrix Converters and Control
Li, Xiao; Abu-Rub, Haitham; Ge, Baoming; Blaabjerg, Frede; Liu, Yushan
John Wiley & Sons Inc
12/2024
272
Dura
9781119906896
15 a 20 dias
Descrição não disponível.
About the Authors xi
Preface xiii
Acknowledgment xiv
1 Background 1
1.1 Power Electronics Converter Topologies and Applications in Modern Power Systems 1
1.2 ZS/QZS Converters 11
1.3 Advantages of ZS/QZS MCs Compared to Existing Technology 12
1.4 Current Status and Future Trends 15
1.5 Contents Overview 16
2 Z-Source/Quasi-Z-Source Direct Matrix Converter 27
2.1 Introduction 27
2.2 Topology and Operating Principle 29
2.3 Modulation Methods 35
2.4 Simulation and Experimental Results 44
2.5 Conclusion 49
3 Z-Source/Quasi-Z-Source Indirect Matrix Converter (Non-All SiC Solution) 53
3.1 Introduction 53
3.2 Topologies and Operating Principle 55
3.3 Modulation Methods 62
3.4 Simulation Results and Applications 65
3.5 Conclusion 71
4 Z-Source/Quasi-Z-Source Indirect Matrix Converter (All SiC Solution) 75
4.1 Introduction 75
4.2 Topologies and Operating Principle 75
4.3 Modulation Methods 82
4.4 Simulation and Experimental Results 97
4.5 Conclusion 101
5 Comparison of Typical Z-Source/Quasi-Z-Source Matrix Converters 105
5.1 Introduction 105
5.2 Operation Analysis of Novel QZS-IMC 109
5.3 Small-Signal Modeling of QZS-IMC 111
5.4 Voltage Gain Investigation 112
5.5 QZS Network's Filtering Function Investigation 116
5.6 Parameters Design of QZS Network 118
5.7 Simulation and Experimental Results 121
5.8 Conclusion 128
6 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters 131
6.1 Introduction 131
6.2 Topology and Modulation of the 3-1-Phase QZS-MC 132
6.3 Modeling and Analysis of Three-Phase-to-Single-Phase qZS-MC 135
6.4 Simulation and Experimental Tests 139
6.5 Conclusion 142
7 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters With Low-Frequency Power Compensation 145
7.1 Introduction 145
7.2 The 3-1-Phase QZS-MC with Input Low-Frequency Harmonic Elimination 146
7.3 Existed Harmonic Components and Required Impedance ParametersWithout Ripple Compensation 147
7.4 Predictive Control of Ripple Compensation Branch 149
7.5 Simulation and Experimental Tests 150
7.6 Conclusion 155
8 Model Predictive Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 161
8.1 Introduction 161
8.2 LC Filter-Integrated QZS-IMC 162
8.3 Principle of Model Predictive Control 163
8.4 Proposed MPC for LC Filter-Integrated QZS-IMC 164
8.5 Simulation and Experimental Results 169
8.6 Conclusion 173
9 Optimum Boost Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 177
9.1 Introduction 177
9.2 Gain Model and Modulation of QZS-IMC System 179
9.3 Multi-Constraints Optimization and Operation Control for QZS-IMC 182
9.4 Simulation and Experimental Verifications 188
9.5 Conclusion 203
10 Applications in Motor Drives 207
10.1 Introduction 207
10.2 LC Filter-Integrated QZS-IMC 208
10.3 QZS-IMC Induction Motor Drive Control 210
10.4 Simulation and Experimental Verifications 215
10.5 Conclusions 224
11 Future Trends 227
11.1 General Expectation 227
11.2 Dual-Three-Level QZS-IMC-Based Power Drive System 229
11.3 Motor Control Strategy 236
11.4 Experimental Verifications 240
11.5 Discussion 245
11.6 Conclusion 247
References 247
Index 251
Preface xiii
Acknowledgment xiv
1 Background 1
1.1 Power Electronics Converter Topologies and Applications in Modern Power Systems 1
1.2 ZS/QZS Converters 11
1.3 Advantages of ZS/QZS MCs Compared to Existing Technology 12
1.4 Current Status and Future Trends 15
1.5 Contents Overview 16
2 Z-Source/Quasi-Z-Source Direct Matrix Converter 27
2.1 Introduction 27
2.2 Topology and Operating Principle 29
2.3 Modulation Methods 35
2.4 Simulation and Experimental Results 44
2.5 Conclusion 49
3 Z-Source/Quasi-Z-Source Indirect Matrix Converter (Non-All SiC Solution) 53
3.1 Introduction 53
3.2 Topologies and Operating Principle 55
3.3 Modulation Methods 62
3.4 Simulation Results and Applications 65
3.5 Conclusion 71
4 Z-Source/Quasi-Z-Source Indirect Matrix Converter (All SiC Solution) 75
4.1 Introduction 75
4.2 Topologies and Operating Principle 75
4.3 Modulation Methods 82
4.4 Simulation and Experimental Results 97
4.5 Conclusion 101
5 Comparison of Typical Z-Source/Quasi-Z-Source Matrix Converters 105
5.1 Introduction 105
5.2 Operation Analysis of Novel QZS-IMC 109
5.3 Small-Signal Modeling of QZS-IMC 111
5.4 Voltage Gain Investigation 112
5.5 QZS Network's Filtering Function Investigation 116
5.6 Parameters Design of QZS Network 118
5.7 Simulation and Experimental Results 121
5.8 Conclusion 128
6 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters 131
6.1 Introduction 131
6.2 Topology and Modulation of the 3-1-Phase QZS-MC 132
6.3 Modeling and Analysis of Three-Phase-to-Single-Phase qZS-MC 135
6.4 Simulation and Experimental Tests 139
6.5 Conclusion 142
7 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters With Low-Frequency Power Compensation 145
7.1 Introduction 145
7.2 The 3-1-Phase QZS-MC with Input Low-Frequency Harmonic Elimination 146
7.3 Existed Harmonic Components and Required Impedance ParametersWithout Ripple Compensation 147
7.4 Predictive Control of Ripple Compensation Branch 149
7.5 Simulation and Experimental Tests 150
7.6 Conclusion 155
8 Model Predictive Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 161
8.1 Introduction 161
8.2 LC Filter-Integrated QZS-IMC 162
8.3 Principle of Model Predictive Control 163
8.4 Proposed MPC for LC Filter-Integrated QZS-IMC 164
8.5 Simulation and Experimental Results 169
8.6 Conclusion 173
9 Optimum Boost Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 177
9.1 Introduction 177
9.2 Gain Model and Modulation of QZS-IMC System 179
9.3 Multi-Constraints Optimization and Operation Control for QZS-IMC 182
9.4 Simulation and Experimental Verifications 188
9.5 Conclusion 203
10 Applications in Motor Drives 207
10.1 Introduction 207
10.2 LC Filter-Integrated QZS-IMC 208
10.3 QZS-IMC Induction Motor Drive Control 210
10.4 Simulation and Experimental Verifications 215
10.5 Conclusions 224
11 Future Trends 227
11.1 General Expectation 227
11.2 Dual-Three-Level QZS-IMC-Based Power Drive System 229
11.3 Motor Control Strategy 236
11.4 Experimental Verifications 240
11.5 Discussion 245
11.6 Conclusion 247
References 247
Index 251
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
impedance source matrix converters topology; impedance source matrix converters control; 3-1-phase matrix converters; matrix converters; power electronics; renewable energy conversion; ac-ac electronics; LC filter integrated
About the Authors xi
Preface xiii
Acknowledgment xiv
1 Background 1
1.1 Power Electronics Converter Topologies and Applications in Modern Power Systems 1
1.2 ZS/QZS Converters 11
1.3 Advantages of ZS/QZS MCs Compared to Existing Technology 12
1.4 Current Status and Future Trends 15
1.5 Contents Overview 16
2 Z-Source/Quasi-Z-Source Direct Matrix Converter 27
2.1 Introduction 27
2.2 Topology and Operating Principle 29
2.3 Modulation Methods 35
2.4 Simulation and Experimental Results 44
2.5 Conclusion 49
3 Z-Source/Quasi-Z-Source Indirect Matrix Converter (Non-All SiC Solution) 53
3.1 Introduction 53
3.2 Topologies and Operating Principle 55
3.3 Modulation Methods 62
3.4 Simulation Results and Applications 65
3.5 Conclusion 71
4 Z-Source/Quasi-Z-Source Indirect Matrix Converter (All SiC Solution) 75
4.1 Introduction 75
4.2 Topologies and Operating Principle 75
4.3 Modulation Methods 82
4.4 Simulation and Experimental Results 97
4.5 Conclusion 101
5 Comparison of Typical Z-Source/Quasi-Z-Source Matrix Converters 105
5.1 Introduction 105
5.2 Operation Analysis of Novel QZS-IMC 109
5.3 Small-Signal Modeling of QZS-IMC 111
5.4 Voltage Gain Investigation 112
5.5 QZS Network's Filtering Function Investigation 116
5.6 Parameters Design of QZS Network 118
5.7 Simulation and Experimental Results 121
5.8 Conclusion 128
6 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters 131
6.1 Introduction 131
6.2 Topology and Modulation of the 3-1-Phase QZS-MC 132
6.3 Modeling and Analysis of Three-Phase-to-Single-Phase qZS-MC 135
6.4 Simulation and Experimental Tests 139
6.5 Conclusion 142
7 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters With Low-Frequency Power Compensation 145
7.1 Introduction 145
7.2 The 3-1-Phase QZS-MC with Input Low-Frequency Harmonic Elimination 146
7.3 Existed Harmonic Components and Required Impedance ParametersWithout Ripple Compensation 147
7.4 Predictive Control of Ripple Compensation Branch 149
7.5 Simulation and Experimental Tests 150
7.6 Conclusion 155
8 Model Predictive Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 161
8.1 Introduction 161
8.2 LC Filter-Integrated QZS-IMC 162
8.3 Principle of Model Predictive Control 163
8.4 Proposed MPC for LC Filter-Integrated QZS-IMC 164
8.5 Simulation and Experimental Results 169
8.6 Conclusion 173
9 Optimum Boost Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 177
9.1 Introduction 177
9.2 Gain Model and Modulation of QZS-IMC System 179
9.3 Multi-Constraints Optimization and Operation Control for QZS-IMC 182
9.4 Simulation and Experimental Verifications 188
9.5 Conclusion 203
10 Applications in Motor Drives 207
10.1 Introduction 207
10.2 LC Filter-Integrated QZS-IMC 208
10.3 QZS-IMC Induction Motor Drive Control 210
10.4 Simulation and Experimental Verifications 215
10.5 Conclusions 224
11 Future Trends 227
11.1 General Expectation 227
11.2 Dual-Three-Level QZS-IMC-Based Power Drive System 229
11.3 Motor Control Strategy 236
11.4 Experimental Verifications 240
11.5 Discussion 245
11.6 Conclusion 247
References 247
Index 251
Preface xiii
Acknowledgment xiv
1 Background 1
1.1 Power Electronics Converter Topologies and Applications in Modern Power Systems 1
1.2 ZS/QZS Converters 11
1.3 Advantages of ZS/QZS MCs Compared to Existing Technology 12
1.4 Current Status and Future Trends 15
1.5 Contents Overview 16
2 Z-Source/Quasi-Z-Source Direct Matrix Converter 27
2.1 Introduction 27
2.2 Topology and Operating Principle 29
2.3 Modulation Methods 35
2.4 Simulation and Experimental Results 44
2.5 Conclusion 49
3 Z-Source/Quasi-Z-Source Indirect Matrix Converter (Non-All SiC Solution) 53
3.1 Introduction 53
3.2 Topologies and Operating Principle 55
3.3 Modulation Methods 62
3.4 Simulation Results and Applications 65
3.5 Conclusion 71
4 Z-Source/Quasi-Z-Source Indirect Matrix Converter (All SiC Solution) 75
4.1 Introduction 75
4.2 Topologies and Operating Principle 75
4.3 Modulation Methods 82
4.4 Simulation and Experimental Results 97
4.5 Conclusion 101
5 Comparison of Typical Z-Source/Quasi-Z-Source Matrix Converters 105
5.1 Introduction 105
5.2 Operation Analysis of Novel QZS-IMC 109
5.3 Small-Signal Modeling of QZS-IMC 111
5.4 Voltage Gain Investigation 112
5.5 QZS Network's Filtering Function Investigation 116
5.6 Parameters Design of QZS Network 118
5.7 Simulation and Experimental Results 121
5.8 Conclusion 128
6 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters 131
6.1 Introduction 131
6.2 Topology and Modulation of the 3-1-Phase QZS-MC 132
6.3 Modeling and Analysis of Three-Phase-to-Single-Phase qZS-MC 135
6.4 Simulation and Experimental Tests 139
6.5 Conclusion 142
7 Z-Source/Quasi-Z-Source 3-1-Phase Matrix Converters With Low-Frequency Power Compensation 145
7.1 Introduction 145
7.2 The 3-1-Phase QZS-MC with Input Low-Frequency Harmonic Elimination 146
7.3 Existed Harmonic Components and Required Impedance ParametersWithout Ripple Compensation 147
7.4 Predictive Control of Ripple Compensation Branch 149
7.5 Simulation and Experimental Tests 150
7.6 Conclusion 155
8 Model Predictive Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 161
8.1 Introduction 161
8.2 LC Filter-Integrated QZS-IMC 162
8.3 Principle of Model Predictive Control 163
8.4 Proposed MPC for LC Filter-Integrated QZS-IMC 164
8.5 Simulation and Experimental Results 169
8.6 Conclusion 173
9 Optimum Boost Control of LC Filter-Integrated Quasi-Z-Source Indirect Matrix Converter 177
9.1 Introduction 177
9.2 Gain Model and Modulation of QZS-IMC System 179
9.3 Multi-Constraints Optimization and Operation Control for QZS-IMC 182
9.4 Simulation and Experimental Verifications 188
9.5 Conclusion 203
10 Applications in Motor Drives 207
10.1 Introduction 207
10.2 LC Filter-Integrated QZS-IMC 208
10.3 QZS-IMC Induction Motor Drive Control 210
10.4 Simulation and Experimental Verifications 215
10.5 Conclusions 224
11 Future Trends 227
11.1 General Expectation 227
11.2 Dual-Three-Level QZS-IMC-Based Power Drive System 229
11.3 Motor Control Strategy 236
11.4 Experimental Verifications 240
11.5 Discussion 245
11.6 Conclusion 247
References 247
Index 251
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
