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Informationen zum Autor D. GRAHAME HOLMES is a professor in the Department of Electrical and Computer Systems Engineering at Monash University, Australia. THOMAS A. LIPO is a professor in the Department of Electrical and Computer Engineering at the University of Wisconsin-Madison. Klappentext * The first single volume resource for researchers in the field who previously had to depend on separate papers and conference records to attain a working knowledge of the subject.* Brings together the field's diverse approaches into an integrated and comprehensive theory of PWM Zusammenfassung The design of inverters employing Pulse Width Modulation (PWM) to vary the voltage and amplitude of power electronic inverters has evolved over the past forty years. This is the first comprehensive textbook to view the subject as a whole and to clarify and unify the many diverse approaches taken by researchers. Inhaltsverzeichnis Preface. Acknowledgments. Nomenclature. Chapter 1: Introduction to Power Electronic Converters. 1.1 Basic Converter Topologies. 1.2 Voltage Source/Stiff Inverters. 1.3 Switching Function Representation of Three-Phase Converters. 1.4 Output Voltage Control. 1.5 Current Source/Stiff Inverters. 1.6 Concept of a Space Vector. 1.7 Three-Level Inverters. 1.8 Multilevel Inverter Topologies. 1.9 Summary. Chapter 2: Harmonic Distortion. 2.1 Harmonic Voltage Distortion Factor. 2.2 Harmonic Current Distortion Factor. 2.3 Harmonic Distortion Factors for Three-Phase Inverters. 2.4 Choice of Performance Indicator. 2.5 WTHD of Three-Level Inverter. 2.6 The Induction Motor Load. 2.7 Harmonic Distortion Weighting Factors for Induction Motor Load. 2.8 Example Calculation of Harmonic Losses. 2.9 WTHD Normalization for PWM Inverter Supply. 2.10 Summary. Chapter 3: Modulation of One Inverter Phase Leg. 3.1 Fundamental Concepts of PWM. 3.2 Evaluation of PWM Schemes. 3.3 Double Fourier Integral Analysis of a Two-Level Pulse Width-Modulated Waveform. 3.4 Naturally Sampled Pulse Width Modulation. 3.5 PWM Analysis by Duty Cycle Variation. 3.6 Regular Sampled Pulse Width Modulation. 3.7 "Direct" Modulation. 3.8 Integer versus Non-Integer Frequency Ratios. 3.9 Review of PWM Variations. 3.10 Summary. Chapter 4: Modulation of Single-Phase Voltage Source Inverters. 4.1 Topology of a Single-Phase Inverter. 4.2 Three-Level Modulation of a Single-Phase Inverter. 4.3 Analytic Calculation of Harmonic Losses. 4.4 Sideband Modulation. 4.5 Switched Pulse Position. 4.6 Switched Pulse Sequence. 4.7 Summary. Chapter 5: Modulation of Three-Phase Voltage Source Inverters. 5.1 Topology of a Three-Phase Inverter (VSI). 5.2 Three-Phase Modulation with Sinusoidal References. 5.3 Third-Harmonic Reference Injection. 5.4 Analytic Calculation of Harmonic Losses. 5.5 Discontinuous Modulation Strategies. 5.6 Triplen Carrier Ratios and Subharmonics. 5.7 Summary. Chapter 6: Zero Space Vector Placement Modulation Strategies. 6.1 Space Vector Modulation. 6.1.1 Principles of Space Vector Modulation. 6.1.2 SVM Compared to Regular Sampled PWM. 6.2 Phase Leg References for Space Vector Modulation. 6.3 Naturally Sampled SVM. 6.4 Analytical Solution for SVM. 6.5 Harmonic Losses for SVM. 6.6 Placement of the Zero Space Vector. 6.7 Discontinuous Modulation. 6.8 Phase Leg References for Discontinuous PWM. 6.9 Analytical Solutions for Discontinuous PWM. 6.10 Comparison of Harmonic Performance. 6.11 Harmonic Losses for Discontinuous PWM.
List of contents
Forward.
Nomenclature.
Chapter 1. Introduction to Power Electronic Converters.
Chapter 2. Harmonic Distortion.
Chapter 3. Modulation of One Phase Leg.
Chapter 4. Modulation of Single Phase Voltage Source Inverters.
Chapter 5. Modulation of Three Phase Voltage Source Inverters.
Chapter 6. Zero Space Vector Placement Modulation Strategies.
Chapter 7. Modulation of Current Source Inverters.
Chapter 8. Overmodulation.
Chapter 9. Programmed Pulse Width Modulation.
Chapter 10. Programmed PWM for Multilevel Converters.
Chapter 11. Carrier Based PWM of Multilevel Inverters.
Chapter 12. Space Vector PWM for Multilevel Converters.
Chapter 13. Implementation Requirements for a Modulation Controller.
Chapter 14. Continuing Developments in Modulation.
Appendix 1. Fourier Series Representation of a Double Variable Controlled Waveform.
Appendix 2. Jacobi-Anger and Bessel Function Relationships.
Appendix 3. Three Phase and Half Cycle Symmetry Relationships.
Appendix 4. Overmodulation of a Single Phase Leg.
Appendix 5. Numeric Integration of a Double Fourier Series Representation of a Switched Waveform.
Bibliography.
