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CONTENTS

CONTENTS. Principles and Methods of Electric Power Conversion Semiconductor Power Switches Supplementary Components and Systems AC-to-DC Converters AC-to-AC Converters DC-to-DC Converters DC-to-AC Converters Switching Power Supplies Power Electronics and Clean Energy.

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CONTENTS

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  1. CONTENTS • Principles and Methods of Electric Power Conversion • Semiconductor Power Switches • Supplementary Components and Systems • AC-to-DC Converters • AC-to-AC Converters • DC-to-DC Converters • DC-to-AC Converters • Switching Power Supplies • Power Electronics and Clean Energy Chapter 1

  2. Chapter 1Principles and Methods of Electric Power Conversion “Introduction to Modern Power Electronics”, 2nd Ed., John Wiley 2010 by Andrzej M. Trzynadlowski

  3. Types of electric power conversion Fig. 1.1 Chapter 1

  4. Generic power converter Fig. 1.2 Chapter 1

  5. AC input voltage waveform Fig. 1.3 Chapter 1

  6. Output voltage and current waveforms in the generic rectifier Fig. 1.4 Chapter 1

  7. Output voltage and current waveforms in the generic inverter Fig. 1.5 Chapter 1

  8. Configurations of power electronic converters: (a) current-source, (b) voltage-source Fig. 1.6 Chapter 1

  9. Decomposition of the output voltage waveform in the generic rectifier Fig. 1.7 Chapter 1

  10. Decomposition of the output current waveform in the generic rectifier Fig. 1.8 Chapter 1

  11. Decomposition of the output voltage waveform in the generic inverter Fig.1.9 Chapter 1

  12. Decomposition of the output current waveform in the generic inverter Fig. 1.10 Chapter 1

  13. Input current waveform and Its fundamental component in the generic inverter Fig. 1.11 Chapter 1

  14. Resistive control schemes: (a) rheostatic control, (b) potentiometric control Fig. 1.12 Chapter 1

  15. Output voltage and current waveforms in the generic rectifier with the firing angle of Fig. 1.13 Chapter 1

  16. Control characteristic of the phase-controlled generic rectifier Fig. 1.14 Chapter 1

  17. Output voltage and current waveforms in the generic AC voltage controller with the firing angle of Fig. 1.15 Chapter 1

  18. Control characteristic of the phase-controlled generic AC voltage controller Fig. 1.16 Chapter 1

  19. Harmonic spectra of output voltage with the firing angle of in: (a) phase-controlled generic rectifier, (b) phase-controlled generic AC voltage controller Fig. 1.17 Chapter 1

  20. Output voltage and current waveforms in the generic chopper Fig. 1.18 Chapter 1

  21. Output voltage and current waveforms in the generic chopper: switching frequency twice as high as in the previous figure Fig. 1.19 Chapter 1

  22. Output voltage and current waveforms in (a) generic PWM rectifier, (b) generic PWM ac voltage controller Fig. 1.20 Chapter 1

  23. Control characteristics of (a) generic PWM rectifier, (b) generic PWM ac voltage controller Fig. 1.21 Chapter 1

  24. Harmonic spectra of output voltage in (a) generic PWM rectifier, (b) generic PWM ac voltage controller (N = 24) Fig. 1.22 Chapter 1

  25. Output voltage and current waveforms in the generic PWM inverter (a) M = 1, (b) M = 0.5 Fig. 1.23 Chapter 1

  26. RL load circuit Fig. 1.24 Chapter 1

  27. Fragments of output voltage and current waveforms in a generic PWM ac voltage controller Fig. 1.25 Chapter 1

  28. Single-pulse diode rectifier Fig. 1.26 Chapter 1

  29. Output voltage and current waveforms in the single-pulse diode rectifier with an R load Fig. 1.27 Chapter 1

  30. Output voltage and current waveforms in the single-pulse diode rectifier with an RL load Fig. 1.28 Chapter 1

  31. Single-pulse diode rectifier with a free-wheeling diode Fig. 1.29 Chapter 1

  32. Output voltage and current waveforms in the single-pulse diode rectifier with a freewheeling diode and an RL load Fig. 1.30 Chapter 1

  33. Single-pulse diode rectifier with an output capacitor Fig. 1.31 Chapter 1

  34. Output voltage and current waveforms in the single-pulse diode rectifier with an output capacitor and an RL load Fig. 1.32 Chapter 1

  35. Two-pulse diode rectifier Fig. 1.33 Chapter 1

  36. Output voltage waveform in the generic cycloconverter in Example 1.1 Fig. 1.34 Chapter 1

  37. Timing diagram of switches in the generic cycloconverter in Example 1.1 Fig. 1.35 Chapter 1

  38. Voltage ripple factor versus firing angle in the generic rectifier in Example 1.3 Fig. 1.36 Chapter 1

  39. Output voltage and current waveforms in the generic PWM rectifier in Example 1.5 Fig. 1.37 Chapter 1

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