Synopses & Reviews
Since its publication in 1989, each edition has strived to present a cohesive presentation of power electronics fundamentals for applications and design in the power range where there is demand in industry for power electronic engineers. A CD-ROM has been added to this edition, which readers will find useful in the exploration of power electronics and use of this text. The CD-ROM contains:
* A large number of new end-of-chapter problems with varying degrees of difficulty.
* PSpice(r) -based simulation examples to illustrate basic concepts and help in the design of converters. PSpice(r) is an ideal simulation tool for this purpose.
* A newly developed magnetic component design program. This program is extremely useful in showing design trade-offs, for example, the influence of switching frequency on the size of inductors and transformers.
* PowerPoint-based slides for all chapters that help summarize topics throughout the text.
The text also explores industrial and commercial applications, as well as practical aspects of power electronic converter design, such as snubber circuits, drive circuits, circuit layout, and heat sinks. Please visit http://www.wiley.com/college/mohan for additional information.
Offering step-by-step, in-depth coverage, the new Third Edition of Power Electronics: Converters, Applications, and Design provides a cohesive presentation of power electronics fundamentals for applications and design in the power range of 500 kW or less. The text describes a variety of practical and emerging power electronic converters made feasible by the new generation of power semiconductor devices. The new edition is now enhanced with a new CD-ROM, complete with PSpice-based examples, a new magnetics design program, and PowerPoint slides.
About the Author
Ned Mohan is the Oscar A. Schott Professor of Power Electronics at the University of Minnesota, He has numerous patents and publications in this field. He is a Fellow of the IEEE.
Tore M. Undeland is a professor in Power Electronics in the Faculty of Information Technology, Mathematics and Electrical Engineering at the Norwegian University of Science and Technology, NTNU, Trondheim, Norway. He is also a scientific advisor to the SINTEF Energy Research.
William P. Robbins is a professor in the Department of Electrical and Computer Engineering at the University of Minnesota. Prior to joining the University of Minnesota, he was a research engineer at the Boeing Company.
Table of Contents
PART 1. INTRODUCTION.
Chapter 1. Power Electronic Systems.
Chapter 2. Overview of Power Semiconductor Switches.
Chapter 3. Review of Basic Electrical and Magnetic Circuit Concepts.
Chapter 4. Computer Simulation of Power Electronic Converters and Systems.
PART 2. GENERIC POWER ELECTRONIC CIRCUITS.
Chapter 5. Line-Frequency Diode Rectifiers: Line-Frequency ac Uncontrolled dc.
Chapter 6. Line-Frequency Phase-Controlled Rectifiers and Inverters: Line-Frequency ac Controlled dc.
Chapter 7. dc-dc Switch-Mode Converters.
Chapter 8. Switch-Mode dc-ac Inverters: dc Sinusoidal ac.
Chapter 9. Resonant Converters: Zero-Voltage and/or Zero-Current Switchings.
PART 3. POWER SUPPLY APPLICATIONS.
Chapter 10. Switching dc Power Supplies.
Chapter 11. Power Conditioners and Uninterruptible Power Supplies.
PART 4. MOTOR DRIVE APPLICATIONS.
Chapter 12. Introduction to Motor Drives.
Chapter 13. dc Motor Drives.
Chapter 14. Induction Motor Drives.
Chapter 15. Synchronous Motor Drives.
PART 5. OTHER APPLICATIONS.
Chapter 16. Residential and Industrial Applications.
Chapter 17. Electric Utility Applications.
Chapter 18. Optimizing the Utility Interface with Power Electronic Systems.
PART 6. SEMICONDUCTOR DEVICES.
Chapter 19. Basic Semiconductor Physics.
Chapter 20. Power Diodes.
Chapter 21. Bipolar Junction Transistors.
Chapter 22. Power MOSFETs.
Chapter 23. Thyristors.
Chapter 24. Gate Turn-Off Thyristors.
Chapter 25. Insulated Gate Bipolar Transistors.
Chapter 26. Emerging Devices and Circuits.
PART 7. PRACTICAL CONVERTER DESIGN CONSIDERATIONS.
Chapter 27. Snubber Circuits.
Chapter 28. Gate and Base Drive Circuits.
Chapter 29. Component Temperature Control and Heat Sinks.
Chapter 30. Design of Magnetic Components.