Description
Book SynopsisBrings the knowledge of 24 experts in this maturing field out from the narrow confines of academic circles, and makes it accessible to graduate students and power electronics professionals alike. aeo Provides practicing engineers with the knowledge to predict power requirement behavior.
Table of ContentsPreface.
Acknowledgments.
List of Contributing Authors.
CHAPTER 1: INTRODUCTION (D. C. Hamill, S. Banerjee, and G. C. Verghese).
1.1 Introduction to Power Electronics.
1.2 An Example: The Buck DC/DC Converter 5
1.3 Study of Nonlinear Dynamics and Chaos in Power Electronics 15
1.4 Conclusions 20
CHAPTER 2: DYNAMIC MODELS OF POWER CONVERTERS.
2.1 Introduction to Power Electronic Converters and Models (G. C. Verghese and A. M. Stankovic).
2.2 A Closer Look at Sampled-Data Models for Power Converters (F. Vasca, M. di Bernardo, and G. Olivar).
CHAPTER 3: BASICS OF BIFURCATION AND CHAOS THEORY.
3.1 Introduction to Nonlinear Dynamics and Chaos (S. Banerjee).
3.2 Bifurcations of Smooth Maps J. H. B. Deane).
3.3 Bifurcations in Piecewise-Smooth Maps (S. Banerjee and C. Grebogi).
3.4 Nonstandard Bifurcations in Discontinuous Maps (/. Dobson and S. Banerjee).
3.5 The Method of Schwarzian Derivatives (C. K. Tse).
3.6 Coexisting Attractors, Basins of Attraction, and Crises (E. Fossas and G. Olivar).
CHAPTER 4: EXPERIMENTAL AND COMPUTATIONAL TECHNIQUES FOR INVESTIGATION OF NONLINEAR PHENOMENA.
4.1 Techniques of Experimental Investigation (C K. Tse).
4.2 Techniques of Numerical Investigation (S. Banerjee and D. C. Hamill).
4.3 Computation of Averages Under Chaos (J. L Rodriguez Marrero, G. C. Verghese, R. Santos Bueno, and S. H. Isabelle).
4.4 Calculation of Spectral Peaks in a Chaotic DC/DC Converter (J. H. B. Deane).
4.5 Computer Methods to Analyze Stability and Bifurcation Phenomena (Y. Kuroe).
4.6 Computation of Operating-Mode Boundaries (Y. Kuroe, T. Kato, and G. C. Verghese).
CHAPTER 5: NONLINEAR PHENOMENA IN DC/DC CONVERTERS.
5.1 Border Collision Bifurcations in the Current-Mode-Controlled Boost Converter (S. Banerjee and P. Ranjan).
5.2 Bifurcation and Chaos in the Voltage-Controlled Buck Converter with Latch (S. Banerjee, D. Kastha, and S. Das).
5.3 Routes to Chaos in the Voltage-Controlled Buck Converter without Latch (M. di Bernardo, G. Olivar, and F. Vasca).
5.4 Saddle-Node and Neimark Bifurcations in PWM DC/DC Converters (C. C. Fang and E. H. Abed).
5.5 Nonlinear Analysis of Operation in Discontinuous-Conduction Mode (C. K. Tse).
5.6 Nonlinear Phenomena in the Cuk Converter (C. K. Tse).
CHAPTER 6: NONLINEAR DYNAMICS IN THYRISTOR AND DIODE CIRCUITS (/. Dobson).
6.1 Introduction.
6.2 Ideal Diode and Thyristor Switching Rules.
6.3 Static VAR System Example.
6.4 Poincare Map.
6.5 Jacobian of Poincare Map.
6.6 Switching Damping.
6.7 Switching Time Bifurcations.
6.8 Diode Circuits.
6.9 Firing Angle Control.
CHAPTER 7: NONLINEAR PHENOMENA IN OTHER POWER ELECTRONIC SYSTEMS.
7.1 Modeling a Nonlinear Inductor Circuit (J. H. B. Deane).
7.2 Inverters Under Tolerance Band Control (A. Magauer).
7.3 Nonlinear Noise Effects in Power Converters (P. T. Krein and P. Midya).
7.4 Nonlinear Phenomena in the Current Control of Induction Motors (/. Nagy and Z. Suto).
7.5 Analysis of Stability and Bifurcation in Power Electronic Induction Motor Drive Systems (Y. Kuroe).
CHAPTER 8: NONLINEAR CONTROL AND CONTROL OF CHAOS.
8.1 Conventional Nonlinear Controls in Power Electronics (P. T. Krein).
8.2 Sliding Mode and Switching Surface Control (P. T. Krein).
8.3 Energy-Based Control in Power Electronics (A. M. Stankovic, G. Escobar, Ft. Ortega, and S. R. Sanders).
8.4 Ripple Correlation Control (P. T. Krein).
8.5 Control of Chaos (M. di Bernardo, G. Olivar, and C. Battle).
8.6 Closed-Loop Regulation of Chaotic Operation (J. L Rodriguez Marrero, R. Santos Bueno, and G. C. Verghese).
8.7 Control of Bifurcation (C. K. Tse and Y.-M. Lai).
8.8 Synchronization of Chaos (C. K. Tse).
Index.
About the Editors.
