Designed to complement a range of power electronics study resources, this unique lab manual helps students to gain a deep understanding of the operation, modeling, analysis, design, and performance of pulse-width modulated (PWM) DC-DC power converters. Exercises focus on three essential areas of power electronics: open-loop power stages; small-signal modeling, design of feedback loops and PWM DC-DC converter control schemes; and semiconductor devices such as silicon, silicon carbide and gallium nitride. Meeting the standards required by industrial employers, the lab manual combines programming…mehr
Designed to complement a range of power electronics study resources, this unique lab manual helps students to gain a deep understanding of the operation, modeling, analysis, design, and performance of pulse-width modulated (PWM) DC-DC power converters. Exercises focus on three essential areas of power electronics: open-loop power stages; small-signal modeling, design of feedback loops and PWM DC-DC converter control schemes; and semiconductor devices such as silicon, silicon carbide and gallium nitride. Meeting the standards required by industrial employers, the lab manual combines programming language with a simulation tool designed for proficiency in the theoretical and practical concepts. Students and instructors can choose from an extensive list of topics involving simulations on MATLAB, SABER, or SPICE-based platforms, enabling readers to gain the most out of the prelab, inlab, and postlab activities. The laboratory exercises have been taught and continuously improved for over 25 years by Marian K. Kazimierczuk thanks to constructive student feedback and valuable suggestions on possible workroom improvements. This up-to-date and informative teaching material is now available for the benefit of a wide audience. Key features: * Includes complete designs to give students a quick overview of the converters, their characteristics, and fundamental analysis of operation. * Compatible with any programming tool (MATLAB, Mathematica, or Maple) and any circuit simulation tool (PSpice, LTSpice, Synopsys SABER, PLECS, etc.). * Quick design section enables students and instructors to verify their design methodology for instant simulations. * Presents lab exercises based on the most recent advancements in power electronics, including multiple-output power converters, modeling, current- and voltage-mode control schemes, and power semiconductor devices. * Provides comprehensive appendices to aid basic understanding of the fundamental circuits, programming and simulation tools. * Contains a quick component selection list of power MOSFETs and diodes together with their ratings, important specifications and Spice models.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Marian K. Kazimierczuk, Wright State University, Ohio, USA Marian K. Kazimierczuk is a Professor of Electrical Engineering at Wright State University's Department of Electrical Engineering. He has taught graduate courses in high-frequency electronics for 30 years and his research interests include: RF power amplifiers, power electronics, high-frequency magnetics and renewable energy sources. He has published seven books, over 160 journal papers and over 200 conference papers. Marian K. Kazimierczuk also holds seven patents, is an IEEE Fellow and serves as an Associate Editor of the IEEE Transactions on Industrial Electronics, IEEE Transactions on Circuits and Systems and International Journal of Circuit Theory and Applications. Agasthya Ayachit, Wright State University, Ohio, USA Agasthya Ayachit is a Graduate Teaching Assistant in the Department of Electrical Engineering at Wright State University working towards his PhD. In this position he has been teaching the following labs: (1) Power Electronics I (power stages of PWM converters and semiconductor power devices), (2) Power Electronics II (modelling and control of PWM converters), (3) High-Frequency Magnetic Components, and (4) Radio-Frequency Power Amplifiers. He graduated with his Masters' degree from Wright State University in 2011 after which he served as a lecturer at Pennsylvania State University for one year where he taught Micro-electronics, power electronics and VLSI courses.
Inhaltsangabe
Preface ix Acknowledgments xiii List of Symbols xv Part I Open Loop Pulse Width Modulated DC DC Converters Steady State and Performance Analysis and Simulation of Converter Topologies 1 Boost DC DC Converter in CCM Steady State Simulation 3 2 Efficiency and DC Voltage Transfer Function of PWM Boost DC DC Converter in CCM 7 3 Boost DC DC Converter in DCM Steady State Simulation 11 4 Efficiency and DC Voltage Transfer Function of PWM Boost DC DC Converter in DCM 15 5 Open Loop Boost AC DC Power Factor Corrector Steady State Simulation 19 6 Buck DC DC Converter in CCM Steady State Simulation 23 7 Efficiency and DC Voltage Transfer Function of PWM Buck DC DC Converter in CCM 27 8 Buck DC DC Converter in DCM Steady State Simulation 31 9 Efficiency and DC Voltage Transfer Function of PWM Buck DC DC Converter in DCM 35 10 High Side Gate Drive Circuit for Buck DC DC Converter 39 11 Quadratic Buck DC DC Converter in CCM Steady State Simulation 41 12 Buck Boost DC DC Converter in CCM Steady State Simulation 45 13 Efficiency and DC Voltage Transfer Function of PWM Buck Boost DC DC Converter in CCM 49 14 Buck Boost DC DC Converter in DCM Steady State Simulation 53 15 Efficiency and DC Voltage Transfer Function of PWM Buck Boost DC DC Converter in DCM 57 16 Flyback DC DC Converter in CCM Steady State Simulation 61 17 Efficiency and DC Voltage Transfer Function of PWM Flyback DC DC Converters in CCM 65 18 Multiple Output Flyback DC DC Converter in CCM 69 19 Flyback DC DC Converter in DCM Steady State Simulation 73 20 Efficiency and DC Voltage Transfer Function of PWM Flyback DC DC Converter in DCM 77 21 Forward DC DC Converter in CCM Steady State Simulation 81 22 Efficiency and DC Voltage Transfer Function of PWM Forward DC DC Converter in CCM 85 23 Forward DC DC Converter in DCM Steady State Simulation 89 24 Efficiency and DC Voltage Transfer Function of PWM Forward DC DC Converter in DCM 93 25 Half Bridge DC DC Converter in CCM Steady State Simulation 97 26 Efficiency and DC Voltage Transfer Function of PWM Half Bridge DC DC Converter in CCM 101 27 Full Bridge DC DC Converter in CCM Steady State Simulation 105 28 Efficiency and DC Voltage Transfer Function of PWM Full Bridge DC DC Converters in CCM 109 Part II Closed Loop Pulse Width Modulated DC DC Converters Transient Analysis, Small Signal Modeling, and Control 29 Design of the Pulse Width Modulator and the PWM Boost DC DC Converter in CCM 115 30 Dynamic Analysis of the Open Loop PWM Boost DC DC Converter in CCM for Step Change in the Input Voltage, Load Resistance, and Duty Cycle 119 31 Open Loop Control to Output Voltage Transfer Function of the Boost Converter in CCM 123 32 Root Locus and 3D Plot of the Control to Output Voltage Transfer Function 129 33 Open Loop Input to Output Voltage Transfer Function of the Boost Converter in CCM 133 34 Open Loop Small Signal Input and Output Impedances of the Boost Converter in CCM 137 35 Feedforward Control of the Boost DC DC Converter in CCM 141 36 P, PI, and PID Controller Design 145 37 P, PI, and PID Controllers: Bode and Transient Analysis 149 38 Transfer Functions of the Pulse Width Modulator, Boost Converter Power Stage, and Feedback Network 153 39 Closed Loop Control to Output Voltage Transfer Function with Unity Gain Control 157 40 Simulation of the Closed Loop Boost Converter with Proportional Control 161 41 Voltage Mode Control of Boost DC DC Converter with Integral Double Lead Controller 165 42 Control to Output Voltage Transfer Function of the Open Loop Buck DC DC Converter 169 43 Voltage Mode Control of Buck DC DC Converter 173 44 Feedforward Control of the Buck DC DC Converter in CCM 179 Part III Semiconductor Materials and Power Devices 45 Temperature Dependence of Si and SiC Semiconductor Materials 187 46 Dynamic Characteristics of the PN Junction Diode 191 47 Characteristics of the Silicon and Silicon Carbide PN Junction Diodes 195 48 Analysis of the Output and Switching Characteristics of Power MOSFETs 199 49 Short Channel Effects in MOSFETs 201 50 Gallium Nitride Semiconductor: Material Properties 205 Appendices 209 A Design Equations for Continuous Conduction Mode 211 B Design Equations for Discontinuous Conduction Mode 215 C Simulation Tools 219 D MOSFET Parameters 231 E Diode Parameters 233 F Selected MOSFETs Spice Models 235 G Selected Diodes Spice Models 237 H Physical Constants 239 I Format of Lab Report 241 Index 245
Preface ix Acknowledgments xiii List of Symbols xv Part I Open Loop Pulse Width Modulated DC DC Converters Steady State and Performance Analysis and Simulation of Converter Topologies 1 Boost DC DC Converter in CCM Steady State Simulation 3 2 Efficiency and DC Voltage Transfer Function of PWM Boost DC DC Converter in CCM 7 3 Boost DC DC Converter in DCM Steady State Simulation 11 4 Efficiency and DC Voltage Transfer Function of PWM Boost DC DC Converter in DCM 15 5 Open Loop Boost AC DC Power Factor Corrector Steady State Simulation 19 6 Buck DC DC Converter in CCM Steady State Simulation 23 7 Efficiency and DC Voltage Transfer Function of PWM Buck DC DC Converter in CCM 27 8 Buck DC DC Converter in DCM Steady State Simulation 31 9 Efficiency and DC Voltage Transfer Function of PWM Buck DC DC Converter in DCM 35 10 High Side Gate Drive Circuit for Buck DC DC Converter 39 11 Quadratic Buck DC DC Converter in CCM Steady State Simulation 41 12 Buck Boost DC DC Converter in CCM Steady State Simulation 45 13 Efficiency and DC Voltage Transfer Function of PWM Buck Boost DC DC Converter in CCM 49 14 Buck Boost DC DC Converter in DCM Steady State Simulation 53 15 Efficiency and DC Voltage Transfer Function of PWM Buck Boost DC DC Converter in DCM 57 16 Flyback DC DC Converter in CCM Steady State Simulation 61 17 Efficiency and DC Voltage Transfer Function of PWM Flyback DC DC Converters in CCM 65 18 Multiple Output Flyback DC DC Converter in CCM 69 19 Flyback DC DC Converter in DCM Steady State Simulation 73 20 Efficiency and DC Voltage Transfer Function of PWM Flyback DC DC Converter in DCM 77 21 Forward DC DC Converter in CCM Steady State Simulation 81 22 Efficiency and DC Voltage Transfer Function of PWM Forward DC DC Converter in CCM 85 23 Forward DC DC Converter in DCM Steady State Simulation 89 24 Efficiency and DC Voltage Transfer Function of PWM Forward DC DC Converter in DCM 93 25 Half Bridge DC DC Converter in CCM Steady State Simulation 97 26 Efficiency and DC Voltage Transfer Function of PWM Half Bridge DC DC Converter in CCM 101 27 Full Bridge DC DC Converter in CCM Steady State Simulation 105 28 Efficiency and DC Voltage Transfer Function of PWM Full Bridge DC DC Converters in CCM 109 Part II Closed Loop Pulse Width Modulated DC DC Converters Transient Analysis, Small Signal Modeling, and Control 29 Design of the Pulse Width Modulator and the PWM Boost DC DC Converter in CCM 115 30 Dynamic Analysis of the Open Loop PWM Boost DC DC Converter in CCM for Step Change in the Input Voltage, Load Resistance, and Duty Cycle 119 31 Open Loop Control to Output Voltage Transfer Function of the Boost Converter in CCM 123 32 Root Locus and 3D Plot of the Control to Output Voltage Transfer Function 129 33 Open Loop Input to Output Voltage Transfer Function of the Boost Converter in CCM 133 34 Open Loop Small Signal Input and Output Impedances of the Boost Converter in CCM 137 35 Feedforward Control of the Boost DC DC Converter in CCM 141 36 P, PI, and PID Controller Design 145 37 P, PI, and PID Controllers: Bode and Transient Analysis 149 38 Transfer Functions of the Pulse Width Modulator, Boost Converter Power Stage, and Feedback Network 153 39 Closed Loop Control to Output Voltage Transfer Function with Unity Gain Control 157 40 Simulation of the Closed Loop Boost Converter with Proportional Control 161 41 Voltage Mode Control of Boost DC DC Converter with Integral Double Lead Controller 165 42 Control to Output Voltage Transfer Function of the Open Loop Buck DC DC Converter 169 43 Voltage Mode Control of Buck DC DC Converter 173 44 Feedforward Control of the Buck DC DC Converter in CCM 179 Part III Semiconductor Materials and Power Devices 45 Temperature Dependence of Si and SiC Semiconductor Materials 187 46 Dynamic Characteristics of the PN Junction Diode 191 47 Characteristics of the Silicon and Silicon Carbide PN Junction Diodes 195 48 Analysis of the Output and Switching Characteristics of Power MOSFETs 199 49 Short Channel Effects in MOSFETs 201 50 Gallium Nitride Semiconductor: Material Properties 205 Appendices 209 A Design Equations for Continuous Conduction Mode 211 B Design Equations for Discontinuous Conduction Mode 215 C Simulation Tools 219 D MOSFET Parameters 231 E Diode Parameters 233 F Selected MOSFETs Spice Models 235 G Selected Diodes Spice Models 237 H Physical Constants 239 I Format of Lab Report 241 Index 245
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