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| 082 |
_a621.31 _bMohP3 |
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| 100 | _aMohan, Ned | ||
| 245 |
_aPower Electronics : _bConverters, Applications and Design [3rd ed.] / _cNed Mohan, Tore M. Undeland, William P. Robbins |
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| 250 | _a3rd ed. | ||
| 260 |
_aNew Delhi: _bWiley: _c©2022 |
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| 300 | _axvii, 697p. | ||
| 505 | 0 | 0 | _a Part 1 Introduction Chapter 1 Power Electronic Systems 1-1 Introduction 1-2 Power Electronics versus Linear Electronics 1-3 Scope and Applications 1-4 Classification of Power Processors and Converters 1-5 Interdisciplinary Nature of Power Electronics 1-6 Convention of Symbols Used 1-7 About the Text Chapter 2 Overview of Power Semiconductor Switches 2-1 Introduction 2-2 Diodes 2-3 Thyristors 2-4 Desired Characteristics in Controllable Switches 2-5 Bipolar Junction Transistors and Monolithic Darlingtons 2-6 Metal–Oxide–Semiconductor Field Effect Transistors 2-7 Gate-Turn-Off Thyristors 2-8 Insulated Gate Bipolar Transistors 2-9 MOS-Controlled Thyristors 2-10 Comparison of Controllable Switches 2-11 Drive and Snubber Circuits 2-12 Justification for Using Idealized Device Characteristics Chapter 3 Review of Basic Electrical and Magnetic Circuit Concepts 3-1 Introduction 3-2 Electrical Circuits 3-3 Magnetic Circuits Part 2 Semiconductor Devices Chapter 4 Basic Semiconductor Physics 4-1 Introduction 4-2 Conduction Processes in Semiconductors 4-3 pn Junctions 4-4 Charge Control Description of pn-Junction Operation 4-5 Avalanche Breakdown Chapter 5 Power Diodes 5-1 Introduction 5-2 Basic Structure and I–V Characteristics 5-3 Breakdown Voltage Considerations 5-4 On-State Losses 5-5 Switching Characteristics 5-6 Schottky Diodes Chapter 6 Bipolar Junction Transistors 6-1 Introduction 6-2 Vertical Power Transistor Structures 6-3 I–V Characteristics 6-4 Physics of BJT Operation 6-5 Switching Characteristics 6-6 Breakdown Voltages 6-7 Second Breakdown 6-8 On-State Losses 6-9 Safe Operating Areas Chapter 7 Power MOSFETs 7-1 Introduction 7-2 Basic Structure 7-3 I–V Characteristics 7-4 Physics of Device Operation 7-5 Switching Characteristics 7-6 Operating Limitations and Safe Operating Areas 7-7 Comparison Between Power BJT and MOSFET Chapter 8 Thyristors 8-1 Introduction 8-2 Basic Structure 8-3 I–V Characteristics 8-4 Physics of Device Operation 8-5 Switching Characteristics 8-6 Methods of Improving di/dt and dv/dt Ratings Chapter 9 Gate Turn-Off Thyristors 9-1 Introduction 9-2 Basic Structure and I–V Characteristics 9-3 Physics of Turn-Off Operation 9-4 GTO Switching Characteristics 9-5 Overcurrent Protection of GTOs Chapter 10 Insulated Gate Bipolar Transistors 10-1 Introduction 10-2 Basic Structure 10-3 I–V Characteristics 10-4 Physics of Device Operation 10-5 Latchup in IGBTs 10-6 Switching Characteristics 10-7 Device Limits and SOAs Chapter 11 Emerging Devices and Circuits 11-1 Introduction 11-2 Power Junction Field Effect Transistors 11-3 Field-Controlled Thyristor 11-4 JFET-Based Devices versus Other Power Devices 11-5 MOS-Controlled Thyristors 11-6 Power Integrated Circuits 11-7 New Semiconductor Materials for Power Devices 11-8 Wide-Bandgap Semiconductors Part 3 Power Electronic Circuits Chapter 12 Diode Rectifiers: ac → Uncontrolled dc 12-1 Introduction 12-2 Basic Rectifier Concepts 12-3 Single-Phase Diode Bridge Rectifiers 12-4 Voltage Doubler (Single-Phase) Rectifiers 12-5 Effect of Single-Phase Rectifiers on Neutral Currents in Three-Phase, Four-Wire Systems 12-6 Three-Phase, Full-Bridge Rectifiers 12-7 Comparison of Single-Phase and Three-Phase Rectifiers 12-8 Inrush Current and Overvoltages at Turn-On 12-9 Concerns and Remedies for Line-Current Harmonics and Low Power Factor Chapter 13 Phase-Controlled Rectifiers and Inverters: Line Frequency ac ↔ Controlled dc 13-1 Introduction 13-2 Thyristor Circuits and their Control 13-3 Single-Phase Converters 13-4 Three-Phase Converters 13-5 Other Three-Phase Converters Chapter 14 dc–dc Converters 14-1 Introduction 14-2 Control of dc–dc Converters 14-3 Step-Down (Buck) Converter 14-4 Step-Up (Boost) Converter 14-5 Buck–Boost Converter 14-6 Cúk dc–dc Converter 14-7 Full-Bridge dc–dc Converter 14-8 dc–dc Converter Comparison Chapter 15 dc–ac Inverters 15-1 Introduction 15-2 Basic Concepts of Switch-Mode Inverters 15-3 Single-Phase Inverters 15-4 Three-Phase Inverters 15-5 Effect of Blanking Time on Voltage in PWM Inverters 15-6 Other Inverter Switching Schemes 15-7 Rectifier Mode of Operation Chapter 16 Resonant Converters 16-1 Introduction 16-2 Classification of Resonant Converters 16-3 Basic Resonant Circuit Concepts 16-4 Load-Resonant Converters 16-5 Resonant-Switch Converters 16-6 Zero-Voltage-Switching, Clamped-Voltage Topologies 16-7 Resonant-dc-Link Inverters with Zero-Voltage Switchings 16-8 High-Frequency-Link Integral-Half-Cycle Converters Chapter 17 ac–ac Converters 17-1 Introduction 17-2 Principle of Converter Control 17-3 Single-Phase Full Wave ac Voltage Controller 17-4 Three-Phase Full Wave Voltage Controller 17-5 Cycloconverter Part 4 Power Supply Applications Chapter 18 Switching dc Power Supplies 18-1 Introduction 18-2 Linear Power Supplies 18-3 Overview of Switching Power Supplies 18-4 dc–dc Converters with Electrical Isolation 18-5 Control of Switch-Mode dc Power Supplies 18-6 Power Supply Protection 18-7 Electrical Isolation in the Feedback Loop 18-8 Designing to Meet the Power Supply Specifications Chapter 19 Power Conditioners and Uninterruptible Power Supplies 19-1 Introduction 19-2 Power Line Disturbances 19-3 Power Conditioners 19-4 Uninterruptible Power Supplies (UPSs) Part 5 Other Applications Chapter 20 Residential and Industrial Applications 20-1 Introduction 20-2 Residential Applications 20-3 Industrial Applications 20-4 Interconnection of Renewable Energy Sources to Utility 20-5 Grid-Connected Electric Vehicle Charging Stations Chapter 21 Optimizing the Utility Interface with Power Electronic Systems 21-1 Introduction 21-2 Generation of Current Harmonics 21-3 Current Harmonics and Power Factor 21-4 Harmonic Standards and Recommended Practices 21-5 Need for Improved Utility Interface 21-6 Improved Single-Phase Utility Interface 21-7 Improved Three-Phase Utility Interface 21-8 Electromagnetic Interference Part 6 Practical Converter Design Considerations Chapter 22 Snubber Circuits 22-1 Function and Types of Snubber Circuits 22-2 Diode Snubbers 22-3 Snubber Circuits for Thyristors 22-4 Need for Snubbers with Transistors 22-5 Turn-Off Snubber 22-6 Overvoltage Snubber 22-7 Turn-On Snubber 22-8 Snubbers for Bridge Circuit Configurations 22-9 GTO Snubber Considerations Chapter 23 Gate and Base Drive Circuits 23-1 Preliminary Design Considerations 23-2 dc-Coupled Drive Circuits 23-3 Electrically Isolated Drive Circuits 23-4 Cascode-Connected Drive Circuits 23-5 Thyristor Drive Circuits 23-6 Power Device Protection in Drive Circuits 23-7 Circuit Layout Considerations Chapter 24 Component Temperature Control and Heat Sinks 24-1 Control of Semiconductor Device Temperatures 24-2 Heat Transfer by Conduction 24-3 Heat Sinks 24-4 Heat Transfer by Radiation and Convection Chapter 25 Design of Magnetic Components 25-1 Magnetic Materials and Cores 25-2 Copper Windings 25-3 Thermal Considerations 25-4 Analysis of a Specific Inductor Design 25-5 Inductor Design Procedures 25-6 Analysis of a Specific Transformer Design 25-7 Eddy Currents 25-8 Transformer Leakage Inductance 25-9 Transformer Design Procedure 25-10 Comparison of Transformer and Inductor Sizes Part 7 Motor Drive Applications Chapter 26 Introduction to Motor Drives 26-1 Introduction 26-2 Criteria for Selecting Drive Components Chapter 27 dc Motor Drives 27-1 Introduction 27-2 Equivalent Circuit of dc Motors 27-3 Permanent-Magnet dc Motors 27-4 dc Motors with a Separately Excited Field Winding 27-5 Effect of Armature Current Waveform 27-6 dc Servo Drives 27-7 Adjustable-Speed dc Drives Chapter 28 Induction Motor Drives 28-1 Introduction 28-2 Basic Principles of Induction Motor Operation 28-3 Induction Motor Characteristics at Rated (Line) Frequency and Rated Voltage 28-4 Speed Control by Varying Stator Frequency and Voltage 28-5 Impact of Nonsinusoidal Excitation on Induction Motors 28-6 Variable-Frequency Converter Classifications 28-7 Variable-Frequency PWM-VSI Drives 28-8 Variable-Frequency Square-Wave VSI Drives 28-9 Variable-Frequency CSI Drives 28-10 Comparison of Variable-Frequency Drives 28-11 Line-Frequency Variable-Voltage Drives 28-12 Reduced Voltage Starting (“Soft Start”) of Induction Motors 28-13 Speed Control by Static Slip Power Recovery Chapter 29 Synchronous Motor Drives 29-1 Introduction 29-2 Basic Principles of Synchronous Motor Operation 29-3 Synchronous Servomotor Drives with Sinusoidal Waveforms 29-4 Synchronous Servomotor Drives with Trapezoidal Waveforms 29-5 Load-Commutated Inverter Drives 29-6 Cycloconverters Appendix Computer Simulation of Power Electronic Converters and Systems A A-1 Introduction A-2 Challenges in Computer Simulation A-3 Simulation Process A-4 Mechanics of Simulation [1] A-5 Solution Techniques for Time-Domain Analysis A-6 Widely Used, Circuit-Oriented Simulators A-7 Equation Solvers |
| 520 | _aPower Electronics offers cohesive and in-depth presentation of power electronics fundamentals for applications and design in an easy-to-follow step-by-step manner. A detailed coverage of practical and emerging power electronic converters based on new generation of power semiconductor devices is also included. This Indian Adaptation of the third edition of the book builds on the conceptual strength of the previous editions, reorganizes topic coverage at places and offers new content. | ||
| 650 | _aPower electronics | ||
| 650 | _aElectric Current Converters | ||
| 650 | _aPower Semiconductors | ||
| 700 | _aUndeland, Tore M. | ||
| 700 | _aRobbins, William P. | ||
| 942 | _cBK | ||
| 999 |
_c7783 _d7783 |
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