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  <titleInfo>
    <title>Power Electronics Handbook</title>
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  <name type="personal">
    <namePart>Rashid, Muhammad H.</namePart>
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    <dateIssued encoding="marc">2024</dateIssued>
    <edition>5th ed.</edition>
    <issuance>monographic</issuance>
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    <extent>1 online resource (1472 pages)</extent>
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  <abstract>Power Electronics Handbook, Fifth Edition delivers an expert guide to power electronics and their applications.The book examines the foundations of power electronics, power semiconductor devices, and power converters, before reviewing a constellation of modern applications.</abstract>
  <tableOfContents>Intro -- Power Electronics Handbook -- Copyright -- Contents -- Contributors -- Preface for Fifth Edition -- Introduction -- Power electronics backgrounds -- Organization -- Changes in the fifth edition -- Locating your topic -- Audience -- Acknowledgments -- Chapter 1: Introduction -- 1.1. Power Electronics Defineda -- 1.2. Key Characteristics -- 1.2.1. The Efficiency Objective: The Switch -- 1.2.2. The Reliability Objective: Simplicity and Integration -- 1.3. Trends in Power Supplies -- 1.4. Conversion Examples -- 1.4.1. Single-Switch Circuits -- 1.4.2. The Method of Energy Balance -- 1.5. Tools for Analysis and Design -- 1.5.1. The Switch Matrix -- 1.5.2. Implications of Kirchhoff�s Voltage and Current Laws -- 1.5.3. Resolving the Hardware Problem: Semiconductor Devices -- 1.5.4. Resolving the Software Problem: Switching Functions -- 1.5.5. Resolving the Interface Problem: Lossless Filter Design -- 1.6. Sample Applications -- 1.7. Summary -- References -- Section A: Power Electronic Devices -- Chapter 2: Semiconductor Diodes and Transistors -- 2.1. Background in Semiconductor Physics -- 2.2. Semiconductor Diode -- 2.2.1. Static Characteristics -- 2.2.2. Dynamic Characteristics -- 2.2.3. Common Types of Diodes -- 2.2.4. Evaluating the Dynamic Characteristics of Real Diodes -- 2.2.5. Series and Parallel Connection of Power Diodes -- 2.2.6. Typical Application of Diodes -- 2.2.6.1. Rectifiers -- 2.2.6.2. Freewheeling -- 2.2.6.3. Voltage Multiplier -- 2.2.7. PSPICE Model -- 2.3. Power Bipolar Transistor -- 2.3.1. Basic Structure and Operation -- 2.3.2. Static Characteristics -- 2.3.3. Safe Operation Area (SOA) -- 2.3.4. Switching Characteristics -- 2.3.5. Transistor Base Driver Circuits -- 2.3.6. BJT Applications -- 2.3.7. PSPICE Model -- 2.4. Power MOSFET -- 2.4.1. Basic Structure -- 2.4.2. Static Characteristics -- 2.4.2.1. Ohmic Region.</tableOfContents>
  <tableOfContents>2.4.2.2. Cutoff Region -- 2.4.2.3. Active Region -- 2.4.3. Switching Characteristics -- 2.4.3.1. Turn-On Analysis -- 2.4.3.2. Turn-Off Analysis -- 2.4.4. Safe Operation Area -- 2.4.5. MOSFET Applications -- 2.4.6. PSPICE Model -- 2.5. Insulated Gate Bipolar Transistor (IGBT) -- 2.5.1. Basic Structure -- 2.5.2. Static Characteristics -- 2.5.3. Switching Characteristics -- 2.5.3.1. Turn-On Analysis -- 2.5.3.2. Turn-Off Analysis -- 2.5.4. IGBT Applications -- 2.5.5. PSPICE Model -- 2.6. Switching Evaluation of a Real MOSFET -- 2.6.1. Results for Sw1 ON and Sw2 OFF and Rpot at the Maximum Resistance -- 2.6.2. Results for Sw1 ON and Sw2 OFF and Rpot at the Maximum Resistance -- 2.6.3. Results for Sw1 and Sw2 ON and Rpot at the Maximum Resistance -- 2.6.4. Results for Sw1 and Sw2 OFF and Rpot at the Maximum Resistance -- 2.7. Heatsink Thermal Design for Power Semiconductors -- 2.7.1. Heatsink Design -- 2.8. Transistor Selection Criteria -- References -- Further Reading -- Chapter 3: Thyristors -- 3.1. Introduction -- 3.2. Basic Structure and Operation -- 3.3. Static Characteristics -- 3.3.1. Current-Voltage Curves for Thyristors -- 3.3.2. Edge and Surface Terminations -- 3.3.3. Packaging -- 3.4. Dynamic Switching Characteristics -- 3.4.1. Cathode Shorts -- 3.4.2. Anode Shorts -- 3.4.3. Amplifying Gate -- 3.4.4. Temperature Dependencies -- 3.5. Thyristor Parameters -- 3.6. Types of Thyristors -- 3.6.1. SCRs and GTOs -- 3.6.1.1. On-State Characteristics -- 3.6.1.2. Off-State Characteristics -- 3.6.1.3. Rate of Rise of Off-State Voltage (dvD/dt) -- 3.6.1.4. Gate Triggering Characteristics -- 3.6.1.5. GTO Switching Phases -- Turn-On -- On-State -- Turn-off -- Off-State Period -- 3.6.1.6. GTO SPICModel -- 3.6.2. MOS-Controlled Thyristors -- 3.6.2.1. Equivalent Circuit and Switching Characteristics -- 3.6.2.2. Turn-On and Turn-Off.</tableOfContents>
  <tableOfContents>3.6.2.3. Comparison of MCT and Other Power Devices -- 3.6.2.4. Protection of MCTs -- Paralleling of MCTs -- Overcurrent Protection -- Snubbers -- Simulation Model of an MCT -- 3.6.3. MOS Turn-Off Thyristor [25] -- 3.6.4. Optically Triggered Thyristors -- 3.6.5. Bi-directional Controlled Thyristors -- 3.7. Gate Drive Requirements -- 3.7.1. Snubber Circuits -- 3.7.2. Gate Circuits -- 3.8. Applications -- 3.8.1. DC-AC Utility Inverters -- 3.8.2. Motor Control -- 3.8.3. VAR Compensators and Static Switching Systems -- 3.8.4. Lighting Control Circuits -- References -- Chapter 4: SiC and GaN Power Semiconductor Devices -- 4.1. Background -- 4.2. Silicon Carbide and Gallium Nitride Materials -- 4.2.1. Silicon Carbide Polytypes -- 4.2.2. Gallium Nitride Crystal Structures -- 4.2.2.1. Silicon Carbide and Gallium Nitride Physical and Electrical Properties -- 4.2.2.2. Critical Electric Field -- 4.2.2.3. Intrinsic Carrier Concentration -- 4.2.2.4. Saturated Drift Velocity -- 4.2.2.5. Thermal Stability -- 4.2.2.6. Coefficient of Thermal Expansion -- 4.2.2.7. Figure of Merit -- FOM for Materials and Technology -- FOM for Devices -- 4.3. SiC Power Devices -- 4.3.1. Introduction -- 4.3.2. SiC Power Diodes -- 4.3.2.1. SiC Schottky Diode -- 4.3.2.2. SiC PiN Diode -- 4.3.2.3. SiC Junction Barrier Schottky Diode -- 4.3.3. SiC MOSFET -- 4.3.4. SiC JFET -- 4.3.5. SiC BJT -- 4.3.6. SiC IGBT -- 4.3.7. SiC Thyristor -- 4.4. GaN Power Devices -- 4.4.1. Lateral GaN Schottky Barrier Diodes -- 4.4.2. Vertical GaN PiN Diodes -- 4.4.3. GaN JFET -- 4.4.3.1. Vertical JFET -- 4.4.3.2. Lateral Channel JFET With Vertical Drift Region -- 4.4.4. GaN MOSFET -- 4.4.4.1. Vertical Trench MOSFET -- 4.4.4.2. Lateral MOSFET -- 4.4.5. GaN HEMT -- 4.4.5.1. GaN HEMT Structure -- 4.4.5.2. GaN HEMT DC Characteristics -- 4.4.5.3. GaN HEMT Design Considerations -- 4.4.5.4. GaN Device Trends.</tableOfContents>
  <tableOfContents>Appendix: Lightly Doped Drift Region Thickness -- References -- Chapter 5: Power Electronic Modules -- 5.1. Introduction -- 5.2. Discrete Power Devices Versus Power Modules -- 5.3. An Example of a Power Module -- 5.4. Manufacturing Process -- 5.4.1. Semiconductor Chips -- 5.4.2. Die Attach -- 5.4.3. Wire Bonds -- 5.4.4. Direct Bonded Copper (DBC) Substrate -- 5.4.5. Baseplate -- 5.5. Types of Power Electronic Modules -- 5.5.1. A Survey of Power Electronic Module Topologies -- 5.5.2. Power Semiconductor Devices Used in Power Electronic Modules -- 5.5.2.1. Power Diode -- 5.5.2.2. Power MOSFET -- 5.5.2.3. Power IGBT -- 5.5.2.4. Power Thyristor -- 5.5.2.5. Power BJT -- 5.6. Thermal Management of Power Modules -- 5.6.1. The Purpose of Thermal Management -- 5.6.2. Equivalent Thermal Network of Power Module -- 5.6.3. Cooling Solutions for Power Module -- 5.6.3.1. Air Cooling -- 5.6.3.2. Liquid Cooling -- 5.6.3.3. Double-Sided Cooling -- 5.6.3.4. Double-Sided Cooling Using the DBC Structure -- 5.6.3.5. Double-Sided Cooling Using the Press-Pack Structure -- 5.7. Reliability of Power Modules -- 5.7.1. Reliability Tests [17] -- 5.8. Design Guidelines and Considerations -- 5.8.1. Bypass Capacitor Considerations -- 5.8.2. Gate Driver Design Considerations -- 5.8.3. Gate Kelvin Contacts -- 5.8.4. Other Design Considerations -- 5.9. Recent Trends in Power Electronics Modules -- 5.9.1. SiC Devices -- 5.9.2. GaN Devices -- 5.9.3. Advanced Packaging Trends -- 5.9.4. Advanced Thermal Management Options for Power Electronics Modules -- 5.10. Summary -- References -- Section B: Power Electronics Converters -- Chapter 6: Diode Rectifiers -- 6.1. Introduction -- 6.2. Single-Phase Diode Rectifiers -- 6.2.1. Single-Phase Half-Wave Diode Rectifier -- 6.2.2. Single-Phase Full-Wave Diode Rectifier -- 6.2.3. Single-Phase Full-Wave Diode Bridge Rectifier.</tableOfContents>
  <tableOfContents>6.3. Performance Parameters -- 6.3.1. Voltage Relationships -- 6.3.2. Current Relationships -- 6.3.3. Power Relationships -- 6.3.4. Ripple Factor -- 6.3.5. Rectification Ratio -- 6.3.6. Transformer Power Factor -- 6.3.7. Fourier Analysis -- 6.3.8. Design Considerations -- 6.4. Three-Phase Diode Rectifiers -- 6.4.1. Three-Phase Half-Wave Diode Rectifier -- 6.4.2. Three-Phase Full-Wave Diode Bridge Rectifier -- 6.5. Six-Phase Diode Rectifiers -- 6.5.1. Six-Phase Half-Wave Diode Rectifier -- 6.5.2. Six-Phase Full-Wave Series Diode Bridge Rectifier -- 6.6. Passive Filters in Diode Rectifier Circuits -- 6.6.1. Inductive Filter Connected to the Rectifier DC-Side -- 6.6.2. Capacitive Filter Connected to the Rectifier DC-Side -- 6.6.3. LC Filter Connected to the Rectifier DC-Side -- 6.7. Diode Rectifier Commutation Overlap -- 6.8. Off-Shore Wind Power Plant Connected to Diode-Based HVDC Link -- 6.8.1. Diode-Based HVDC Link Description -- 6.8.2. System Ratings, Nomenclature, dq Domain, and Per Unit Representation -- 6.8.3. System Simulation -- 6.8.4. Diode Rectifier Unit Components -- 6.8.4.1. AC Filters -- 6.8.4.2. Transformers -- 6.8.4.3. HVDC Diode Bridge Rectifier -- 6.8.4.4. DC Filters -- 6.8.5. HVDC Diode Rectifier Model -- 6.8.6. Diode-Based HVDC Link Operation in Steady State -- 6.8.7. Small-Signal Stability Analysis of Diode-Based HVDC Link -- 6.8.7.1. State-Space Variables and Equations -- 6.8.7.2. Model Validation and Small-Signal Stability Analysis -- 6.9. High-Frequency Diode Rectifiers -- 6.9.1. Forward Converter -- 6.9.2. Diodes Design -- Appendix A. HVDC System Parameters -- Appendix B. DRU AC-Filter Banks -- References -- Chapter 7: Single-Phase Controlled Rectifiers -- 7.1. Introduction -- 7.2. Performance Factors -- 7.2.1. Summary of Section 7.2 -- 7.3. Line-Commutated Single-Phase Controlled Rectifiers.</tableOfContents>
  <tableOfContents>7.3.1. Single-Phase Half-Wave Rectifier.</tableOfContents>
  <subject authority="lcsh">
    <topic>Power electronics</topic>
  </subject>
  <classification authority="lcc">TK7881.15 .P694 2024</classification>
  <classification authority="ddc">621.31/7</classification>
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