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Power electronic converters : dynamics and control in conventional and renewable energy applictions

✍ Scribed by Messo, Tuomas; Puukko, Joonas; Suntio, Teuvo

Year
2018
Tongue
English
Leaves
707
Category
Library
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✦ Synopsis

Title Page -- Copyright -- Preface -- About the Authors -- Part One: Introduction -- Chapter 1: Introduction -- 1.1 Introduction -- 1.2 Implementation of Current-Fed Converters -- 1.3 Dynamic Modeling of Power Electronic Converters -- 1.4 Linear Equivalent Circuits -- 1.5 Impedance-Based Stability Assessment -- 1.6 Time Domain-Based Dynamic Analysis -- 1.7 Renewable Energy System Principles -- 1.8 Content Review --

6.4 Remote Sensing -- 6.5 Simple Control Design Method -- 6.6 PCM-Controlled Superbuck Converter: Experimental Examples -- 6.7 Concluding Remarks -- References -- Part Three: Current-Fed Converters -- Chapter 7: Introduction to Current-Fed Converters -- 7.1 Introduction -- 7.2 Duality Transformation Basics -- 7.3 Duality-Transformed Converters -- 7.4 Input Capacitor-Based Converters -- References -- Chapter 8: Dynamic Modeling of DDR-Controlled CF Converters -- 8.1 Introduction -- 8.2 Dynamic Models -- 8.3 Source and Load Interactions -- 8.4 Impedance-Based Stability Assessment -- 8.5 Output-Voltage Feedforward -- 8.6 Dynamic Review -- References -- Chapter 9: Dynamic Modeling of PCM/PVM-Controlled CF Converters -- 9.1 Introduction -- 9.2 Duty-Ratio Constraints and Dynamic Models under PCM Control -- 9.3 Duty-Ratio Constraints and Dynamic Models under PVM Control -- 9.4 Concluding Remarks -- References -- Chapter 10: Introduction to Photovoltaic Generator -- 10.1 Introduction -- 10.2 Solar Cell Properties -- 10.3 PV Generator -- 10.4 MPP Tracking Methods -- 10.5 MPP Tracking Design Issues -- 10.6 Concluding Remarks -- References -- Chapter 11: Photovoltaic Generator Interfacing Issues -- 11.1 Introduction -- 11.2 Centralized PV System Architecture -- 11.3 Distributed PV System Architectures -- 11.4 PV Generator-Induced Effects on Interfacing-Converter Dynamics -- 11.5 Stability Issues in PV Generator Interfacing -- 11.6 Control Design Issues -- References -- Part Four: Three-Phase Grid-Connected Converters -- Chapter 12: Dynamic Modeling of Three-Phase Inverters -- 12.1 Introduction -- 12.2 Dynamic Model of Voltage-Fed Inverter -- 12.3 Dynamic Model of Current-Fed Inverter -- 12.4 Source-Affected Dynamics of Current-Fed Inverter -- 12.5 Dynamic Model of Current-Fed Inverter with LCL-Filter -- 12.6 Summary -- Appendix 12.A -- References.

Chapter 13: Control Design of Grid-Connected Three-Phase Inverters -- 13.1 Introduction -- 13.2 Synchronous Reference Frame Phase-Locked-Loop -- 13.3 AC Current Control -- 13.4 Decoupling Gains -- 13.5 Grid Voltage Feedforward -- 13.6 Cascaded Control Scheme in Current-Fed Inverters -- 13.7 Case Study: Instability Due to RHP-Pole -- 13.8 Summary -- References -- Chapter 14: Reduced-Order Closed-Loop Modeling of Inverters -- 14.1 Introduction -- 14.2 Reduced-Order Model of Voltage-Fed Inverter -- 14.3 Reduced-Order Model of Current-Fed Inverter with L-Type Filter -- 14.4 Closed-Loop Model of Current-Fed Inverter with LC-Type Filter -- 14.5 Summary -- References -- Chapter 15: Multivariable Closed-Loop Modeling of Inverters -- 15.1 Introduction -- 15.2 Full-Order Model of Current-Fed Inverter with L-Type Filter -- 15.3 Experimental Verification of Admittance Model -- 15.4 Full-Order Model of Current-Fed Inverter with LCL-Type Filter -- 15.5 Summary -- References -- Chapter 16: Impedance-Based Stability Assessment -- 16.1 Introduction -- 16.2 Modeling of Three-Phase Load Impedance in the dq-Domain -- 16.3 Impedance-Based Stability Criterion -- 16.4 Case Studies -- 16.5 Summary -- References -- Chapter 17: Dynamic Modeling of Three-Phase Active Rectifiers -- 17.1 Introduction -- 17.2 Open-Loop Dynamics -- 17.3 Verification of Open-Loop Model -- 17.4 Experimental Results -- 17.5 Summary -- References -- Index -- End User License Agreement. οΏ½Read more...


Abstract: Title Page -- Copyright -- Preface -- About the Authors -- Part One: Introduction -- Chapter 1: Introduction -- 1.1 Introduction -- 1.2 Implementation of Current-Fed Converters -- 1.3 Dynamic Modeling of Power Electronic Converters -- 1.4 Linear Equivalent Circuits -- 1.5 Impedance-Based Stability Assessment -- 1.6 Time Domain-Based Dynamic Analysis -- 1.7 Renewable Energy System Principles -- 1.8 Content Review -- References -- Chapter 2: Dynamic Analysis and Control Design Preliminaries -- 2.1 Introduction -- 2.2 Generalized Dynamic Representations - DC-DC -- 2.3 Generalized Dynamic Representations: DC-AC, AC-DC, and AC-AC -- 2.4 Small-Signal Modeling -- 2.5 Control Design Preliminaries -- 2.6 Resonant LC-Type Circuits -- References -- Part Two: Voltage-Fed DC-DC Converters -- Chapter 3: Dynamic Modeling of Direct-on-Time Control -- 3.1 Introduction -- 3.2 Direct-on-Time Control -- 3.3 Generalized Modeling Technique -- 3.4 Fixed-Frequency Operation in CCM -- 3.5 Fixed-Frequency Operation in DCM -- 3.6 Source and Load Interactions -- 3.7 Impedance-Based Stability Issues -- 3.8 Dynamic Review -- References -- Chapter 4: Dynamic Modeling of Current-Mode Control -- 4.1 Introduction -- 4.2 Peak Current Mode Control -- 4.3 Average Current-Mode Control -- 4.4 Variable-Frequency Control -- 4.5 Source and Load Interactions -- 4.6 Impedance-Based Stability Issues -- 4.7 Dynamic Review -- 4.8 Critical Discussions on PCM Models and Their Validation -- References -- Chapter 5: Dynamic Modeling of Current-Output Converters -- 5.1 Introduction -- 5.2 Dynamic Modeling -- 5.3 Source and Load Interactions -- 5.4 Impedance-Based Stability Issues -- 5.5 Dynamic Review -- References -- Chapter 6: Control Design Issues in Voltage-Fed DC-DC Converters -- 6.1 Introduction -- 6.2 Developing Switching and Average Models -- 6.3 Factors Affecting Transient Response.

6.4 Remote Sensing -- 6.5 Simple Control Design Method -- 6.6 PCM-Controlled Superbuck Converter: Experimental Examples -- 6.7 Concluding Remarks -- References -- Part Three: Current-Fed Converters -- Chapter 7: Introduction to Current-Fed Converters -- 7.1 Introduction -- 7.2 Duality Transformation Basics -- 7.3 Duality-Transformed Converters -- 7.4 Input Capacitor-Based Converters -- References -- Chapter 8: Dynamic Modeling of DDR-Controlled CF Converters -- 8.1 Introduction -- 8.2 Dynamic Models -- 8.3 Source and Load Interactions -- 8.4 Impedance-Based Stability Assessment -- 8.5 Output-Voltage Feedforward -- 8.6 Dynamic Review -- References -- Chapter 9: Dynamic Modeling of PCM/PVM-Controlled CF Converters -- 9.1 Introduction -- 9.2 Duty-Ratio Constraints and Dynamic Models under PCM Control -- 9.3 Duty-Ratio Constraints and Dynamic Models under PVM Control -- 9.4 Concluding Remarks -- References -- Chapter 10: Introduction to Photovoltaic Generator -- 10.1 Introduction -- 10.2 Solar Cell Properties -- 10.3 PV Generator -- 10.4 MPP Tracking Methods -- 10.5 MPP Tracking Design Issues -- 10.6 Concluding Remarks -- References -- Chapter 11: Photovoltaic Generator Interfacing Issues -- 11.1 Introduction -- 11.2 Centralized PV System Architecture -- 11.3 Distributed PV System Architectures -- 11.4 PV Generator-Induced Effects on Interfacing-Converter Dynamics -- 11.5 Stability Issues in PV Generator Interfacing -- 11.6 Control Design Issues -- References -- Part Four: Three-Phase Grid-Connected Converters -- Chapter 12: Dynamic Modeling of Three-Phase Inverters -- 12.1 Introduction -- 12.2 Dynamic Model of Voltage-Fed Inverter -- 12.3 Dynamic Model of Current-Fed Inverter -- 12.4 Source-Affected Dynamics of Current-Fed Inverter -- 12.5 Dynamic Model of Current-Fed Inverter with LCL-Filter -- 12.6 Summary -- Appendix 12.A -- References.

Chapter 13: Control Design of Grid-Connected Three-Phase Inverters -- 13.1 Introduction -- 13.2 Synchronous Reference Frame Phase-Locked-Loop -- 13.3 AC Current Control -- 13.4 Decoupling Gains -- 13.5 Grid Voltage Feedforward -- 13.6 Cascaded Control Scheme in Current-Fed Inverters -- 13.7 Case Study: Instability Due to RHP-Pole -- 13.8 Summary -- References -- Chapter 14: Reduced-Order Closed-Loop Modeling of Inverters -- 14.1 Introduction -- 14.2 Reduced-Order Model of Voltage-Fed Inverter -- 14.3 Reduced-Order Model of Current-Fed Inverter with L-Type Filter -- 14.4 Closed-Loop Model of Current-Fed Inverter with LC-Type Filter -- 14.5 Summary -- References -- Chapter 15: Multivariable Closed-Loop Modeling of Inverters -- 15.1 Introduction -- 15.2 Full-Order Model of Current-Fed Inverter with L-Type Filter -- 15.3 Experimental Verification of Admittance Model -- 15.4 Full-Order Model of Current-Fed Inverter with LCL-Type Filter -- 15.5 Summary -- References -- Chapter 16: Impedance-Based Stability Assessment -- 16.1 Introduction -- 16.2 Modeling of Three-Phase Load Impedance in the dq-Domain -- 16.3 Impedance-Based Stability Criterion -- 16.4 Case Studies -- 16.5 Summary -- References -- Chapter 17: Dynamic Modeling of Three-Phase Active Rectifiers -- 17.1 Introduction -- 17.2 Open-Loop Dynamics -- 17.3 Verification of Open-Loop Model -- 17.4 Experimental Results -- 17.5 Summary -- References -- Index -- End User License Agreement

✦ Subjects

Umrichter.;Leistungselektronik.

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