Control of Power Electronic Converters and Systems
Volume 2
- 1st Edition - April 27, 2018
- Imprint: Academic Press
- Editor: Frede Blaabjerg
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 1 6 1 3 6 - 4
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 1 6 1 6 8 - 5
Control of Power Electronic Converters, Volume Two gives the theory behind power electronic converter control and discusses the operation, modelling and control of basic converter… Read more
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Request a sales quoteControl of Power Electronic Converters, Volume Two gives the theory behind power electronic converter control and discusses the operation, modelling and control of basic converters. The main components of power electronics systems that produce a desired effect (energy conversion, robot motion, etc.) by controlling system variables (voltages and currents) are thoroughly covered. Both small (mobile phones, computer power supplies) and very large systems (trains, wind turbines, high voltage power lines) and their power ranges, from the Watt to the Gigawatt, are presented and explored. Users will find a focused resource on how to apply innovative control techniques for power converters and drives.
- Discusses different applications and their control
- Explains the most important controller design methods, both in analog and digital
- Describes different, but important, applications that can be used in future industrial products
- Covers voltage source converters in significant detail
- Demonstrates applications across a much broader context
Electrical, mechanical, mechatronic, and control engineers, who are working on the design and control of power electronic equipment
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Part IV: Power System and Quality
- Chapter 13: Active Rectifiers and Their Control
- Abstract
- 13.1 Introduction
- 13.2 Harmonic Emission Standard and Measures
- 13.3 Application-Oriented Design
- 13.4 Control Strategies
- 13.5 Nonideal Operating Conditions
- 13.6 Future Prospective
- Chapter 14: Power Converters for Power Quality Improvement
- Abstract
- 14.1 Introduction
- 14.2 Control Mechanism of Parallel Active Power Filter
- 14.3 DC Side Capacitor Design for Active Power Filter
- 14.4 Filter Inductor Design [7–9]
- 14.5 Improved Control Strategy for Power Quality Improvement
- 14.6 Conclusions
- Chapter 15: Voltage Source Converters for Large-Scale Power System Control
- Abstract
- 15.1 Introduction
- 15.2 Conventional Multilevel Converters
- 15.3 AC-DC and DC-AC Conversion Based on the Modular Multilevel Converter
- 15.4 DC-DC Conversion Based on the Modular Multilevel Converter
- 15.5 AC-AC Conversion Based on the Modular Multilevel Converter
- 15.6 Conclusions
- Chapter 16: Current Source Converters and Their Control
- Abstract
- 16.1 Introduction
- 16.2 Current Source Converters and Their Applications
- 16.3 PWM of CSC
- 16.4 Design Example on High-Power Current Source Converters for Active Grid Harmonics Mitigation
- 16.5 Conclusions
- Chapter 17: Modular Multilevel Converter (MMC) and Its Control
- Abstract
- 17.1 Introduction
- 17.2 Advanced Control Schemes of the MMC
- 17.3 Alternative Families of MMCs and Future Trends
- 17.4 Conclusion
- Chapter 18: AC and DC Microgrid Control
- Abstract
- 18.1 Introduction
- 18.2 Classification of Power Converters in AC and DC MGs
- 18.3 AC Microgrid Control
- 18.4 DC Microgrid Control
- 18.5 Conclusion
- Chapter 19: Control of Smart Grid Architecture
- Abstract
- Acknowledgments
- Nomenclature
- 19.1 Microgrid Optimization Model
- 19.2 Uncertainty Management
- 19.3 Modeling Example
- 19.4 Conclusions
- Part V: Appliances
- Chapter 20: Single-Phase Induction Motor and AC Drives
- Abstract
- 20.1 Introduction to the Single-Phase Induction Motor
- 20.2 Working Principle of the Single-Phase Induction Motor
- 20.3 Modeling of the Single-Phase Induction Motor
- 20.4 Basic Supply Methods for SPIM
- 20.5 Power Electronic Device-Based AC Drives Topology for Variable Speed Control Strategy
- 20.6 Simulation Examples
- 20.7 Conclusions
- Chapter 21: Induction Heating
- Abstract
- 21.1 Introduction
- 21.2 Induction Heating Power Systems
- 21.3 Modeling and Control
- 21.4 Design Example
- 21.5 Conclusions
- Part VI: Mobility
- Chapter 22: Theory and Control of Wireless Power Transfer Systems
- Abstract
- 22.1 Introduction
- 22.2 Fundamentals of IPT
- 22.3 Control of IPT Systems
- 22.4 Conclusion
- Chapter 23: Power Electronic Systems and Control in Automobiles
- Abstract
- 23.1 Power Electronic Systems in Electrified Vehicles
- 23.2 Control of Traction Inverter
- 23.3 Control of Boost Converter and Constant Power Load
- 23.4 Control of LV Battery Charger APM
- 23.5 Conclusions and Future Trends
- Chapter 24: Power Electronic Systems for Aircraft
- Abstract
- 24.1 Introduction
- 24.2 Aircraft Electrical Power Systems
- 24.3 Power Electronics for Electrical Power Generation Systems
- 24.4 Power Electronics for Electrical Power Distribution Systems
- 24.5 Power Electronics for New Electrical Loads
- 24.6 All-Electrical Aircraft Technologies
- 24.7 Summary
- Chapter 25: Power Electronics Systems in Satellites
- Abstract
- 25.1 Power Conditioning Unit
- 25.2 DC-DC Converter
- 25.3 Hall Power-Processing Units
- 25.4 Multimodular Combination Technology
- 25.5 Summary
- Part VII: Advanced Features in Control of Power Converters
- Chapter 26: Thermal Loading Control in Power Converters
- Abstract
- 26.1 Thermal Loading and Reliability of Power Electronics
- 26.2 Concept of Thermal Loading Control for Improved Reliability
- 26.3 Thermal Control at Modulation Level
- 26.4 Thermal Control at System Function Level
- 26.5 Thermal Control at Other Levels
- 26.6 Conclusions
- Chapter 27: Robust Continuous-Time Model Predictive Control of a Grid-Tied Photovoltaic System
- Abstract
- 27.1 Introduction to the Continuous-Time Model Predictive Control
- 27.2 Robust Continuous-Time MPC of a Grid-Tied Three-Phase Inverter
- 27.3 Robust Continuous-Time Model Predictive Control of the Boost Converter
- 27.4 Summary
- Chapter 28: Advanced Gate Drive Approaches for Optimal Device-Level Control
- Abstract
- 28.1 Trend of a Digital Revolution
- 28.2 IGBT Gate Drive Control
- 28.3 Summary
- Chapter 29: Modern Control Architectures and Implementation
- Abstract
- 29.1 Introduction
- 29.2 Digital Technologies
- 29.3 Digital Implementation Design Flow
- 29.4 Simulation
- 29.5 Conclusions
- Appendix A
- Appendix B
- Appendix C
- Appendix D
- Index
- Edition: 1
- Published: April 27, 2018
- No. of pages (Paperback): 532
- No. of pages (eBook): 532
- Imprint: Academic Press
- Language: English
- Paperback ISBN: 9780128161364
- eBook ISBN: 9780128161685
FB
Frede Blaabjerg
Prof. Blaabjerg has been a Professor of Power Electronics and Drives with AAU Energy at Aalborg University, Denmark since 1998. He has published over 600 journal papers and 22 books. He has received 38 IEEE Prize Paper Awards, the IEEE PELS Distinguished Service Award (2009), the EPE-PEMC Council Award (2010), the IEEE William E. Newell Power Electronics Award (2014), the Villum Kann Rasmussen Research Award (2014), the Global Energy Prize (2019) and the 2020 IEEE Edison Medal. He was the Editor-in-Chief of the IEEE Transaction on Power Electronics (2006-2012), and a Distinguished Lecturer for the IEEE Power Electronics Society (2005-2007) and the IEEE Industry Applications Society (2010-2011, 2017-2018). He has served as President of the IEEE Power Electronics Society (2019-2020) and Vice-President of the Danish Academy of Technical Sciences, and was named one of the 250 top-cited Engineering researchers in the world (Thomas Reuters, 2014-2021).
Affiliations and expertise
Professor of Power Electronic Systems, Department of Energy, Technology, Aalborg University, DenmarkRead Control of Power Electronic Converters and Systems on ScienceDirect