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Control of Power Electronic Converters and Systems
Volume 3
- 1st Edition - April 1, 2021
- Editor: Frede Blaabjerg
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 1 9 4 3 2 - 4
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 1 9 4 3 3 - 1
Control of Power Electronic Converters and Systems, Volume 3, explores emerging topics in the control of power electronics and converters, including the theory behind control,… Read more
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Request a sales quoteControl of Power Electronic Converters and Systems, Volume 3, explores emerging topics in the control of power electronics and converters, including the theory behind control, and the practical operation, modeling, and control of basic power system models. This book introduces the most important controller design methods, including both analog and digital procedures. This reference explains the dynamic characterization of terminal behavior for converters, as well as preserving the stability and power quality of modern power systems. Useful for engineers in emerging applications of power electronic converters and those combining control design methods into different applications in power electronics technology.
Addressing controller interactions - in light of increasing renewable energy integration and related challenges with stability and power quality - is becoming more frequent in power converters and passive components.
- Discusses different applications and their control in integrated renewable energy systems
- Introduces the most important controller design methods, both in analog and digital
- Describes different important applications to be used in future industrial products
- Explains the dynamic characterization of terminal behavior for converters
Graduate students, researchers, and practitioners in industry who are working on the design and control of power electronic equipment and engineers who are using the power electronic equipment in their application
- Cover image
- Title page
- Table of Contents
- Copyright
- Preface
- Chapter 1. Advanced control of power electronic systems—an overview of methods
- 1.1. Introduction
- 1.2. Linear controller implementation and analysis
- 1.3. Nonlinear controller implementation and analysis
- 1.4. Summary
- Chapter 2. Robust design and passivity control methods
- 2.1. Introduction
- 2.2. State space model of power electronic systems
- 2.3. Robust controller design
- 2.4. Robust small-signal stabilization control design
- 2.5. Passivity-based control design
- 2.6. Conclusions and future prospective
- Chapter 3. Sliding mode controllers in power electronic systems
- 3.1. Introduction
- 3.2. System dynamics of a voltage source inverter
- 3.3. Introduction to sliding mode control
- 3.4. Classical sliding mode control
- 3.5. Boundary-layer sliding mode control
- 3.6. Adaptive sliding mode control
- 3.7. Integral sliding mode control
- 3.8. Terminal sliding mode control
- 3.9. Second-order sliding mode control
- 3.10. Comparison of different SMCs
- 3.11. Experimental results
- 3.12. Conclusions
- Chapter 4. Model predictive control of power converters, motor drives, and microgrids
- 4.1. Introduction on MPC
- 4.2. MPC for permanent-magnet synchronous motor drives
- 4.3. MPC for microgrids
- 4.4. MPC for renewable energy applications (PMSG wind turbine)
- 4.5. Conclusions and future trends
- Chapter 5. Adaptive control in power electronic systems
- 5.1. Introduction
- 5.2. System dynamics on a UPS system
- 5.3. System identification
- 5.4. Indirect adaptive predictive control
- 5.5. Model reference direct adaptive control of UPS
- 5.6. Conclusion
- Chapter 6. Machine learning technique for low-frequency modulation techniques in power converters
- 6.1. Introduction
- 6.2. Cascaded H-bridge active power filter configuration
- 6.3. ANN for the asymmetric selective harmonic current mitigation-PWM
- 6.4. The proposed technique simulation and experimental results
- 6.5. Conclusion
- Chapter 7. Overview of stability analysis methods in power electronics
- 7.1. Introduction
- 7.2. Small-signal stability analysis methods
- 7.3. Large-signal stability analysis methods
- 7.4. Case studies with practical examples
- 7.5. Summary
- Chapter 8. Cyber security in power electronic systems
- 8.1. Introduction
- 8.2. Cyber physical architecture of power electronic converters
- 8.3. Vulnerability analysis of cyber attacks on control of VSCs
- 8.4. Cyber attack detection and mitigation mechanisms in power electronic systems
- 8.5. Test cases
- 8.6. Conclusions and future challenges
- Chapter 9. Advanced modeling and control of voltage source converters with LCL filters
- 9.1. Introduction
- 9.2. Modeling of the VSCs with LCL filters
- 9.3. Alternative current control of the VSCs with LCL filters
- 9.4. Impedance-based stability analysis under weak grid conditions
- Chapter 10. Phase-locked loops and their design
- 10.1. Introduction
- 10.2. PLL’s control and design
- 10.3. Three-phase PLLs
- 10.4. Single-phase PLLs
- 10.5. Summary
- Chapter 11. Stability and robustness improvement of power converters
- 11.1. Introduction
- 11.2. Stability and robustness improvement of current control
- 11.3. Stability and robustness improvement of outer-loop control
- Chapter 12. High switching frequency three-phase current-source converters and their control
- 12.1. Challenges of high switching frequency CSCs control
- 12.2. Stability analysis of the single-loop DC-link current control
- 12.3. Active damping methods for high switching frequency CSCs
- 12.4. Summary
- Chapter 13. High-power current source converters
- 13.1. Introduction
- 13.2. Current source converters and applications
- 13.3. Parallel CSC system and modulation strategies
- 13.4. Parallel CSC and circuit analysis
- 13.5. DC current balance and CMV reduction methods
- 13.6. Conclusions
- Chapter 14. Parallel operation of power converters and their filters
- 14.1. Introduction
- 14.2. Circulating current modeling
- 14.3. Circulating current control
- 14.4. Harmonic performance improvement through interleaved operation
- 14.5. Circulating current suppression in parallel interleaved converters
- 14.6. Summary
- Chapter 15. Advanced power control of photovoltaic systems
- 15.1. Introduction
- 15.2. Overview of PV inverter control
- 15.3. Requirement of advanced control functionality
- 15.4. Constant power generation control strategy
- 15.5. Benchmarking of constant power generation control strategy
- 15.6. Summary
- Chapter 16. Low voltage ride-through operation of single-phase PV systems
- 16.1. Introduction
- 16.2. Low voltage ride-through operations
- 16.3. Reactive power injection strategies under LVRT
- 16.4. Summary
- Chapter 17. Grid-following and grid-forming PV and wind turbines
- 17.1. Introduction
- 17.2. PV and wind turbine systems
- 17.3. Grid-following power converters
- 17.4. Grid-forming power converters
- 17.5. Conclusions
- Chapter 18. Virtual inertia operation of renewables
- 18.1. Introduction
- 18.2. Evolution of green energy transition
- 18.3. Virtual inertia-based control
- 18.4. VSM implementation
- 18.5. Summary and future trend
- Chapter 19. Virtual inertia emulating in power electronic–based power systems
- 19.1. Introduction
- 19.2. Inertia concept
- 19.3. Inertia challenges of power electronic–based power systems
- 19.4. Adaptive inertia for grid-connected VSGs
- 19.5. Simulation and experimental results
- 19.6. Summary
- Chapter 20. Abnormal operation of wind turbine systems
- 20.1. Introduction
- 20.2. Control of type III wind turbine during grid faults
- 20.3. Control of type IV wind turbine during grid faults
- 20.4. Summary
- Chapter 21. Wind farm control and optimization
- 21.1. Introduction
- 21.2. Wind farm active dispatch
- 21.3. Wind farm reactive dispatch
- 21.4. Wind farm layout optimization
- 21.5. Conclusion
- Chapter 22. Power converters and control of LEDs
- 22.1. Introduction
- 22.2. Characteristics of LEDs and drivers
- 22.3. Color control with a power converter
- 22.4. Efficiency and lifetime improvement
- 22.5. Current sharing schemes
- 22.6. Reliability assessment
- Index
- No. of pages: 718
- Language: English
- Edition: 1
- Published: April 1, 2021
- Imprint: Academic Press
- Paperback ISBN: 9780128194324
- eBook ISBN: 9780128194331
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