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Control of Power Electronic Converters and Systems: Volume 4
- 1st Edition - February 24, 2024
- Editor: Frede Blaabjerg
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 8 5 6 2 2 - 5
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 8 5 6 2 3 - 2
Control of Power Electronic Converters and Systems, Volume Four covers emerging topics in the control of power electronics and converters not covered in previous volumes, includ… Read more
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Request a sales quoteControl of Power Electronic Converters and Systems, Volume Four covers emerging topics in the control of power electronics and converters not covered in previous volumes, including emerging power converter topologies, storage systems, battery chargers and the smart transformer. This updated edition specifically focuses on emerging power converter topologies and discusses very recent advances and topics with applications in power electronics and formidable probable dynamics. Chapters include modeling of power converters and their control, with supportive simulations and additional experimental results.Anyone looking for fundamental knowledge regarding new trends in power electronics by application, and also ready to use models and methodologies in their design, control and testing will find this the next invaluable resource in this highly regarded series.
- Combines essential control design methods and trends with different applications of power convertor topologies
- Includes global perspectives, case studies and real examples from different applications and their control
- Features ready-to-use models and methodologies in power electronic application, their design, control and testing
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, Graduate courses Fundamentals of Power Electronic Converter Control (Graduate course, Intensive industrial course), Control of Power Electronic Converters and Systems, Power Converters and their applications
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Section I. Emerging power converters and control technique
- Chapter 1. Z-source converters and their classifications
- 1.1. Background of Z-source converters (impedance-source converters)
- 1.2. Future directions
- Chapter 2. Control and modulation techniques of Z-source converter
- 2.1. Modeling of Z-source inverter
- 2.2. Modulation strategy classification and basic introduction
- 2.3. Impact of modulation strategies on reliability and harmonics of impedance-source inverters
- 2.4. Control strategy of Z-source networked converter
- Chapter 3. Dual active bridge converter and its control
- 3.1. Introduction
- 3.2. Operation principle and performance characterization of dual active bridge converter
- 3.3. Modeling and control for dual active bridge converter
- 3.4. Summary
- Chapter 4. Matrix converter: Model and control
- 4.1. Introduction
- 4.2. Modeling and control of third-harmonic injection matrix converter
- 4.3. Model and control of high-frequency link matrix converter
- 4.4. Summary
- Chapter 5. Switched-boost-based multilevel inverters
- 5.1. Introduction
- 5.2. Switched-boost-based 3L converter: A basic cell
- 5.3. Switched-boost-based 5L voltage source inverters
- 5.4. Switched-boost-based hybrid multilevel voltage source inverters
- 5.5. Interleaved configuration of switched-boost-based multilevel voltage source inveters with a comparative study
- 5.6. Conclusion
- Chapter 6. Power electronics building blocks: Control and applications
- 6.1. Introduction
- 6.2. Design considerations of power electronics building block architecture
- 6.3. Summary
- Chapter 7. Multisampled current control of grid-following voltage source converters
- 7.1. Introduction
- 7.2. Multisampling pulse width modulation analysis and aliasing suppression
- 7.3. Dissipation of converter-side current control
- 7.4. Dissipation of grid-side current control
- 7.5. Summary
- Section II. AI in power applications
- Chapter 8. Artificial intelligence–assisted data-driven control of power electronics systems
- 8.1. Introduction
- 8.2. Metaheuristic methods
- 8.3. Fuzzy logic
- 8.4. Machine learning
- 8.5. Perspectives and outlooks
- 8.6. Conclusions
- Chapter 9. Electric vehicle charging technology and its control
- 9.1. Introduction to electric vehicle charging
- 9.2. Onboard charger
- 9.3. Offboard charger
- 9.4. Contactless charger
- 9.5. Power quality of EV charging
- 9.6. Smart charging
- 9.7. Summary
- Chapter 10. Physics-informed neural network-based control of power electronic converters
- 10.1. Introduction
- 10.2. Trends in scientific computing
- 10.3. Data-driven estimation problems in controlling power electronics under saturation boundaries
- 10.4. Physics-informed neural network for power electronics
- 10.5. Results using physics-informed neural networks
- 10.6. Conclusions
- Chapter 11. Surrogate models for power electronic systems applying machine learning techniques
- 11.1. Introduction
- 11.2. Basic framework of surrogate model
- 11.3. Examples of applying surrogate modeling in power electronics
- 11.4. Detailed example applying surrogate modeling to power semiconductor thermal modeling considering cross-coupling effects
- 11.5. Conclusions
- Section III. Storage system and applications
- Chapter 12. Topologies and control for battery balancing applications
- 12.1. Introduction
- 12.2. Balancing topologies
- 12.3. Balancing control
- 12.4. Field examples
- 12.5. Summary
- Chapter 13. Battery state-of-health estimation using machine learning
- 13.1. Introduction—what is battery state of health?
- 13.2. Battery performance and degradation
- 13.3. Overview of state-of-health estimation methods
- 13.4. Feature-based battery state-of-health estimation
- 13.5. Sequence-based battery state-of-health estimation
- 13.6. Comparison of machine learning-based state-of-health estimation
- 13.7. Summary
- Chapter 14. Operation and control of data centers
- 14.1. Introduction
- 14.2. Full power processing–based point-of-load converters
- 14.3. Differential power processing–based point-of-load converters
- 14.4. Operation and control for data centers
- 14.5. Summary
- Chapter 15. Operation and control of uninterruptible power supply system
- 15.1. Introduction
- 15.2. Power converter topologies for uninterruptible power supply systems
- 15.3. Uninterruptible power supply control techniques
- 15.4. Progress in uninterruptible power supplies
- 15.5. Summary
- Chapter 16. Efficient modeling and simulation of wear-out and state-of-charge in storage systems
- 16.1. Introduction
- 16.2. Wear-out concept of battery energy storage
- 16.3. Challenges in estimating degradation
- 16.4. Online incremental degradation estimation
- 16.5. Case study
- 16.6. Conclusion
- Section IV. Solid state transformer and its use
- Chapter 17. Solid-state transformer and magnetic properties with potential topologies: Magnetic properties of soft magnetic material for medium- or high-frequency transformers
- 17.1. Introduction
- 17.2. Classification of soft magnetic materials for solid-state transformers
- 17.3. Magnetic properties of soft magnetic materials under actual conditions
- 17.4. Summary
- Chapter 18. Voltage control of solid-state transformer to guarantee smart transformer functionalities
- 18.1. Solid-state transformer architectures
- 18.2. Smart transformer control structures
- 18.3. Stability and power quality assessment of smart transformer–fed LVAC grids
- 18.4. Influence of current feedback
- 18.5. Tuning of current and voltage controllers
- 18.6. Conclusions
- Chapter 19. Solid-state transformer applied in electrified railway systems
- 19.1. Introduction
- 19.2. Development of solid-state transformers in traction power system
- 19.3. Solid-state transformers in AC electrified railway
- 19.4. Solid-state transformers in DC electrified railway systems
- 19.5. Simulation results
- 19.6. Challenges and opportunities
- 19.7. Summary
- Index
- No. of pages: 640
- Language: English
- Edition: 1
- Published: February 24, 2024
- Imprint: Academic Press
- Paperback ISBN: 9780323856225
- eBook ISBN: 9780323856232
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: Volume 4 on ScienceDirect