Microgrid Cyberphysical Systems

Renewable Energy and Plug-in Vehicle Integration

1st Edition - June 3, 2022
Imprint: Elsevier
Editors: Bidyadhar Subudhi, Pravat Kumar Ray
Language: English
Paperback ISBN:
9 7 8 - 0 - 3 2 3 - 9 9 9 1 0 - 6
eBook ISBN:
9 7 8 - 0 - 3 2 3 - 9 8 3 9 9 - 0

Microgrid Cyberphysical Systems: Renewable Energy and Plug-in Vehicle Integration outlines the fundamental concepts on microgrid system design and control in a cyberphysical… Read more

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Microgrid Cyberphysical Systems: Renewable Energy and Plug-in Vehicle Integration outlines the fundamental concepts on microgrid system design and control in a cyberphysical framework, focusing on the integration of renewables and EVs into microgrids. Including operational, control and management perspectives, the volume aims to optimize the reliability and economic performance of microgrids, focusing on power quality, storage and voltage and frequency control. The work encompasses generation, transmission, protection and load management under uncertainty and discusses critical drivers in robustness, uncertainty and sustainability management. Focusing on applied implementations, chapters are supported by detailed methods, heavy figurative explication, and comparative and integrative analysis.

Case studies range across chapters. In addition, chapters are supported by representative experimental or test bed validations of proposed algorithms or methods which can be directly applied to reader problems.

Cover
Title page
Table of Contents
Copyright
Contributors
Preface
Chapter 1: Denial-of-service attack resilient control for cyber physical microgrid system
Abstract
1: Introduction
2: Microgrid control design for DOS attack
3: Event-based control in presence of DOS attack
4: Verification and result analysis of the proposed scheme
5: Conclusion
References
Chapter 2: Distributed generating system integration: Operation and control
Abstract
1: Introduction
2: Grid supporting mode of VSI in distributed generating system
3: Grid following mode of VSI in distributed generating system
4: Grid forming mode of VSI in distributed generating system
5: Converter control in EV-based distributed generating system
6: Conclusions
References
Chapter 3: Short-term solar irradiance forecasting using ground-based sky images
Abstract
1: Introduction
2: Methodology adopted for forecasting of solar irradiance using sky images
3: Updating clearness index Kt using RLS algorithm
4: Updating clearness index Kt using variable leaky LMS (VLLMS) algorithm
5: Conclusions
References
Chapter 4: Design and experimental validation of robust PID control for a power converter in a DC microgrid application
Abstract
1: Introduction
2: QFT design of external disturbance minimization problem
3: Application of the proposed QFT design to NMP boost-type DC-DC power electronic converter
4: Simulation studies
5: Experimental validation
6: Conclusions
References
Further reading
Chapter 5: Control of PV and EV connected smart grid
Abstract
Acknowledgment
1: Introduction
2: Impact of PV and EV on the electricity grid
3: Smart microgrids, classifications, and interconnection of sources
4: Control architecture for efficient operation of microgrids
5: EV modeling and charging algorithms
6: Digital real-time simulators
7: Conclusions
References
Chapter 6: Adaptive control of islanded AC microgrid
Abstract
1: Introduction
2: Detailed modeling of islanded AC MG
3: Proposed adaptive control scheme
4: Simulation results and analysis
5: Conclusion
References
Chapter 7: Proactive defense system for enhanced resiliency of power grids with microgrids
Abstract
1: Introduction
2: Dependencies and energy management in deregulated grid
3: Renewable uncertainty instigated disturbance propagation
4: Enhancing the power grid resiliency against long-term voltage instability
5: Proactive defense methodology for enhancing power system resiliency
6: Implementation of presented methodology
7: Case studies and discussions
8: Conclusions
References
Chapter 8: Adaptive controller-based shunt active power filter for power quality enhancement in grid-integrated PV systems
Abstract
1: Introduction
2: Filter configuration
3: Modeling of three-phase three-wire SAPF
4: PI controller for DC voltage stabilization
5: MRAC for DC voltage stabilization
6: Simulation results
7: Experimental results
8: Conclusions
References
Chapter 9: Issues and challenges in microgrid protection
Abstract
1: Introduction
2: Microgrid protection challenges
3: Review of microgrid protection schemes
4: Conclusions
References
Chapter 10: Protection schemes in microgrid
Abstract
1: Introduction
2: Classification of microgrids
3: Hierarchical control architecture of microgrids
4: Protection issues in microgrids
5: Protection schemes for AC microgrids
6: Protection schemes for DC microgrids
7: Protection scheme for hybrid AC/DC microgrid
8: Conclusion
References
Index

Bidyadhar Subudhi

Bidyadhar Subudhi received the Bachelor Degree in Electrical Engineering from National Institute of Technology, Rourkela, India, Master of Technology in Control & Instrumentation from Indian Institute of Technology, Delhi, India in 1988 and 1994 respectively and Ph.D. degree in Control System Engineering from Univ. of Sheffield in 2003. He was a post doc in the Dept of Electrical and Computer Engineering, National University of Singapore in 2005. He authored/co-authored 130 research papers, 3 books and 12 book and book chapters. Currently he is a professor in the School of Electrical Science at Indian Institute of Technology Goa, India. He is a Senior Member of IEEE, Fellow IET and Fellow of INAE. His research interests include system and control, PV and Microgrid Control and Active power filtering.

Affiliations and expertise

Professor in the School of Electrical Science at Indian Institute of Technology Goa, India

Pravat Kumar Ray

Pravat Kumar Ray received the B.E. degree in Electrical Engineering from Indira Gandhi Institute of Technology Sarang, Odisha, India, in 2000, the M.E. degree in Electrical Engineering from Indian Institute of Engineering Science and Technology, Shibpur, Howrah, India, in 2003, and the Ph.D. degree in Electrical Engineering from National Institute of Technology (NIT) Rourkela, Rourkela, India, in 2011. He was also a Postdoctoral Fellow at Nanyang Technological University, Singapore during Jan. 2016 to June 2017. He is currently serving as an Associate Professor, Electrical Engineering in NIT Rourkela. He has guided 8 Ph.D. theses. He works on several sponsored R&D projects. He authored/co-authored 100 research papers. His research interests include Estimation & Filtering in Power System, Power system operation and control, Power Quality, Hybrid AC/DC Micro-grids, Smart Grid, Solar irradiance forecasting, Renewable Integration

Affiliations and expertise

Associate Professor, National Institute of Technology, Rourkela (NIT Rourkela), Rourkela, Odisha, India

Life Sciences

Physical Sciences & Engineering

Social Sciences & Humanities

Health