Enhancing Resilience in Power Distribution Systems - Softcover

Li, Fangxing Fran; Shi, Qingxin; Zhao, Jin

 
9780443236402: Enhancing Resilience in Power Distribution Systems
Softcover
ISBN 10: 0443236402 ISBN 13: 9780443236402
Publisher: Elsevier, 2025

Synopsis

Enhancing Resilience in Power Distribution Systems presents practical guidance for readers on the challenges and potential solutions for resilience in modern power systems. The book begins by explaining the risks and problems for resilience presented by renewable-based power systems. It goes on to clarify the current state of research and propose several novel methodologies and technologies for analysis and improvement of power system resilience. These methods include deep learning, linear programming, and generative adversarial networks.

Packed with practical steps and tools for implementing the latest technologies, this book provides researchers and industry professionals with guidance on the resilient systems of the future.

  • Breaks down novel methodologies and tools from deep learning to generative adversarial networks
  • Supports readers in implementing practical steps towards resilient renewable energy
  • Presents practical guidance for readers on the challenges and potential solutions for resilience in modern power systems

"synopsis" may belong to another edition of this title.

About the Authors

Fangxing ‘Fran’ Li is the James W. McConnell Professor in Electrical Engineering and the Campus Director of CURENT at the University of Tennessee at Knoxville, USA. His current research interests include resilience, artificial intelligence in power, demand response, distributed generation and microgrid, and energy markets. From 2020 to 2021, he served as the Chair of the IEEE PES Power System Operation, Planning and Economics (PSOPE) Committee. He has been the Chair of IEEE WG on Machine Learning for Power Systems since 2019 and the Editor-In-Chief of IEEE Open Access Journal of Power and Energy (OAJPE) since 2020. Prof. Li has received numerous awards and honours including R&D 100 Award in 2020, IEEE PES Technical Committee Prize Paper award in 2019, 5 best or prize paper awards at international journals, and 6 best papers/posters at international conferences.

Qingxin Shi is an Assistant Professor in the School of Electrical and Electronic Engineering, North China Electric Power University, Beijing, China. His research interests include demand response, resilient urban power systems, and hydrogen-electric integrated energy systems. He serves as the Associate Editor of Protection and Control of Modern Power Systems and the IEEE Open Access Journal of Power and Energy (OAJPE).

Jin Zhao is an Assistant Professor in the Department of Electronic & Electrical Engineering, Trinity College Dublin, Ireland. Her research interests include power system resilience, climate adaptive energy systems, microgrids and machine learning. She currently serves as Senior Editor for IET Generation, Transmission & Distribution, Associate Editor for the IEEE Trans. on Smart Grid, Chair of the IEEE Task Force AISR, and as a member of the Steering Committee and PES representative for IEEE DataPort.

From the Back Cover

Enhancing Resilience in Power Distribution Systems presents practical guidance for readers on the challenges and potential solutions for resilience in modern power systems.

This book begins by explaining the risks and problems for resilience presented by renewable-based power systems. It goes on to clarify the current state of research and propose several novel methodologies and technologies for analysis and improvement of power system resilience. These methods include deep learning, linear programming, and generative adversarial networks.

Packed with practical steps and tools for implementing the latest technologies, Enhancing Resilience in Distribution Systems provides researchers and industry professionals with guidance on the resilient systems of the future.

"About this title" may belong to another edition of this title.

Publisher
Elsevier
Publication date
2025
Language
English
ISBN 10 
0443236402
ISBN 13 
9780443236402
Binding
Paperback
Edition number
1
Number of pages
232