This book provides readers with an in-depth review of deep learning-based techniques and discusses how they can benefit power system applications. Representative case studies of deep learning techniques in power systems are investigated and discussed, including convolutional neural networks (CNN) for power system security screening and cascading failure assessment, deep neural networks (DNN) for demand response management, and deep reinforcement learning (deep RL) for heating, ventilation, and air conditioning (HVAC) control.
Deep Learning for Power System Applications: Case Studies Linking Artificial Intelligence and Power Systems is an ideal resource for professors, students, and industrial and government researchers in power systems, as well as practicing engineers and AI researchers.
- Provides a history of AI in power grid operation and planning;
- Introduces deep learning algorithms and applications in power systems;
- Includes several representative case studies.
Introduction-A Brief History of Deep Learning and Its Applications in
Power Systems.- Deep Neural Network for Microgrid Management.- Deep
Convolutional Neural Network for Power System N-1 Contingency Screening and
Cascading Outage Screening.- Intelligent Multi-zone Residential HVAC Control
Strategy Based on Deep Reinforcement Learning.- Summary and Future Works.
Fangxing Fran Li received his B.S.E.E. and M.S.E.E. degrees from Southeast University, Nanjing, in 1994 and 1997, respectively, and his Ph.D. from Virginia Tech, Blacksburg, VA, in 2001. He is the James McConnell Professor with the University of Tennessee, Knoxville, TN. His research interests include power system artificial intelligence, renewable energy integration, demand response, power markets, and power system control. He is a registered Professional Engineer (P.E.) in the State of North Carolina, a Fellow of the IEEE (Class of 2017), the current Editor-In-Chief of IEEE Open Access Journal of Power and Energy (OAJPE), the current Chair of the IEEE/PES Power System Operation, Planning and Economics (PSOPE) committee, and the current Chair of the IEEE/PES Task Force on Machine Learning in Power Systems. He received the 2020 Best Paper Award from the Journal of Modern Power Systems and Clean Energy (MPCE), the Third Prize Paper Award from CSEE Journal of Powerand Energy Systems (JPES) in 2019, the 2019 IEEE/PES Technical Committee Prize Paper Award, the Applied Energy Highly Cited Paper Awards three times for papers published in 2016, 2020, and 2021, and six Best Conference Papers/Posters awards. As a Principal Investigator, he received the prestigious 2020 R&D 100 Finalist honor for the project DCNNN (Deep Convolutional Neural Network for N-1) which is closely related to this book. Also, as a Principal Investigator, he received the prestigious R&D 100 Award in 2020 for the project CURENT LTB (Large-scale Test Bed).
Yan Du received her B.S. degree from Tianjin University, Tianjin, in 2013, an M.S. degree from the Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing, in 2016, and her Ph.D. degree from The University of Tennessee (UT) in 2020. She received the UT EECS Department Outstanding Graduate Research Assistant award in 2019, the UT Chancellors Citation Award in Extraordinary Professional Promise in 2020, and the UT Min Kao Fellowship in 2019-2020. Presently, she is a software engineer at Google, Seattle, WA. Her research interest is deep learning in power systems. As the lead developer, she was a co-recipient of the prestigious R&D 100 Finalist honor in 2020 for the project DCNNN (Deep Convolutional Neural Network for N-1) which is closely related to this book.
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