Qiuwei Wu is currently a Chair Professor at the School of Electrical and Information Engineering at Tianjin University, China. Prior to this he was a tenured Associate Professor at the Tsinghua-Berkeley Shenzhen Institute of Tsinghua University, China. His research interests are in decentralized/distributed optimal operation and control of power systems with high penetration of renewables, including distributed wind power modelling and control, decentralized/distributed congestion management, voltage control and load restoration of active distribution networks, and decentralized/distributed optimal operation of integrated energy systems. Dr. Wu is an Associate Editor of IEEE Transactions on Power Systems and IEEE Power Engineering Letters, Deputy Editor-in-Chief and Associate Editor of the International Journal of Electrical Power and Energy Systems and the Journal of Modern Power Systems and Clean Energy, and a subject editor for IET Generation, Transmission & Distribution and IET Renewable Power Generation.

Sheng Huang is currently a full Professor in the College of Electrical and Information Engineering, Hunan University, China. He received his M.S. and PhD degrees both from the College of Electrical and Information Engineering, Hunan University, Changsha, China, in 2012 and 2016, respectively. His research interests are in decentralized/distributed optimal operation and coordinated control of power systems with high penetration of wind power, including renewable energy generation, modeling and integration study of wind power, and decentralized/distributed voltage control of integrated wind power systems. Prof. Huang is an Editor of IET Renewable Power Generation and Protection and Control of Modern Power Systems.

Juan Wei is currently a Postdoc with the College of Electrical and Information Engineering, Hunan University, China. She received her B.S. and M.S. degrees in electrical engineering from the North China Electric Power University, Beijing, China, in 2011 and 2014, and obtained her PhD degree in electrical engineering from Hunan University, China, in 2022. Her research interests include wind power modeling and control, decentralized/distributed voltage control and optimal operation of integrated wind power systems, and high-voltage ride-through and post-event recovery control of large-scale wind farms. Dr. Wei is an Editor of Hunan Electric Power.

Pengda Wang is a Research Associate with College of Electrical and Information Engineering, Hunan University, China. He obtained his PhD degree in Electrical Engineering from the Technical University of Denmark, Denmark, in 2022. His research interests lie in coordinated control of wind power and combined AC/DC grid, including distributed wind power modelling and control, voltage control and active/reactive power control of large-scale wind farms and combined AC/DC grid.

Canbing Li is currently a Professor with the School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai, China. He received his B.E. and Ph.D. degrees from Tsinghua University, Beijing, China, in 2001 and 2006, respectively, both in electrical engineering. His research interests include power systems, smart grid, renewable energy with an emphasis on large-scale power system dispatch, economic and secure operation of power systems, energy efficiency and energy saving in smart grid, electric demand management of data centers, vehicle-to-grid technologies.

Vladimir Terzija is a Full Professor at the School of Engineering, Newcastle University, in the United Kingdom. He was previously a Full Professor and the Head of Laboratory of Modern Energy Systems with Skoltech, Russian Federation (2021-23), EPSRC Chair Professor in power system engineering at the University of Manchester, UK (2006-20), and an Assistant Professor at the University of Belgrade (1997-99). From 2000 to 2006, he was a Senior Specialist for switchgear and distribution automation with ABB, in Germany. His research interests include smart grid applications, wide-area monitoring, protection and control, multi-energy systems, switchgear and transient processes, ICT, data analytics, and digital signal processing applications in power systems. Prof. Terzija was the recipient of the prestigious Alexander von Humboldt Fellowship, and is the Editor-in-Chief of the International Journal of Electrical Power and Energy Systems.

Texte du rabat
Distributed Optimal Control of Large-Scale Wind Farm Clusters: Optimal Active and Reactive Power Control, and Fault Ride Through explores the latest advances in distributed optimal control of large-scale wind farm clusters, also describing distributed optimal control techniques for high voltage ride through (HVRT). The control schemes can enable wind farm clusters to deliver the required active and reactive power for the secure operation of future renewable based power systems. Both mathematical formulations and algorithm details are provided in the book, with MATLAB codes in order to replicate and implement the distributed optimal control schemes. A volume in the Elsevier Wind Energy Engineering Series, this is a valuable resource for all those with an interest in the operation, control, and integration of wind power plants, wind farms, and electricity grids, both at research and operational levels. This includes researchers, faculty, scientists, engineers, R&D, and other industry professionals, as well as graduate and postgraduate students studying and working in wind energy.

Contenu

Section I - Introduction

Introduction to Large-Scale Wind Power Integration

Section II - Optimal Active Power Control of Large-Scale Wind Farm Clusters

Bi-Level Decentralized Active Power Control for Large-Scale Wind Farm Clusters
Optimal Active Power Control Based on MPC for DFIG-based Wind Farm Equipped with Distributed Energy Storage Systems
Hierarchical Active Power Control of DFIG-based Wind Farm with Distributed Energy Storage Systems based on Alternating Direction Method of Multipliers (ADMM)
5 Hierarchical Optimal Control for Synthetic Inertial Response of Wind Farm Based on Alternating Direction Method of Multipliers (ADMM)

Section III - Optimal Active and Reactive Power Control of Large-Scale Wind Farm Clusters

Bi-Level Decentralized Active and Reactive Power Control for Large-Scale Wind Farm Cluster
Two-Tier Combined Active and Reactive Power Control for VSC-HVDC Connected Large-Scale Wind Farm Cluster based on Alternating Direction Method of Multipliers (ADMM)
Distributed Optimal Active and Reactive Power Control for Wind Farms Based on ADMM
ADMM-based Distributed Active and Reactive Power Control for Regional AC Grids with Wind Farms

Section IV - Optimal Voltage Control of Large-Scale Wind Farm Clusters

Distributed Voltage Control based on ADMM for Large Scale Wind Farm Cluster connected to VSC HVDC
Distributed Optimal Voltage Control for VSC-HVDC Connected Large-Scale Wind Farm Cluster Based on Analytical Target Cascading Method
Adaptive Droop-based Hierarchical Optimal Voltage Control Scheme for VSC-HVDC Connected Offshore Wind Farm
Distributed Optimal Voltage Control Strategy for AC Grid with DC Connection and Offshore Wind Farms Based on Alternating Direction Method of Multipliers (ADMM)

Section V - Fault Ride Through of Wind Farm Clusters

Coordinated Droop Control and Adaptive Model Predictive Control for Enhancing HVRT and Post-Event Recovery of Large-Scale Wind Farms
Hierarchical Event-Triggered MPC-Based Coordinated Control for HVRT and Voltage Restoration of Large-Scale Wind Farms
Coordinated Voltage Support Control for Enhancing LVRT Capability of Large-Scale Wind Farms