Chapter 1: Introduction

Chapter 2: Smart grid: Benefits and challenges

Chapter 3: Concept of Flexibility in power systems

Chapter 4: Quantifying demand side flexibility

Chapter 5: Predicting available demand side flexibility

Dr. Roya Ahmadiahangar received her M.S. and Ph.D. degrees in power systems engineering from the Babol University of Technology, Babol, Iran, in 2009 and 2014, respectively. She is a Postdoctoral researcher with the Department of Electrical Power Engineering and Mechatronics, Tallinn University of Technology. Her research interests Include integration of DER in smart grids, demand response, AI applied to smart grid and planning and management of power systems.

Prof. Ivo Palu received his PhD in electrical engineering from Tallinn University of Technology, Tallinn, Estonia, in 2009. He is presently a Professor and Head of Department of the Department of Electrical Power Engineering, Tallinn University of Technology. His research interests include Integration of renewable energy sources into electrical networks including co-operation of power units, power quality measurements and research.

Prof. Aydin Azizi holds a PhD degree in Mechanical Engineering and currently serves as a Senior Lecturer at the Oxford Brookes University, also he conducts SMSCP certification program as an official Siemens certified mechatronics instructor at German University of Technology in Oman. His current research focuses on investigating and developing novel techniques to model, control and optimize complex systems. Prof. Azizi’s areas of expertise include Control & Automation, Artificial Intelligence and Simulation Techniques. Prof. Azizi is the recipient of the National Research Award of Oman for his AI-focused research, DELL EMC’s “Envision the Future” completion award in IoT for “Automated Irrigation System”, and ‘Exceptional Talent’ recognition by the British Royal Academy of Engineering.

This book highlights recent advances in the identification, prediction and exploitation of demand side (DS) flexibility and investigates new methods of predicting DS flexibility at various different power system (PS) levels. Renewable energy sources (RES) are characterized by volatile, partially unpredictable and mostly non-dispatchable generation. The main challenge in terms of integrating RES into power systems is their intermittency, which negatively affects the power balance. Addressing this challenge requires an increase in the available PS flexibility, which in turn requires accurate estimation of the available flexibility on the DS and aggregation solutions at the system level. This book discusses these issues and presents solutions for effectively tackling them.