Provides a deep understanding of the mechanisms, analysis methods, stability criteria, and stabilization methods for converter-driven oscillations in power systems

The extensive integration of converter-interfaced resources into power systems has significantly increased the occurrences of converter-driven oscillations, posing a serious new challenge to power system stability over the past decade. Stability Analysis of Converter-Rich Power Grids offers a comprehensive understanding of converter interactions with power systems and their oscillation characteristics. Based on academic research, this book is to explicitly connect mathematical mechanism and converter-driven oscillation phenomena, helping readers with deep insight into converter-driven oscillations.

To provide a solid foundation for studying converter-driven oscillations, the book is organized into ten chapters, covering topics such as stability mechanisms, modeling, stability criteria, analysis methods, and stabilization techniques for different types of converters.

Equipping readers with the knowledge to design stable converter systems and tackle critical power system challenges, Stability Analysis of Converter-Rich Power Grids:

• Describes the history of converter-driven oscillations and presents recent understandings and categorizations of these oscillations in sub-synchronous oscillation classification and power system stability classification
• Presents modeling methods for typical converter control approaches, including grid-following and grid-forming converters
• Explains the mechanism of mirror-frequency oscillations induced by converters and clarifies the fundamental causes of converter-driven oscillations
• Provides comprehensive stability analysis methods and distinctions in their applications, including the impedance measurement methods for stability analysis for black-box systems
• Analyzes and specifies the stability characteristics of both grid-following and grid-forming converters, with relevant stabilization measures provided accordingly

Stability Analysis of Converter-Rich Power Grids is an essential resource for engineers, system operators, and converter designers addressing power system stability challenges. It is also an excellent supplementary text for graduate and advanced undergraduate courses in power systems, renewable energy integration, and power electronics.

Jun Liang, PhD, is a Chair Professor at Cardiff University’s School of Engineering, United Kingdom. A Fellow of the IET and Senior Member of IEEE, he has extensive expertise in power electronics and HVDC systems. He co-authored the Wiley-IEEE Press title HVDC Grids: For Offshore and Supergrid of the Future (2016) and has held leadership roles in IEEE and CIGRE, contributing significantly to power system stability research.

Chuanyue Li, PhD, is a Research Associate at Cardiff University’s School of Engineering, specializing in power systems, renewable energy integration, and transportation electrification. He has co-authored multiple high-impact journal articles in leading IEEE publications. His research focuses on developing advanced analytical tools and solutions to address converter-driven instability and grid integration challenges.