This book explains and analyzes the dynamic performance of linear and nonlinear systems, particularly for Power Systems including Hybrid Power Sources. Offers a detailed description of system stability using state space energy conservation principle, and more.
The book s text focuses on explaining and analyzing the dynamic performance of linear and nonlinear systems, in particular for Power Systems (PS) including Hybrid Power Sources (HPS). The system stability is important for both PS operation and planning. Placing emphasis on understanding the underlying stability principles, the book opens with an exploration of basic concepts using mathematical models and case studies from linear and nonlinear system, and continues with complex models and algorithms from field of PS. The book s features include: (1) progressive approach from simplicity to complexity, (2) deeper look into advanced aspects of stability theory, (3) detailed description of system stability using state space energy conservation principle, (4) review of some research in the field of PS stability analysis, (5) advanced models and algorithms for Transmission Network Expansion Planning (TNEP), (6) Stability enhancement including the use of Power System Stabilizer (PSS) and Flexible Alternative Current Transmission Systems (FACTS), and (7) examination of the influence of nonlinear control on fuel cell HPS dynamics.
The book will be easy to read and understand and will be an essential resource for both undergraduate and graduate students in electrical engineering as well as to the PhDs and engineers from this field. It is also a clear and comprehensive reference text for undergraduate students, postgraduate and research students studying power systems, and also for practicing engineers and researchers who are working in electricity companies or in the development of power system technologies. All will appreciate the authors' accessible approach in introduction the power system dynamics and stability from both a mathematical and engineering viewpoint.
Revisiting and generalizing the Barkhausen s equality.- State space energy conservation principle as a tool for design and simulation of linear and nonlinear systems.- Power systems stability analysis based on advanced techniques and optimaloperation.- Optimal Tuning of UPFC Based Damping Controller Using PSO and QPSO.- Application of PSO and GA for Transmission Network Expansion Planning.- Nonlinear Control of the Hybrid Power Sources.
Presents Advanced optimization methods and robust control techniques in field of Electric Power System (including Hybrid Powers Sources) which are supported by design examples and simulation results, making them easy to understand
Includes examples that are related to state space energy (SSE) representation of systems reveal new approaches of synthesis and design of SSE feedback controllers for nonlinear systems
Considers new approaches of stability conditions for nonlinear systems that which can be adapted and built on further as master and PhD thesis proposals