Decentralized Robust Control for Damping Inter-area Oscillations in Power Systems
For power system operators, this provides a robust damping control method that overcomes the limited effectiveness of traditional controllers under varying operating conditions.
This paper develops decentralized robust controllers that improve damping ratios of inter-area oscillation modes by directly affecting real power through turbine governing systems, requiring only local signals and being robust to variations in operation conditions and system topology. Case studies on two test systems demonstrate effectiveness.
As power systems become more and more interconnected, the inter-area oscillations has become a serious factor limiting large power transfer among different areas. Underdamped (Undamped) inter-area oscillations may cause system breakup and even lead to large-scale blackout. Traditional damping controllers include Power System Stabilizer (PSS) and Flexible AC Transmission System (FACTS) controller, which adds additional damping to the inter-area oscillation modes by affecting the real power in an indirect manner. However, the effectiveness of these controllers is restricted to the neighborhood of a prescribed set of operating conditions. In this paper, decentralized robust controllers are developed to improve the damping ratios of the inter-area oscillation modes by directly affecting the real power through the turbine governing system. The proposed control strategy requires only local signals and is robust to the variations in operation condition and system topology. The effectiveness of the proposed robust controllers is illustrated by detailed case studies on two different test systems.