" Robust decentralized PID-based power system stabilizer design using an LMI approach " , Electric Power System Research 80 , pp. 1488-1497 , 2010
• 2010
معلومات البحث
المؤلفون
M. Soliman , A.-L. Elshafei, F.Bendary ,W.M.Mansour
الكلمات المفتاحية
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المجلة العلمية
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العدد
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الصفحات
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publication.type
International
رابط البحث
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المواد المرفقة
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الملخص
Thanks to its essential functionality and structure simplicity , proportional-integral derivative (PID) controllers are commonly used by industrial utilities . A robust PID- based power system stabilizer (PSS) is proposed to properly function over a wide range of operating conditions. Uncertainties in plant parameters, due to variation in generation and load patterns, are expressed in the form of a polytopic model.
The PID control problem is firstly reduced to a generalized static output feedback (SOF) synthesis. The derivative action is designed and implemented as a high pass filter based on a low-pass block to reduce its sensitivity to sensor noise . The proposed design algorithm adopts a quadratic Lyapunov approach to guarantee α- decay rate for the entire polytope. A constrained structure of Lyapunov function and SOF gain matrix is considered to enforce a decentralized scheme. Setting of controller parameters is carried out via an iterative linear matrix inequality (ILMI). Simulation results , based on a benchmark model of a two-area four-machine test system, are presented to compare the proposed design to a well-tuned conventional PSS and to the standard IEEE-PSS4B stabilizer .
The PID control problem is firstly reduced to a generalized static output feedback (SOF) synthesis. The derivative action is designed and implemented as a high pass filter based on a low-pass block to reduce its sensitivity to sensor noise . The proposed design algorithm adopts a quadratic Lyapunov approach to guarantee α- decay rate for the entire polytope. A constrained structure of Lyapunov function and SOF gain matrix is considered to enforce a decentralized scheme. Setting of controller parameters is carried out via an iterative linear matrix inequality (ILMI). Simulation results , based on a benchmark model of a two-area four-machine test system, are presented to compare the proposed design to a well-tuned conventional PSS and to the standard IEEE-PSS4B stabilizer .
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