The paper addresses the design of two‐level power system stabilizers using an optimal reduced order model whose state variables are torque angles and speeds. The reduced order model retains their physical meaning and is used to design a two‐level linear feedback controller that takes into account the realities and constraints of electrical power systems. The two‐level control strategy is used, and a global control signal is generated from the output variables to minimize the effect of interactions. The effectiveness of this controller is evaluated and a multimachine system is given as an example to illustrate the advantages of the proposed method. Responses of the system with a two‐level scheme and an optimal reduced order scheme are included for comparative analysis.
h i s paper addresses the design of two-level Power System Stabilizers using an optimal reduced order model whose state variables are torque angles and speeds. The reduced-order model retains their physical meaning and is used to design a two-level linear feedback controller that takes into account the realities and constraints of the electrical power systems. The two-level control strategy is used and a global control signal is generated from the output variables to minimize the effect of interactions. Effectiveness of this controller is evaluated and example, the multimachine system, is given to illustrate the advantages of the proposed method. Fesponses of the system with two-level scheme and optimal reduced order scheme are included for comparative analyses.
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