Optimization-Based Design of SVC Wide-Area Damping Controller for Power System Stability Enhancement

2021 22nd International Middle East Power Systems Conference (MEPCON) Pub Date : 2021-12-14 DOI:10.1109/MEPCON50283.2021.9686293

M. M. Radwan, A. Elgebaly, A. Azmy, Gamal E. M. Ali

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引用次数: 1

Abstract

This paper proposes a systematic approach for the design of wide-area damping controller for static VAR compensator (SVC). The proposed approach is developed in the form of a two-stage optimization problem. In the first stage, the problem of identifying the optimal feedback signal of the controller is solved, while the second stage is concerned with finding the optimal controller parameters. The optimal feedback signal is considered as a weighted summation of multiple signals that have the same type. The weights are determined optimally, where two signal selection approaches are considered for problem formulation. The two selected approaches are the geometric approach, and the residues approach. In the second stage, a multi-objective optimization problem is formulated to obtain the desired performance of the closed loop system. Both optimization stages are solved using Self-adaptive Multi-population Elitist Jaya Algorithm (SAMPE-JAYA). The proposed methodology is tested on the Western System Coordinating Council (WSCC) 3-machine, 9-bus system. Both modal analysis and nonlinear simulations have been carried out to confirm the effectiveness of the proposed design methodology.

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基于优化设计的SVC广域阻尼控制器增强电力系统稳定性

针对静态无功补偿器(SVC)，提出了一种系统的广域阻尼控制器设计方法。提出的方法以两阶段优化问题的形式发展。第一阶段解决了辨识控制器最优反馈信号的问题，第二阶段解决了寻找最优控制器参数的问题。最优反馈信号被认为是具有相同类型的多个信号的加权和。权重是最优确定的，其中两种信号选择方法被考虑用于问题的表述。所选择的两种方法是几何方法和残数方法。在第二阶段，制定了一个多目标优化问题，以获得闭环系统的期望性能。采用自适应多种群精英Jaya算法(SAMPE-JAYA)求解这两个优化阶段。该方法在西部系统协调委员会(WSCC)的3机9总线系统上进行了测试。模态分析和非线性仿真验证了所提设计方法的有效性。

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2021 22nd International Middle East Power Systems Conference (MEPCON)

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