TSKARNA-Norm Adaption Based NLMS with Optimized Fractional Order PID Controller Gains for Voltage Power Quality

Q1 Engineering

Chinese Journal of Electrical Engineering Pub Date : 2023-09-01 DOI:10.23919/CJEE.2023.000025

Prashant Kumar;Sabha Raj Arya;Khyati D. Mistry

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Abstract

The operation of a dynamic voltage restorer (DVR) is studied using a three-phase voltage source converter (VSC)-based topology to alleviate voltage anomalies from a polluted supply voltage. The control algorithm used included two components. The first is an adaptive Takagi-Sugeno-Kang (TSK)-based adaptive reweighted $L_{1}$ norm adaption-based normalized least mean square (TSK-ARNA-NLMS) unit, which is proposed for the extraction of fundamental active and reactive components from the non-ideal supply and is further employed to generate the load reference voltage and switching pulse for the VSC. The step size was evaluated using the proposed TSK-ARNA-NLMS controller, and the TSK unit was optimized by integration with the marine predator algorithm (MPA) for a faster convergence rate. The second, a fractional-order PID controller (FOPID), was employed for AC- and DC-link voltage regulation and was approximated using the Oustaloup technique. The FOPID ( $PI^{\gamma}D^{\mu}$ ) provides more freedom for tuning the settling time, rise time, and overshoot. The FOPID coefficients ( $K_{\mathrm{i}}, K_{\mathrm{d}}, K_{\mathrm{p}}, \gamma$ , and $\mu$ ) were optimized by employing an advanced ant lion optimization (ALO) meta-heuristics technique to minimize the performance index, namely, the integral time absolute error (ITAE) and assess the accuracy of controllers. The DVR performance was validated under dynamic- and steady-state conditions.

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基于tskarna -范数自适应的NLMS与优化分数阶PID控制器增益的电压电能质量

研究了动态电压恢复器（DVR）的操作，该恢复器使用基于三相电压源变换器（VSC）的拓扑结构来缓解电源电压污染引起的电压异常。所使用的控制算法包括两个部分。第一种是基于自适应Takagi-Sugeno-Kang（TSK）的自适应重加权$L_{1}$范数自适应归一化最小均方（TSK-ARNA-NLMS）单元，该单元被提出用于从非理想电源中提取基本有功和无功分量，并被进一步用于生成VSC的负载参考电压和开关脉冲。使用所提出的TSK-ARNA-NLMS控制器评估步长，并通过与海洋捕食者算法（MPA）集成来优化TSK单元，以获得更快的收敛速度。第二种是分数阶PID控制器（FOPID），用于交流和直流链路电压调节，并使用Oustaloup技术进行近似。FOPID（$PI^｛\gamma｝D^｛\mau｝$）为调整稳定时间、上升时间和过冲提供了更多的自由度。采用先进的蚂蚁优化（ALO）元启发式技术对FOPID系数（$K_。DVR的性能在动态和稳态条件下得到了验证。

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