Learning-based Fractional Order PID Controller for Load Frequency Control of Distributed Energy Resources Including PV and Wind Turbine Generator

Mohsen Babaei, Mohsen Hadian
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Abstract

Due to the ever-increasing penetration of renewable resources, Frequency control of microgrids has recently been received special consideration from researchers. The continual supply of load consumption is the major issue of standalone microgrids due to the high penetration of renewable resources. Furthermore, microgrids suffer from low inertia against load changes due to their small size and unpredictable load interruption. In addition to the above-mentioned issues, the uncertain and intermittent behaviors of renewable resources cause problems to keep the balance between load and generation sides. Hence, it is very important to consider novel control methods for keeping balance and consequently control of frequency deviation. In this research, a novel learning-based fractional-order controller is proposed to control the frequency of microgrids including micro-turbines, photovoltaic panels, and wind turbines in order to increase system stability and reduce frequency fluctuation time. The efficiency of this controller has been compared with conventional methods in the simulation and result section.
基于学习的分数阶PID控制器用于分布式能源(包括光伏和风力发电)的负荷频率控制
由于可再生能源的不断普及,微电网的频率控制近年来受到了研究人员的特别关注。由于可再生资源的高度渗透,负载消耗的持续供应是独立微电网的主要问题。此外,由于微电网体积小,负载中断不可预测,因此对负载变化的惯性较低。除上述问题外,可再生资源的不确定性和间歇性行为也给负荷侧与发电侧的平衡带来了问题。因此,考虑新的控制方法来保持平衡,从而控制频率偏差是非常重要的。本研究提出了一种基于学习的分数阶控制器,用于控制微电网的频率,包括微涡轮、光伏板和风力发电机组,以提高系统稳定性,减少频率波动时间。在仿真和结果部分,将该控制器与传统方法的效率进行了比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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