Current Harmonic Compensation by Active Power Filter Using Neural Network-Based Recognition and Controller

Sahand Liasi, R. Hadidi, Narges S. Ghiasi
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Abstract

In recent decades, the increasing use of nonlinear loads has caused many problems in terms of power quality. These problems include low power factor, and voltage and current harmonics. The distorted voltage can result in increasing temperature of wires and cables, inappropriate performance of protective devices and disturbance in telecommunication lines. Therefore, it would be essential to install filters to omit or damp these distortions. Conventionally, passive filters were used to maintain harmonics under a sensible level. Nevertheless, this kind of filters has many problems such as large size and resonance issues. In recent years, by improvements in power electronics, passive filters have been replaced with active power filters (APF). Controlling APFs using PI, deadbeat, and predictive controllers have been discussed in different works. However, they all need an accurate model of the system or information about the converters. In this paper, we will provide two control strategies: first, an artificial neural network (ANN)-based control method which mimic conventional control methods; second, ANN-based recognition and control method, which does not require any information about the system model. This control method can be well suiting any system because it can control the whole system only based on the effects on the input on the output of the system. In this paper, ANN-based control methods have been discussed. Then, a control method based on ANN recognition and control will be introduced and developed. The simulation results will be brought, discussed, and compared to show the proficiency of the proposed method over the existent methods.
基于神经网络识别与控制的有源电力滤波器电流谐波补偿
近几十年来,越来越多的非线性负载的使用引起了许多电能质量方面的问题。这些问题包括低功率因数,电压和电流谐波。电压畸变会导致电线电缆温度升高,保护装置性能不佳,造成通信线路的干扰。因此,必须安装过滤器来消除或抑制这些扭曲。传统上,无源滤波器被用来保持谐波在一个合理的水平。然而,这种滤波器存在体积大、共振等问题。近年来,随着电力电子技术的进步,无源滤波器已被有源滤波器(APF)所取代。使用PI、无差拍和预测控制器控制apf已经在不同的工作中进行了讨论。然而,它们都需要一个精确的系统模型或有关转换器的信息。在本文中,我们将提供两种控制策略:第一,基于人工神经网络(ANN)的控制方法,模仿传统的控制方法;二是基于人工神经网络的识别控制方法,该方法不需要系统模型的任何信息。这种控制方法可以很好地适用于任何系统,因为它可以根据输入对系统输出的影响来控制整个系统。本文讨论了基于人工神经网络的控制方法。然后,介绍并发展了一种基于人工神经网络识别与控制的控制方法。本文将对仿真结果进行讨论和比较,以表明所提方法相对于现有方法的熟练程度。
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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