State of the Art of Repetitive Control in Power Electronics and Drive Applications

IF 7.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Mi Tang;Marco di Benedetto;Stefano Bifaretti;Alessandro Lidozzi;Pericle Zanchetta
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引用次数: 3

Abstract

Power electronic systems present a non-linear behavior mainly due to their switching nature. This is often combined with their interaction with non-linear systems, such as other switching converters, diode rectifiers, motor drives, etc. and with possible non linearities of the power grid in the case of grid connected systems. The major effect of these non-linear interactions is the generation of harmonic distortion on voltages and currents (both in DC and AC), which needs to be compensated to achieve high power quality systems. The use of passive filters is often the simplest and most immediate solution; however, this decreases converter efficiency and increases its weight and volume. Thus, the use of a control strategy capable of tracking periodic signals, rejecting periodic disturbance and largely improving steady state behavior and harmonic distortion with a limited bandwidth is a very desirable feature. Repetitive Control (RC) represents an extremely practical and efficient solution for the aforementioned issues, and it is widely employed in many different applications. This paper focuses on state of the art of RC used in power electronics and drives. RC basic concepts, different control structures, design methods, fixed and variable frequency operating conditions, etc. are investigated. Furthermore, many example applications and existing control approaches developed in recent years for power electronics and drive systems based on RC, have also been discussed in detail.
重复控制在电力电子和驱动应用中的最新进展
电力电子系统主要由于其开关特性而呈现非线性行为。这通常与它们与非线性系统(如其他开关转换器、二极管整流器、电机驱动器等)的相互作用相结合,并且在并网系统的情况下与电网的可能非线性相结合。这些非线性相互作用的主要影响是在电压和电流(直流和交流)上产生谐波失真,需要对其进行补偿以实现高电能质量系统。使用无源滤波器通常是最简单和最直接的解决方案;然而,这降低了转换器的效率并增加了转换器的重量和体积。因此,使用能够跟踪周期性信号、抑制周期性干扰并在有限带宽下大幅改善稳态行为和谐波失真的控制策略是非常理想的特征。重复控制(RC)是解决上述问题的一种非常实用和有效的解决方案,它被广泛应用于许多不同的应用中。本文重点介绍了RC在电力电子和驱动器中的应用现状。研究了RC的基本概念、不同的控制结构、设计方法、固定和变频操作条件等。此外,还详细讨论了近年来基于RC的电力电子和驱动系统的许多示例应用和现有控制方法。
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CiteScore
13.50
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