Singular Perturbation Theory for PWM AC/DC Converters: Cascade Nonlinear Control Design and Stability Analysis

Q3 Energy Iranian Journal of Electrical and Electronic Engineering Pub Date : 2022-03-01 DOI:10.22068/IJEEE.18.1.2013

Y. Mchaouar, A. Abouloifa, I. Lachkar, H. Katir, F. Giri, A. E. Aroudi, A. Elallali, C. Taghzaoui

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引用次数: 1

Abstract

In this paper, the problem of controlling PWM single-phase AC/DC converters is addressed. The control objectives are twofold: (i) regulating the output voltage to a selected reference value, and (ii) ensuring a unitary power factor by forcing the grid current to be in phase with the grid voltage. To achieve these objectives, the singular perturbation technique is used to prove that the power factor correction can be done in the open-loop system with respect to certain conditions that are not likely to take place in reality. It is also applied to fulfill the control objectives in the closed-loop through a cascade nonlinear controller based on the three-time scale singular perturbation theory. Additionally, this study develops a rigorous and complete formal stability analysis, based on multi-time-scale singular perturbation and averaging theory, to examine the performance of the proposed controller. The theoretical results have been validated by numerical simulation in MATLAB/Simulink/SimPowerSystems environment.

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PWM AC/DC变换器的奇异摄动理论：串级非线性控制设计与稳定性分析

本文研究了PWM单相AC/DC变换器的控制问题。控制目标有两个：（i）将输出电压调节到选定的参考值，以及（ii）通过强制电网电流与电网电压同相来确保单位功率因数。为了实现这些目标，奇异摄动技术被用来证明功率因数校正可以在开环系统中针对现实中不太可能发生的某些条件进行。它还被应用于通过基于三时间尺度奇异摄动理论的级联非线性控制器来实现闭环中的控制目标。此外，本研究基于多时间尺度奇异摄动和平均理论，进行了严格而完整的形式稳定性分析，以检验所提出控制器的性能。在MATLAB/Simulink/SimPowerSystems环境下进行了数值模拟，验证了理论结果的正确性。

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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