Robust controller designs of switched reluctance motor for electrical vehicle

22nd Mediterranean Conference on Control and Automation Pub Date : 2014-06-16 DOI:10.1109/MED.2014.6961373

N. Ouddah, M. Boukhnifer, A. Chaibet, E. Monmasson

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引用次数: 12

Abstract

The strong nonlinear and uncertain parameters of the switched reluctance motor make the traditional controllers difficult to ensure its performance and stable operation under diverse operating conditions. In this paper, we present two designs of H∞, robust controller for switched reluctance motor drives for electrical vehicle to aim at attenuating the effect of disturbances and parameters uncertainties. For the application of the H∞ theory, we have adopted the cascade control architecture (velocity - torque). The first controller of velocity in the outer control loop products the total torque of SRM. Hence, a linear equivalent mechanical dynamic is obtained. In the inner control loop, the phase reference current is determined using the torque-angle-current (T-θ-i) characteristics stored in a tabular form, the torque is regulated indirectly through the second controller of current. The design of both speed and current robust controllers using modern H∞ control theory is then summarized. For each control loop, two H∞ synthesis approaches are used and compared by μ-analysis. The simulation results demonstrate the effectiveness of the designed robust controllers and confirm the ability of the proposed designs.

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电动汽车开关磁阻电机鲁棒控制器设计

开关磁阻电机具有较强的非线性和不确定性参数，使得传统的控制器难以保证其在各种工况下的性能和稳定运行。本文提出了两种用于电动汽车开关磁阻电机驱动的H∞鲁棒控制器设计，旨在衰减干扰和参数不确定性的影响。对于H∞理论的应用，我们采用了串级控制结构(速度-转矩)。外控制回路中的第一个速度控制器产生SRM的总转矩。因此，得到了线性等效力学动力学。在内控制回路中，利用以表格形式存储的转矩-角电流(T-θ-i)特性确定相参电流，转矩通过电流第二控制器间接调节。然后总结了采用现代H∞控制理论设计速度和电流鲁棒控制器的方法。对于每个控制回路，采用了两种H∞综合方法，并通过μ-分析进行了比较。仿真结果验证了所设计鲁棒控制器的有效性，验证了所设计鲁棒控制器的有效性。

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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22nd Mediterranean Conference on Control and Automation

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