Extended State Observer based Integral Sliding Mode Control of Maglev Systems with Enhanced Chattering Alleviation

2021 Seventh Indian Control Conference (ICC) Pub Date : 2021-12-20 DOI:10.1109/ICC54714.2021.9703181

Atul S. Sharma, Syed Muhammad Amrr, M. Nabi, Subrata Banerjee

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引用次数: 2

Abstract

This paper investigates the development of a robust controller for regulating the magnetic levitation system, in the presence of multiple sources of uncertainties and disturbances. The proposed control strategy is designed by employing the extended state observer (ESO) with integral sliding mode control (ISMC). The proposed scheme attenuates all the uncertainties without using the upper bound knowledge of uncertainties. The application of ESO compensates for the effect of uncertainties and disturbances, which helps in significantly reducing the input chattering from ISMC because the discontinuous control of ISMC is not primarily employed for disturbance rejection. The ISMC is exploited to improve the system convergence rate and ensure robustness from the starting time $t=0$ by eliminating the reaching phase. The theoretical analysis of the closed-loop system guarantees the asymptotic convergence of system states. Besides, the performance of the proposed methodology is validated through numerical simulation. Moreover, the efficacy of the proposed controller is also illustrated by comparing its simulation results with a state-of-the-art method.

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基于扩展状态观测器的增强减振磁悬浮系统积分滑模控制

本文研究了在多不确定性和干扰源存在的情况下，对磁悬浮系统进行鲁棒控制器的开发。采用扩展状态观测器(ESO)和积分滑模控制(ISMC)设计控制策略。该方案在不使用不确定性上界知识的情况下对所有不确定性进行了衰减。ESO的应用补偿了不确定性和干扰的影响，这有助于显著降低ISMC的输入抖振，因为ISMC的不连续控制并不主要用于抑制干扰。ISMC通过消除到达相位，提高了系统的收敛速度，保证了系统从起始时间t=0开始的鲁棒性。对闭环系统的理论分析保证了系统状态的渐近收敛。最后，通过数值仿真验证了该方法的有效性。此外，通过将所提控制器的仿真结果与一种最新方法的仿真结果进行比较，也说明了所提控制器的有效性。

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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2021 Seventh Indian Control Conference (ICC)

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