Design of Robust Control for Vehicle Steer-by-Wire System

Q1 Earth and Planetary Sciences

Indonesian Journal of Science and Technology Pub Date : 2022-12-28 DOI:10.17509/ijost.v8i2.54794

S. S. Husain, M. Q. Kadhim, A. Al-Obaidi, Alaq F. Hasan, A. Humaidi, Dwi Novia Al Husaeni

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引用次数: 6

Abstract

This study presented the design of a robust controller based on Integral Sliding Mode Control (ISMC) for controlling the Vehicle Steer-by-Wire (VSbW) system. The dynamic model of the VSbW system is first developed and then the design of ISMC has been conducted via the states of the system. The VSbW system has been described by two terms; one term represents the nominal model, which is free from nonlinearities, and the other term lumps the uncertainties in system parameters. The integral sliding mode controller has been designed for controlling the VSbW system. The control design consists of two parts. The first control part has addressed the nominal term of the system, while the second control part tackles and eliminates the effects of uncertainties and perturbation due to the uncertain term of the system. The numerical simulation has been conducted to show the robustness of ISMC and its capability to reduce the chattering effect in the control signal. In addition, a comparison study in performance has been conducted between the proposed controller and other controllers in the literature. We also carry out bibliometric analysis to see research trends. Based on our analysis, the number of publications regarding the keywords "controller", "steer", and "wire system" changes every year (25 (2018), 56 (2019), 51 (2020), 71 (2021), and 61 (2022)).

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汽车线控转向系统鲁棒控制设计

研究了基于积分滑模控制(ISMC)的汽车线控系统鲁棒控制器的设计。首先建立了VSbW系统的动力学模型，然后根据系统的状态进行ISMC的设计。VSbW系统用两个术语来描述;其中一项表示没有非线性的标称模型，另一项则集中了系统参数中的不确定性。设计了积分滑模控制器来控制VSbW系统。控制设计包括两个部分。第一个控制部分解决了系统的名义项，而第二个控制部分处理和消除了系统不确定项引起的不确定性和扰动的影响。数值仿真结果表明了ISMC的鲁棒性和抑制控制信号抖振效应的能力。此外，本文还对所提出的控制器与文献中其他控制器的性能进行了比较研究。我们还进行文献计量分析，以了解研究趋势。根据我们的分析，关于“控制器”、“转向”和“电线系统”等关键词的出版物数量每年都在变化(25篇(2018年)、56篇(2019年)、51篇(2020年)、71篇(2021年)和61篇(2022年))。

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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