Vibration control and performance analysis of full car active suspension system using fractional order terminal sliding mode controller

IF 1.2 4区计算机科学 Q4 AUTOMATION & CONTROL SYSTEMS Archives of Control Sciences Pub Date : 2023-07-20 DOI:10.24425/acs.2020.133501

T. Yuvapriya

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引用次数: 4

Abstract

The main goal of introducing Active Suspension System in vehicles is to reduce the vehicle body motion under road obstacles which improves the ride comfort of the passenger. In this paper, the Full Car Model (FCM) with seven Degrees of Freedom is considered and simulated by MATLAB/Simulink. The Terminal Sliding Mode Controller (TSMC) and Fractional Order Terminal Sliding Mode Controller (FOTSMC) are designed to enhance the ride quality, stability and passenger comfort for FCM. The designed FOTSMC has the ability to provide higher control accuracy in a ﬁnite time. The performances of the designed controllers are evaluated by measuring the vehicle body vibration in both angular and vertical direction under bump input and ISO-8608 random input against passive suspension system. The Frequency Weighted Root Mean Square (FWRMS) and Vibration dose value of Body Acceleration as per ISO-2631 are evaluated for FOTSMC, TSMC and PSS. The stability of the FCM is proved by Lyapunouv theory. Further analysis with sprung mass and speed variation of FCM demonstrate the robustness of proposed controller. To investigate the performances of designed controllers, comparison is made with existing Sliding Mode Controller (SMC) which proves that the designed FOTSMC performs better than existing SMC.

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基于分数阶终端滑模控制器的整车主动悬架系统振动控制及性能分析

引入主动悬架系统的主要目的是为了减少车辆在道路障碍物下的车身运动，从而提高乘客的乘坐舒适性。本文采用MATLAB/Simulink对具有7个自由度的整车模型(FCM)进行了仿真研究。终端滑模控制器(TSMC)和分数阶终端滑模控制器(FOTSMC)旨在提高FCM的乘坐质量、稳定性和乘客舒适度。所设计的FOTSMC能够在有限的时间内提供更高的控制精度。通过在碰撞输入和ISO-8608随机输入下对被动悬架系统进行车身角方向和垂直方向振动测量，评价了所设计控制器的性能。根据ISO-2631对FOTSMC、TSMC和PSS进行了频率加权均方根(FWRMS)和振动剂量值的评估。用李雅普诺夫理论证明了FCM的稳定性。进一步分析了FCM的簧载质量和速度变化，证明了该控制器的鲁棒性。为了研究所设计控制器的性能，与现有滑模控制器(SMC)进行了比较，证明所设计的FOTSMC比现有滑模控制器性能更好。

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来源期刊

Archives of Control Sciences Mathematics-Modeling and Simulation

CiteScore

2.40

自引率

33.30%

发文量

审稿时长

14 weeks

期刊介绍： Archives of Control Sciences welcomes for consideration papers on topics of significance in broadly understood control science and related areas, including: basic control theory, optimal control, optimization methods, control of complex systems, mathematical modeling of dynamic and control systems, expert and decision support systems and diverse methods of knowledge modelling and representing uncertainty (by stochastic, set-valued, fuzzy or rough set methods, etc.), robotics and flexible manufacturing systems. Related areas that are covered include information technology, parallel and distributed computations, neural networks and mathematical biomedicine, mathematical economics, applied game theory, financial engineering, business informatics and other similar fields.