Performance of semi-active cab suspension system with different control methods

Journal of Mechatronics and Artificial Intelligence in Engineering Pub Date : 2023-01-20 DOI:10.21595/jmai.2022.23019

Shicheng Ni, V. Nguyen

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Abstract

In this study, based on adaptive control methods, the semi-active suspension system of the heavy truck cab is researched and controlled to improve the ride comfort of the heavy truck. A dynamic model of the vehicle is established for simulation. Matlab/Simulink software is used to simulate and calculate the root mean square (RMS) accelerations of the driver’s seat and cab pitch angle under different operation conditions. Proportional-integral-derivate controller with its parameters optimized by the genetic algorithm (GA-PID controller) and Fuzzy logic control combined with PID (FLC-PID controller) are used to control the semi-active cab suspension system of the heavy truck. The obtained results show that the ride comfort of the vehicle using FLC-PID is better improved in comparison with using GA-PID under different operating conditions. Especially, when the vehicle moves at a speed of 72 km/h, the RMS accelerations of the driver's seat and cab pitch angle are greatly reduced by 26.45 % and 26.07 % respectively. Therefore, the FLC-PID control should be applied to the suspension system of the vehicles to improve the vehicle's ride comfort.

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半主动驾驶室悬架系统在不同控制方式下的性能

本文基于自适应控制方法，对重型载货汽车驾驶室半主动悬架系统进行了研究和控制，以提高重型载货汽车的乘坐舒适性。建立了车辆的动力学模型进行仿真。利用Matlab/Simulink软件对不同工况下驾驶员座椅和驾驶室俯仰角加速度的均方根(RMS)进行仿真计算。采用遗传算法优化参数的比例-积分-导数控制器(GA-PID控制器)和模糊PID结合控制(FLC-PID控制器)对重型卡车驾驶室半主动悬架系统进行控制。结果表明，在不同工况下，采用FLC-PID与采用GA-PID相比，车辆的平顺性得到了更好的改善。特别是当车辆以72 km/h的速度行驶时，驾驶员座椅和驾驶室俯仰角的均方根加速度分别大大降低了26.45%和26.07%。因此，应将FLC-PID控制应用于车辆的悬架系统，以提高车辆的平顺性。

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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Journal of Mechatronics and Artificial Intelligence in Engineering

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