Dynamic Responses of 8-DoF Vehicle with Active Suspension: Fuzzy-PID Control

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC World Electric Vehicle Journal Pub Date : 2023-09-06 DOI:10.3390/wevj14090249
Zongjun Yin, Rong Su, Xuegang Ma
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引用次数: 1

Abstract

The driving smoothness of vehicles is heavily influenced by their suspension system, and implementing active suspension control can effectively minimize the vibration movement of the vehicle and ensure a comfortable driving experience. An 8-DoF active suspension model of the full vehicle is established, and a fuzzy-PID controller is designed to autonomously regulate the parameters of the PID controller. Using the MATLAB/Simulink environment, a simulation model for suspension is created, and the vibration characteristics of passive, PID control, and fuzzy-PID control suspensions are compared with the help of the continuous crossing road hump model and C-level road model as road inputs. The results show that the utilization of fuzzy-PID control considerably diminishes the vertical, pitch, and roll oscillations of the suspension body and modifies the suspension dynamic deflection and tire dynamic load in contrast to the other two scenarios, thus enhancing ride comfort. Fuzzy-PID control led to a decrease of approximately 40% in acceleration, 25% in suspension workspace, and 30% in tire deflection compared to passive suspension. In addition, the reduction in acceleration is about 20%, the reduction in suspension workspace is approximately 10%, and the reduction in tire deflection is about 15% compared to the PID control suspension system.
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主动悬架8-DoF车辆的动态响应:模糊PID控制
车辆的行驶平顺性在很大程度上受到悬架系统的影响,实施主动悬架控制可以有效地减少车辆的振动运动,确保舒适的驾驶体验。建立了整车的8-DoF主动悬架模型,并设计了模糊PID控制器来自主调节PID控制器的参数。利用MATLAB/Simulink环境,建立了悬架仿真模型,并以连续跨越驼峰模型和C级道路模型为道路输入,比较了被动、PID控制和模糊PID控制悬架的振动特性。结果表明,与其他两种情况相比,模糊PID控制的使用显著减少了悬架车身的垂直、纵摇和侧倾振荡,并改变了悬架动态偏转和轮胎动态载荷,从而提高了乘坐舒适性。与被动悬架相比,模糊PID控制使加速度下降了约40%,悬架工作空间下降了25%,轮胎偏转下降了30%。此外,与PID控制悬架系统相比,加速度减小约20%,悬架工作空间减小约10%,轮胎偏转减小约15%。
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来源期刊
World Electric Vehicle Journal
World Electric Vehicle Journal Engineering-Automotive Engineering
CiteScore
4.50
自引率
8.70%
发文量
196
审稿时长
8 weeks
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