Performance of the Machine Learning on Controlling the Pneumatic Suspension of Automobiles on the Rigid and Off-Road Surfaces

IF 0.5 Q4 TRANSPORTATION SCIENCE & TECHNOLOGY
Siping Xu, V. Nguyen, Shiming Li, Deng Ni
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引用次数: 2

Abstract

To enhance the ride comfort and control performance of the semi-active pneumatic suspension system (PSS) of automobiles on the different road surfaces, a machine learning method (MLM) developed on the optimal control rules of the fuzzy logic control is proposed for the semi-active PSS. A nonlinear dynamic model of the automobile with eight degrees of freedom (DOF) is established to compute the results. The root mean square (RMS) accelerations of the vertical driver’s seat and the pitching angle and rolling angle of the automobile are selected to evaluate the ride comfort of the automobile on the rigid road and off-road terrain surfaces. The research results show that the off-road terrain surfaces remarkably affect the ride comfort of the automobile, especially at a high moving speed range of the automobile over 17.5 m/s. The performance of the MLM in improving the ride comfort of the automobile is better than the fuzzy logic control under various simulation conditions. Particularly, the RMS accelerations of the vertical driver’s seat and the pitching angle and rolling angle of the automobile with the MLM are smaller than that of the fuzzy logic control by 14.6%, 9.6%, and 5.3% on the rigid road surfaces and reduced by 14.9%, 8.7%, and 9.8% on the soil terrain of off-road terrain surfaces, respectively. However, the research results also indicate that the performance of the MLM significantly depends on the data map of the learning process. Thus, to further enhance the performance of the MLM, the data map for the machine learning process should be expanded under different operating conditions of the automobile.
机器学习在刚性路面和越野路面上控制汽车气动悬架的性能
为了提高汽车半主动气动悬架系统(PSS)在不同路面上的平顺性和控制性能,提出了一种基于模糊逻辑控制最优控制规则的半主动PSS机器学习方法。建立了汽车八自由度的非线性动力学模型,对结果进行了计算。选择垂直驾驶员座椅的均方根加速度以及汽车的俯仰角和滚动角来评估汽车在刚性道路和越野地形表面上的乘坐舒适性。研究结果表明,越野地形表面对汽车的乘坐舒适性有显著影响,尤其是在汽车行驶速度超过17.5米/秒的情况下。在各种仿真条件下,MLM在提高汽车乘坐舒适性方面的性能优于模糊逻辑控制。特别是,在刚性路面上,采用MLM的垂直驾驶座的RMS加速度以及汽车的俯仰角和滚动角分别比模糊逻辑控制的RMS加速度小14.6%、9.6%和5.3%,在越野路面的土壤地形上分别降低14.9%、8.7%和9.8%。然而,研究结果也表明,传销的表现在很大程度上取决于学习过程的数据图。因此,为了进一步提高MLM的性能,应该在汽车的不同操作条件下扩展机器学习过程的数据图。
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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CiteScore
1.30
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