Vehicle Dynamics in Electric Cars Development Using MSC Adams and Artificial Neural Network

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC World Electric Vehicle Journal Pub Date : 2023-10-15 DOI:10.3390/wevj14100293

Santiago J. Cachumba-Suquillo, Mariel Alfaro-Ponce, Sergio G. Torres-Cedillo, Jacinto Cortés-Pérez, Moises Jimenez-Martinez

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Abstract

Recently, there has been renewed interest in lightweight structures; however, a small structure change can strongly affect vehicle dynamic behavior. Therefore, this study provides new insights into non-parametric modeling based on artificial neural networks (ANNs). This work is then motivated by the requirement for a reliable substitute for virtual instrumentation in electric car development to enable the prediction of the current value of the vehicle slip from a given time history of the vehicle (input) and previous values of synthetic data (feedback). The training data are generated from a multi-body simulation using MSC Adams Car; the simulation involves a double lane-change maneuver. This test is commonly used to evaluate vehicle stability. Based on dynamic considerations, this study implements the nonlinear autoregressive exogenous (NARX) identification scheme used in time-series modeling. This work presents an ANN that is able to predict the side slip angle from simulated training data generated employing MSC Adams Car. This work is a specific solution to overtake maneuvers, avoiding the loss of vehicle control and increasing driving safety.

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基于MSC Adams和人工神经网络的电动汽车动力学研究

最近，人们对轻量化结构重新产生了兴趣;然而，一个小的结构变化会强烈影响车辆的动力行为。因此，本研究为基于人工神经网络(ann)的非参数建模提供了新的见解。这项工作的动机是电动汽车开发中对虚拟仪器的可靠替代品的需求，以便能够根据车辆的给定时间历史(输入)和合成数据的先前值(反馈)预测车辆滑动的当前值。使用MSC Adams Car进行多体仿真生成训练数据;该模拟涉及双变道机动。该测试通常用于评估车辆的稳定性。基于动态考虑，本研究实现了用于时间序列建模的非线性自回归外生(NARX)识别方案。这项工作提出了一种能够从使用MSC Adams Car生成的模拟训练数据中预测侧滑角的人工神经网络。该工作是超车机动的具体解决方案，避免了车辆失控，提高了行车安全性。

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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