基于滑模控制的四轮驱动轮内电机电动汽车稳定性控制

2015 Sixth International Conference on Intelligent Control and Information Processing (ICICIP) Pub Date : 2015-11-01 DOI:10.1109/ICICIP.2015.7388178

Chuanxue Song, F. Xiao, Shixin Song, Shaokun Li, Jianhua Li

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引用次数: 10

摘要

直接偏航力矩控制可以在危急情况下保持车辆的稳定性。对于四轮独立驱动(4WD)电动汽车，采用轮内电机(IWMs)，可以轻松实现直接偏航力矩控制(DYC)。相当准确地计算所需的偏航力矩可以提高车辆的稳定性。运动控制采用了一种新颖的滑模控制(SMC)技术，以跟踪期望的车辆运动，与传统的DYC相比，它适用于不同的工作环境。下控制器通过加权最小二乘算法，根据期望的偏航力矩确定分配给各车轮的转矩。在控制策略中考虑了多个执行器约束。此外，利用非线性轮胎模型提高了轮胎侧向力估计的精度。然后进行仿真，比较车辆状态值。仿真结果表明，所提出的控制系统能有效地提高车辆的操纵稳定性。

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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Stability control of 4WD electric vehicle with in-wheel-motors based on sliding mode control

Direct yaw moment control can maintain the vehicle stability in critical situation. For four-wheel independently driven (4WD) electric vehicle with in-wheel motors (IWMs), direct yaw moment control (DYC) can be easily achieved. A fairly accurate calculation of the required yaw moment can improve vehicle stability. A novel sliding mode control (SMC) technique is employed for the motion control so as to track the desired vehicle motion, which is it for different working circumstances compared to the well-used traditional DYC. Through the weighted least square algorithm, the lower controller is used to determine the torque properly allocated to each wheel according to the desired yaw moment. Several actuator constraints are considered in the control strategy. In addition, a nonlinear tire model is utilized to improve the accuracy of tire lateral force estimation. Then, simulations are carried out and the values of vehicle states are compared. The simulation results show that the control system proposed can effectively improve the handling stability of the vehicle.

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来源期刊

2015 Sixth International Conference on Intelligent Control and Information Processing (ICICIP)

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