基于机器学习和车辆动态模型融合的智能车辆质量估计方法

Zhuoping Yu, Xinchen Hou, Bo Leng, Yuyao Huang
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引用次数: 0

摘要

车辆质量是智能车辆运动控制的一个重要参数,但很难用普通传感器直接测量。因此,准确估计车辆质量变得至关重要。本文介绍了一种基于机器学习和车辆动态模型融合的车辆质量估计方法。在机器学习方法中,使用前馈神经网络(FFNN)来学习车辆质量与其他状态参数(即纵向速度和加速度、驱动或制动扭矩以及车轮角速度)之间的关系。在基于动力学的方法中,使用基于车辆动力学模型的带遗忘因子的递归最小二乘法(RLS)来估计车辆质量。根据每种方法在不同条件下的可靠性,这两种方法使用模糊逻辑进行了融合。在新欧洲行驶循环(NEDC)条件下进行了模拟测试。仿真结果表明,融合方法的估计精度约为 97%,与每种单一方法相比,融合方法具有更好的稳定性和鲁棒性。
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Mass estimation method for intelligent vehicles based on fusion of machine learning and vehicle dynamic model

Vehicle mass is an important parameter for motion control of intelligent vehicles, but is hard to directly measure using normal sensors. Therefore, accurate estimation of vehicle mass becomes crucial. In this paper, a vehicle mass estimation method based on fusion of machine learning and vehicle dynamic model is introduced. In machine learning method, a feedforward neural network (FFNN) is used to learn the relationship between vehicle mass and other state parameters, namely longitudinal speed and acceleration, driving or braking torque, and wheel angular speed. In dynamics-based method, recursive least square (RLS) with forgetting factor based on vehicle dynamic model is used to estimate the vehicle mass. According to the reliability of each method under different conditions, these two methods are fused using fuzzy logic. Simulation tests under New European Driving Cycle (NEDC) condition are carried out. The simulation results show that the estimation accuracy of the fusion method is around 97%, and that the fusion method performs better stability and robustness compared with each single method.

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