Hierarchical Nonlinear Moving Horizon Estimation of Vehicle Lateral Speed and Road Friction Coefficient

ASME Letters in Dynamic Systems and Control Pub Date : 2019-10-08 DOI:10.1115/dscc2019-9069

C. Jin, A. Maitland, J. McPhee

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引用次数: 1

Abstract

In this paper, we address nonlinear moving horizon estimation (NMHE) of vehicle lateral speed, as well as the road friction coefficient, using measured signals from sensors common to modern series-production automobiles. Due to nonlinear vehicle dynamics, a standard nonlinear moving horizon formulation leads to non-convex optimization problems, and numerical optimization algorithms can be trapped in undesirable local minima, leading to incorrect solutions. To address the challenge of non-convex cost functions, we propose an estimator with a two-level hierarchy. At the high level, a grid search combined with numerical optimization aims to find reference estimates that are sufficiently close to the global optimum. The reference estimates are refined at the low level leading to high-precision solutions. Our algorithm ensures that the estimates converge to the true values for the nominal model without the need for accurate initialization. Our design is tested in simulation with both the nominal model as well as a high-fidelity model of Autonomoose, the self-driving car of the University of Waterloo.

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车辆横向速度和道路摩擦系数的层次非线性运动水平估计

在本文中，我们解决非线性移动地平线估计(NMHE)的车辆横向速度，以及道路摩擦系数，使用测量信号从传感器常见的现代量产汽车。由于车辆动力学的非线性，标准的非线性运动视界公式会导致非凸优化问题，而数值优化算法可能会陷入不理想的局部极小值，从而导致不正确的解。为了解决非凸代价函数的挑战，我们提出了一个具有两层层次结构的估计器。在高层次上，网格搜索与数值优化相结合，旨在找到足够接近全局最优的参考估计。参考估计在低水平上进行了细化，从而得到高精度的解决方案。我们的算法保证了在不需要精确初始化的情况下，估计收敛于名义模型的真实值。我们的设计在模拟中测试了标称模型以及滑铁卢大学的自动驾驶汽车autonomose的高保真模型。

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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ASME Letters in Dynamic Systems and Control

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