Robust Position and Velocity Tracking Control of a Four-wheel Drive and Four-wheel Steered Electric Vehicle

2020 6th International Conference on Control, Automation and Robotics (ICCAR) Pub Date : 2020-04-01 DOI:10.1109/ICCAR49639.2020.9108078

M. Schwartz, Thomas Rudolf, S. Hohmann

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引用次数: 3

Abstract

The scope of this paper is the design and evaluation of a robust position and velocity tracking control of a four-wheel drive and four-wheel steered electric vehicle (4WD4WS EV). In an autonomous setup, an $\mathcal{H}_{\infty}$-controller based on the normalized coprime factor synthesis followed by a flat velocity control with an asymptotic stable tracking error is designed. Optimized force control allocation (CA) is supported by state of the art methods enhanced with the Redistributed Pseudoinverse (RPI) algorithm leading to a robust force distribution in case of actuator failure. The presented methods are applied to a continuous maneuver sequence covering parking as well as the double lane change and the weave test. Realistic and nonlinear disturbances on the steering and drive are considered. Therefore, a high gain observer coupled with SISO-control for each wheel supplements the cascaded control architecture. The results, considering measurement noise of the considered sensors, are discussed. For the given context, such a comprehensive controller structure has not been proposed or studied sufficiently.

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四轮驱动和四轮转向电动汽车的鲁棒位置和速度跟踪控制

本文的研究范围是四轮驱动和四轮转向电动汽车(4WD4WS EV)的鲁棒位置和速度跟踪控制的设计和评估。在自主设置中，设计了基于归一化协素数因子合成的$\mathcal{H}_{\infty}$ -控制器，然后设计了具有渐近稳定跟踪误差的平坦速度控制。优化的力控制分配(CA)由最先进的方法支持，并辅以再分布伪逆(RPI)算法，从而在执行器失效时实现鲁棒的力分配。将该方法应用于包括停车、双变道和编织试验在内的连续机动序列。考虑了转向和驱动系统的实际和非线性扰动。因此，每个车轮的高增益观测器与siso控制相结合，补充了级联控制体系结构。讨论了考虑所考虑传感器测量噪声的结果。对于给定的环境，这样一个全面的控制器结构还没有被提出或充分研究。

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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2020 6th International Conference on Control, Automation and Robotics (ICCAR)

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