外部干扰和参数不确定条件下车辆队列横向控制：一种自适应DMPC方法

IF 7.1 2区计算机科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Vehicular Technology Pub Date : 2024-12-25 DOI:10.1109/TVT.2024.3519253

Panshuo Li;Zhixiang Weng;Kunsong Lin;Jing Zhao

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引用次数: 0

摘要

针对存在外部干扰和转弯刚度不确定的车辆队列，提出了一种基于估计量的分布式模型预测控制方法。利用基于路径的车辆跟随策略，建立了车辆排的横向动力学模型。然后提出了一种自适应参数估计器来估计转弯刚度。在此基础上，开发了分布式扰动反馈最小-最大模型预测控制器，以保证车辆排的横向扰动串稳定性，提高跟随车辆的路径跟踪性能和横向稳定性，同时防止执行器饱和。考虑到求解最小-最大优化所涉及的计算量较大，推导了基于线性矩阵不等式的条件，以方便控制器增益的求解。该方法能有效地解决大不确定区间内的转弯刚度问题，保证排柱在外界干扰下的横向稳定性。仿真结果验证了该方法在不同场景下的有效性。

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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Lateral Control of Vehicle Platoons Under External Disturbance and Parameter Uncertainty: An Adaptive DMPC Approach

This paper proposes an estimator-based distributed model predictive control (DMPC) approach for vehicle platoons in the presence of external disturbance and uncertain cornering stiffness. A lateral dynamics model of vehicle platoons is established by utilizing a path-based vehicle-following strategy. An adaptive parameter estimator is then proposed to estimate the cornering stiffness. Based on it, a distributed disturbance-feedback min-max model predictive controller is developed to ensure the lateral disturbance string stability of vehicle platoons, enhance path-following performance and lateral stability of following vehicles, and simultaneously prevent the actuator saturation. Considering the high computational burden involved in solving min-max optimization, the linear matrix inequalities-based conditions are derived to facilitate the controller gain solving. The proposed method can effectively tackle the cornering stiffness within large uncertain intervals and guarantee the lateral string stability of platoons under external disturbances. Simulation results validate the effectiveness of the proposed DMPC approach in different scenarios.

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来源期刊

IEEE Transactions on Vehicular Technology 工程技术-电信学

CiteScore

6.00

自引率

8.80%

发文量

1245

审稿时长

6.3 months

期刊介绍： The scope of the Transactions is threefold (which was approved by the IEEE Periodicals Committee in 1967) and is published on the journal website as follows: Communications: The use of mobile radio on land, sea, and air, including cellular radio, two-way radio, and one-way radio, with applications to dispatch and control vehicles, mobile radiotelephone, radio paging, and status monitoring and reporting. Related areas include spectrum usage, component radio equipment such as cavities and antennas, compute control for radio systems, digital modulation and transmission techniques, mobile radio circuit design, radio propagation for vehicular communications, effects of ignition noise and radio frequency interference, and consideration of the vehicle as part of the radio operating environment. Transportation Systems: The use of electronic technology for the control of ground transportation systems including, but not limited to, traffic aid systems; traffic control systems; automatic vehicle identification, location, and monitoring systems; automated transport systems, with single and multiple vehicle control; and moving walkways or people-movers. Vehicular Electronics: The use of electronic or electrical components and systems for control, propulsion, or auxiliary functions, including but not limited to, electronic controls for engineer, drive train, convenience, safety, and other vehicle systems; sensors, actuators, and microprocessors for onboard use; electronic fuel control systems; vehicle electrical components and systems collision avoidance systems; electromagnetic compatibility in the vehicle environment; and electric vehicles and controls.