基于张量积建模的全轮独立转向车辆横向运动控制

doi:10.3901/JME.260279

机械工程学报 ›› 2026, Vol. 62 ›› Issue (8): 285-297.doi: 10.3901/JME.260279

• 特邀专辑：汽车线控底盘 • 上一篇下一篇

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基于张量积建模的全轮独立转向车辆横向运动控制

万航, 聂士达, 张猗淼, 刘辉, 张晨, 项昌乐

北京理工大学机械与车辆学院北京 100081

收稿日期:2025-07-20 修回日期:2025-11-20 出版日期:2026-04-20 发布日期:2026-06-12
作者简介:万航,男,1995年出生,博士研究生。主要研究方向为无人驾驶车辆运动规划与控制。E-mail:stefanwan@bit.edu.cn;聂士达,男,1990年出生,博士,特别副研究员。主要研究方向为自动驾驶、车辆动力学控制和车辆仿真技术。E-mail:nieshida@bit.edu.cn
基金资助:
国家自然科学基金资助项目(52394262,52472445)。

Tensor Product Model based Lateral Motion Control for FWIS Vehicles

WAN Hang, NIE Shida, ZHANG Yimiao, LIU Hui, ZHANG Chen, XIANG Changle

School of Mechanical and Engineering, Beijing Institute of Technology, Beijing 100081

Received:2025-07-20 Revised:2025-11-20 Online:2026-04-20 Published:2026-06-12

摘要/Abstract

摘要： 模块化车辆取消轮间机械约束，全轮独立转向极大地提升底盘运动的灵活性。然而，弯道工况下全轮转向动态独立，各轮垂向载荷呈现出时变性差异，为控制器的设计带来挑战。针对现有LPV建模对调度参数选择存在约束、系统凸包表达较为保守以及缺乏统一的严凸包构建等问题，基于张量积建模(Tensor product model,TP model)提出一种针对全轮独立转向车辆的线性变参数(Linear parameter varying,LPV)建模方法，可以有效地缩减调度参数的维度，保证凸包构建的严格性。张量积模型可以运用高阶奇异值分解(Higher order singular value decomposition,HOSVD)对原时变系统筛选凸包顶点并构建系统严凸包表达，得到基于TP建模的多胞形LPV模型(TP model based polytopic LPV,TP-PLPV)。利用并行分布式补偿控制框架(Parallel distributed compensation,PDC)设计鲁棒增益调度控制器解决弯道工况下不同纵向车速以及各轮垂向载荷的时变造成的轨迹跟踪精度降低的问题。同时，在轨迹跟踪模型推导中，利用车辆的质心侧偏角对控制器的参考航向角进行修正，推导了基于质心侧偏角修正的鲁棒控制策略(Robust TP-PLPV controller with side slip compensation,RLPV-SC)，使得轨迹跟踪控制系统的精度得到进一步提升，最终，通过Carsim-Simulink联合仿真实验，验证了所提控制算法的有效性。

关键词: 张量积建模, 高阶奇异值分解, 全轮独立转向车辆, 轨迹跟踪控制

Abstract: Modular vehicles eliminate mechanical constraints between wheels and achieve independent steering of all wheels, greatly enhancing the flexibility of chassis control. However, under curved conditions, each steering wheel is dynamically independent, and the vertical loads of each wheel exhibit time-varying differences, posing challenges for the design of the controller. This paper proposes a linear parameter varying(LPV) modeling method for full wheels independent steering vehicles based on tensor product model(TP model) to address the problems of constraints on scheduling parameter selection, conservatism of system convex hull, and lack of unified tight convex hull construction. The TP model can use higher-order singular value decomposition(HOSVD) to select vertices of the convex hull for the original time-varying system and construct a tight convex hull of the system, resulting in a polytopic LPV(PLPV) model. A robust gain scheduling controller is designed by the parallel distributed compensation(PDC) framework to solve the problem of trajectory tracking caused by different speeds and time-varying vertical loads on each wheel. At the same time, in the derivation of the trajectory tracking model, the reference heading angle of the controller is corrected using the vehicle's side-slip angle, and a robust controller with side slip compensation(RLPV-SC) is derived, which further improves the accuracy of the trajectory tracking. Finally, the effectiveness of the proposed control algorithm is verified through Carsim-Simulink simulation.

Key words: TP model, HOSVD, FWIS, trajectory tracking

中图分类号:

U469

万航, 聂士达, 张猗淼, 刘辉, 张晨, 项昌乐. 基于张量积建模的全轮独立转向车辆横向运动控制[J]. 机械工程学报, 2026, 62(8): 285-297.

WAN Hang, NIE Shida, ZHANG Yimiao, LIU Hui, ZHANG Chen, XIANG Changle. Tensor Product Model based Lateral Motion Control for FWIS Vehicles[J]. Journal of Mechanical Engineering, 2026, 62(8): 285-297.

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基于张量积建模的全轮独立转向车辆横向运动控制

Tensor Product Model based Lateral Motion Control for FWIS Vehicles

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