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Dynamic Reconfigurable Adaptive UGV Formation System
- Acta Armamentarii Vol. 45, Issue 10, Pages: 3654-3673(2024)
- 作者机构:
1. 中兵智能创新研究院有限公司 群体协同与自主实验室, 北京 100072
2. 北京理工大学 机械与车辆学院, 北京 100081
- 作者简介:
- 基金信息:
DOI:10.12382/bgxb.2023.0879
CLC:Received:06 September 2023,
Published Online:30 October 2024,
Published:31 October 2024
- 稿件说明:
移动端阅览
Yifei JIA, Chaoyang JIANG. Dynamic Reconfigurable Adaptive UGV Formation System[J]. Acta Armamentarii, 2024, 45(10): 3654-3673.
Yifei JIA, Chaoyang JIANG. Dynamic Reconfigurable Adaptive UGV Formation System[J]. Acta Armamentarii, 2024, 45(10): 3654-3673. DOI: 10.12382/bgxb.2023.0879.
摘要
为研究无人车编队系统的编队保持、队形重构及队形变换功能
提出一种混合式领航跟随策略
以降低对领航车的依赖并确保编队完整性。开发基于车间(Vehicle to Vehicle
V2V)通信的跟随车独立避障功能
并设计了实时管理编队成员属性并支持人机交互的编队节点管理系统。提出一种三维空间下的三次样条曲线动态扩展轨迹规划方法
结合V2V通信获取前车位姿信息生成跟随轨迹并实现避障。利用Frenet坐标系解耦车距保持与轨迹跟踪问题
采用PID控制器和线性二次调节(Linear Quadratic Regulator
LQR)控制器分别进行纵向控制和横向轨迹跟踪。研究结果表明:所搭建的仿真环境可快速验证方法性能
显示该方法具有良好的性能;通过实车验证了车辆编队系统的3种功能
通过车距稳定保持
证实所提方法具备良好实时性
能够实现多车编队的有效跟随
通过多种队形的变换以及成员入队离队场景
显示出高度的智能拓展性和适应性。
Abstract
The formation keeping
reconfiguration and transformation functions of unmanned ground vehicle (UGV) formation systems are studied A hybrid leader-follower strategy is proposed to reduce the dependence on the leading vehicle and ensure the formation integrity. An independent obstacle avoidance function based on vehicle-to-vehicle (V2V) communication for the following vehicles is developed
and a formation node management system is designed manages the attributes of formation members in real time and supports the human-computer interaction. A dynamic extended trajectory planning method with cubic spline curve in three-dimensional space is proposed to generate the following trajectory and realize the obstacle avoidance by acquiring the position information of the front vehicle through V2V communication. The Frenet coordinate system is utilized to decouple the distance keeping and trajectory tracking problems
and the proportional-integral-differential (PID) controller and linear quadratic regulator (LQR) controller are used for longitudinal control and lateral trajectory tracking
respectively. The research results show that the performance of the proposed method can be quickly verifued in the simulation environment built
showing that the method has good performance. And the three functions of the vehicle formation system are verified by real vehicles
and the proposed method is confirmed to have good real-time performance through the stable maintenance of the distance between the vehicles
which is capable of realizing the effective following of the multi-vehicle formation
and shows a high degree of intelligent expansion and adaptability through the transformation of multiple formation shapes as well as the scenarios of members’ joinning and departuring from the vehicle formation.
关键词
Keywords
references
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