基于RRT*的碰撞风险感知无人机最优状态运动规划

IF 2 4区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS

Information Technology and Control Pub Date : 2023-09-26 DOI:10.5755/j01.itc.52.3.33583

Haolin Yin, Baoquan Li, Hai Zhu, Lintao Shi

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引用次数: 0

摘要

提出了一种考虑动态采样和视场的无人机自主导航策略。与基于搜索的运动规划相比，基于采样的运动规划方案往往能够在复杂的环境中找到可行的运动轨迹。具体而言，首先利用物理信息生成全局轨迹，并构造了一种基于动力学快速探索随机树* (KRRT*)的展开算法。然后，设计了KRRT*扩展策略来寻找局部无碰撞轨迹。在轨迹优化中，考虑了机载传感器的视场和潜在风险，定义了弯曲半径、碰撞风险函数和偏航角惩罚项。然后，在初始轨迹生成的基础上，对平滑可行项和动态可行项进行惩罚。通过时间重新分配细化轨迹，通过优化求解权值。仿真和实验验证了该策略的有效性。

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Kinodynamic RRT* Based UAV Optimal State Motion Planning with Collision Risk Awareness

In this paper, an autonomous navigation strategy is proposed for unmanned aerial vehicles (UAVs) based on consideration of dynamic sampling and field of view (FOV). Compare to search-based motion planning, sampling-based kinodynamic planning schemes can often find feasible trajectories in complex environments. Specifically, a global trajectory is first generated with physical information, and an expansion algorithm is constructed regarding to kinodynamic rapidly-exploring random tree* (KRRT*). Then, a KRRT* expansion strategy is designed to find local collision-free trajectories. In trajectory optimization, bending radius, collision risk function, and yaw angle penalty term are defined by taking into account onboard sensor FOV and potentialrisk. Then, smooth and dynamic feasible terms are penalized based on initial trajectory generation. Trajectories are refined by time reallocation, and weights are solved by optimization. Effectiveness of the proposed strategy is demonstrated by both simulation and experiment.

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来源期刊

Information Technology and Control 工程技术-计算机：人工智能

CiteScore

2.70

自引率

9.10%

发文量

审稿时长

12 months

期刊介绍： Periodical journal covers a wide field of computer science and control systems related problems including: -Software and hardware engineering; -Management systems engineering; -Information systems and databases; -Embedded systems; -Physical systems modelling and application; -Computer networks and cloud computing; -Data visualization; -Human-computer interface; -Computer graphics, visual analytics, and multimedia systems.