引用本文:魏瑞轩,倪天,赵晓林,张兴宇.认知无人机–环境系统的防碰撞稳定性[J].控制理论与应用,2019,36(9):1453~1460.[点击复制]
WEI Rui-xuan,NI Tian,ZHAO Xiao-lin,ZHANG Xing-yu.Collision avoidance stability of the cognitive unmanned aerial vehicle & environment system[J].Control Theory and Technology,2019,36(9):1453~1460.[点击复制]
认知无人机–环境系统的防碰撞稳定性
Collision avoidance stability of the cognitive unmanned aerial vehicle & environment system
摘要点击 2130  全文点击 922  投稿时间:2018-05-07  修订日期:2019-06-06
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DOI编号  10.7641/CTA.2019.80330
  2019,36(9):1453-1460
中文关键词  无人机  防碰撞稳定  脉冲微分包含  认知决策
英文关键词  unmanned aerial vehicle  collision avoidance stability  impulse differential inclusions  cognitive decision-making
基金项目  国家自然科学基金
作者单位E-mail
魏瑞轩 空军工程大学航空工程学院 1806987269@qq.com 
倪天* 部队 doctor_tian85822@qq.com 
赵晓林 空军工程大学 装备管理与无人机工程学院  
张兴宇 部队  
中文摘要
      借鉴人在复杂动态环境中的自主防碰撞行为, 可以构建具有认知防碰撞能力的无人机. 针对认知防碰撞决策的有效性问题, 将认知无人机与环境的动态交互过程作为整体, 通过分析认知无人机–环境系统状态的运动模式, 基于混合时间集建立了认知无人机–环境系统的脉冲微分包含(impulse differential inclusions, IDI)模型. 按照认知无人机防碰撞过程的IDI运行机理, 将系统状态空间划分为三类运行域, 建立了认知无人机–环境系统的防碰撞稳定性定义, 进而运用IDI理论, 导出了使认知无人机–环境系统防碰撞稳定的充要条件. 仿真实验结果表明, 导出的防碰撞稳定条件可以为无人机认知防碰撞决策的有效性提供依据.
英文摘要
      Benefited from autonomous collision avoidance behavior of human in some dynamic complex environment, it is possible to construct an unmanned aerial vehicle (UAV) with cognitive collision avoidance ability. For the validity problem of cognitive decision-making in collision avoidance, the dynamic interaction process between UAV and environment is considered integrally. By analyzing state running patterns of the cognitive unmanned aerial vehicle & environment system, the impulse differential inclusions (IDI) model of the cognitive unmanned aerial vehicle & environment system is established based on hybrid time trajectory. And the system state space is partitioned into three classes of running fields according to IDI running mechanism within cognitive UAV’s collision avoidance process, thus, the definition of collision avoidance stability for the cognitive unmanned aerial vehicle & environment system is established. Furthermore, the necessary and sufficient condition that guarantees the collision avoidance stability of the cognitive unmanned aerial vehicle & environment system is deduced by utilizing IDI theory. Finally, simulation experiment results verify that the proposed condition of collision avoidance stability can provide a basis for the validity of UAV’s cognitive decision-making in collision avoidance.