引用本文:张思洁,吴怀宇,郑秀娟.具有执行器故障的四旋翼无人机有限时间容错控制[J].控制理论与应用,2023,40(7):1270~1276.[点击复制]
ZHANG Si-jie,WU Huai-yu,ZHENG Xiu-juan.Finite-time fault tolerant control of quadrotor UAV with actuator faults[J].Control Theory and Technology,2023,40(7):1270~1276.[点击复制]
具有执行器故障的四旋翼无人机有限时间容错控制
Finite-time fault tolerant control of quadrotor UAV with actuator faults
摘要点击 2454  全文点击 666  投稿时间:2022-03-11  修订日期:2023-05-19
查看全文  查看/发表评论  下载PDF阅读器
DOI编号  10.7641/CTA.2022.20173
  2023,40(7):1270-1276
中文关键词  容错控制  快速终端滑模控制  无人机  执行器故障
英文关键词  fault tolerant control  fast terminal sliding mode control  unmanned aerial vehicle  actuator faults
基金项目  国家自然科学基金项目(62073250, 62003249, 62173262)资助.
作者单位E-mail
张思洁 武汉科技大学 zhangsijie125@163.com 
吴怀宇 武汉科技大学  
郑秀娟* 武汉科技大学 zhengxj@wust.edu.cn 
中文摘要
      本文主要研究了四旋翼无人机在外部干扰、执行器存在部分失效和偏置故障并发情况下有限时间轨迹跟踪的控制问题. 通过分析四旋翼无人机动力学特性, 构建了带有外部干扰、执行器机构故障的动力学模型. 基于鲁棒全局快速终端滑模控制算法, 设计了一种有限时间容错控制器, 提高了系统对故障的响应速度. 其次, 针对常值/时变故障和干扰,在控制器设计中采用改进的连续函数进行补偿, 减少了由切换函数引起的系统抖振, 并基于Lyapunov函数对控制器的稳定性进行了分析. 最后, 通过仿真实验验证了所设计控制器的有效性和可靠性, 同时存在执行器故障和外部干扰的情况下, 无人机能够实现较好的轨迹跟踪性能.
英文摘要
      This article focused on the control problem of finite-time trajectory tracking of quadrotor UAV in the case of external interferences, and both partial and bias fault of actuators. By analyzing the dynamic characteristics of quadrotor UAV, the dynamic model with external interferences and actuator faults is constructed. Based on the robust global fast terminal sliding mode control algorithm, a finite-time fault-tolerant controller is designed to improve the response speed of the system to the fault. Secondly, for constant / time-varying faults and disturbances, the improved continuous function is used for compensation in the controller design, which reduces the problem of the system chattering caused by switching function, and the stability of the controller is analyzed based on Lyapunov function. Finally, the effectiveness and reliability of the designed controller are verified by simulation experiments, and the UAV can achieve better trajectory tracking performance under the condition of actuator failures and external interferences.