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基于执行器动力学补偿线性自抗扰控制器的双倾转旋翼无人机周期变距统一精确姿态控制

Unified Accurate Attitude Control for Dual-Tiltrotor UAV with Cyclic Pitch Using Actuator Dynamics Compensated LADRC.

作者信息

Wang Zexin, Wang Yingxun, Cai Zhihao, Zhao Jiang, Liu Ningjun, Zhao Yanqi

机构信息

School of Automation Science and Electrical Engineering, Beihang University, Beijing 100191, China.

Institute of Unmanned System, Beihang University, Beijing 100191, China.

出版信息

Sensors (Basel). 2022 Feb 17;22(4):1559. doi: 10.3390/s22041559.

DOI:10.3390/s22041559
PMID:35214458
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8877619/
Abstract

This paper proposes a unified attitude controller based on the modified linear active disturbance rejection control (LADRC) for a dual-tiltrotor unmanned aerial vehicle (UAV) with cyclic pitch to achieve accurate attitude control despite its nonlinear and time-varying characteristics during flight mode transitions. The proposed control algorithm has higher robustness against model mismatch compared with the model-based control algorithms. The modified LADRC utilizes the state feedbacks from the onboard sensors like IMU and Pitot tube instead of the mathematical model of the plane. It has less dependency on the accurate dynamics model of the dual-tiltrotor UAV, which can hardly be built. In contrast to the original LADRC, an actuator model is integrated into the modified LADRC to compensate for the non-negligible slow rotor flapping dynamics and servo dynamics. This modification eliminates the oscillation of the original LADRC when applied on the plant with slow-response actuators, such as propeller and rotors of the helicopter. In this way, the stability and performance of the controller are improved. The controller replaces the gain-scheduling or the control logic switching by a unified controller structure, which simplifies the design approach of the controller for different flight modes. The effectiveness of the modified LADRC and the performance of the unified attitude controller are demonstrated in both simulation and flight tests using a dual-tiltrotor UAV. The attitude control error is less than ±4° during the conversion flight. The control rising time in different flight modes is all about 0.5 s, despite the variations in the airspeed and tilt angle. The flight results show that the controller guarantees high control accuracy and uniform control quality in different flight modes.

摘要

本文针对一种具有周期变距的双倾转旋翼无人机,提出了一种基于改进线性自抗扰控制(LADRC)的统一姿态控制器,以在飞行模式转换过程中实现精确的姿态控制,尽管其具有非线性和时变特性。与基于模型的控制算法相比,所提出的控制算法对模型失配具有更高的鲁棒性。改进的LADRC利用来自机载传感器(如惯性测量单元和皮托管)的状态反馈,而不是飞机的数学模型。它对双倾转旋翼无人机精确动力学模型的依赖性较小,而精确动力学模型很难建立。与原始LADRC相比,改进的LADRC集成了一个执行器模型,以补偿不可忽略的慢旋翼挥舞动力学和伺服动力学。这种改进消除了原始LADRC应用于具有慢响应执行器(如直升机的螺旋桨和旋翼)的对象时的振荡。通过这种方式,提高了控制器的稳定性和性能。该控制器用统一的控制器结构取代了增益调度或控制逻辑切换,简化了针对不同飞行模式的控制器设计方法。使用双倾转旋翼无人机进行的仿真和飞行测试均证明了改进的LADRC的有效性和统一姿态控制器的性能。在转换飞行过程中,姿态控制误差小于±4°。尽管空速和倾斜角有所变化,但不同飞行模式下的控制上升时间均约为0.5 s。飞行结果表明,该控制器在不同飞行模式下保证了高控制精度和一致的控制质量。

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本文引用的文献

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Design, Analysis, and Testing of a Hybrid VTOL Tilt-Rotor UAV for Increased Endurance.混合动力垂直起降倾转旋翼无人机的设计、分析与测试,以提高续航能力。
Sensors (Basel). 2021 Sep 7;21(18):5987. doi: 10.3390/s21185987.
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Equivalence of LADRC and INDI controllers for improvement of LADRC in practical applications.在实际应用中用于改进自抗扰控制器(LADRC)的自抗扰控制器与积分分离式PID(INDI)控制器的等效性
ISA Trans. 2022 Jul;126:562-573. doi: 10.1016/j.isatra.2021.07.039. Epub 2021 Aug 3.
3
Modified active disturbance rejection control for time-delay systems.
时滞系统的改进型自抗扰控制
ISA Trans. 2014 Jul;53(4):882-8. doi: 10.1016/j.isatra.2013.09.013. Epub 2013 Oct 3.