Sliding Mode Control for the hovering flight of a Tilt tri-rotor UAV

2022 11th International Conference on Control, Automation and Information Sciences (ICCAIS) Pub Date : 2022-11-21 DOI:10.1109/ICCAIS56082.2022.9990488

Le Thi Tuyet Nhung, Vu Dinh Quy, Nguyen Quang Hung, Pham Xuan Tung

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Abstract

The hover, transition, and fixed-wing modes are the three flight configurations available for the tilt tri-rotor unmanned aerial vehicle (UAV). . PID and SMC controllers were commonly used to build flight controllers to help realize stable flight for this UAV. The PID control method has the ability to adjust the error as low as possible, increase the response speed, reduce the overshoot, and limit the oscillation. The outstanding advantage of the sliding controller is its stability and stability even when the system has noise or when the object's parameters change over time. This paper will build flight control including attitude control, and position control for the Tilt tri-rotor model in hover mode based on PID control and SMC to evaluate their performance. First, the kinematic equations of Tilt tri-rotor UAV are built based on coordinate systems and Newton's laws. Secondly, two control diagrams and built two flight controllers based on PID and SMC control methods are investigated. Finally, the simulation results of these two methods are shown and discussed. The results show that the SMC controllers give better stability and better orbital tracking in both cases of noise and no noise.

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倾斜三旋翼无人机悬停飞行的滑模控制

悬停、过渡和固定翼模式是倾斜三旋翼无人机可采用的三种飞行构型。为了实现该无人机的稳定飞行，通常采用PID控制器和SMC控制器来构建飞行控制器。PID控制方法具有调节误差尽可能低，提高响应速度，减少超调，限制振荡的能力。滑动控制器的突出优点是即使在系统存在噪声或对象参数随时间变化时，其稳定性和稳定性。本文将基于PID控制和SMC控制对悬停模式下的倾斜三旋翼模型建立包括姿态控制和位置控制的飞行控制，并对其性能进行评价。首先，基于坐标系和牛顿定律建立了倾斜三旋翼无人机的运动学方程。其次，研究了基于PID和SMC控制方法的两个控制图，并建立了两个飞行控制器。最后给出了两种方法的仿真结果并进行了讨论。结果表明，在有噪声和无噪声情况下，SMC控制器都具有较好的稳定性和轨道跟踪性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 11th International Conference on Control, Automation and Information Sciences (ICCAIS)

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