Lyapunov‐Lasalle Based Dynamic Stabilization for Fixed Wing Drones

Q4 Engineering

Journal of Automation, Mobile Robotics and Intelligent Systems Pub Date : 2024-03-07 DOI:10.14313/jamris/4-2023/29

Jean Sawma, Alain Ajami, T. Maillot, Joseph El Maalouf

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引用次数: 0

Abstract

The market of Unmanned Aerial Vehicles (UAVs) for civil applications is extensively growing. Indeed, these airplanes are nowadays widely used in applications such as data gathering, agriculture monitoring and rescue. The UAVs are required to track a fixed or moving object, thus tracking control algorithms that ensure the system stability and that have a quick time response are developed. This paper tackles the problem of supervising a fixed target using a ϐixed wing UAV flying at a constant altitude and a constant speed. For that purpose, three control algorithms are developed. In all of the algorithms, the UAV is expected to hover around the target in a circular trajectory. Moreover, the three approaches are based upon a Lyapunov‑LaSalle stabilization method. The first tracking algorithm ensures the UAV to circle around the target however the path that the UAV will follow in order to join this pattern is not studied. In the second and third approach, two different techniques that allow the UAV to intercept its final circular pattern in the quickest possible time and thus follow the tangent to the circular pattern are presented. Simulation results that show and compare the performances of the proposed methods are presented.

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基于 Lyapunov-Lasalle 的固定翼无人机动态稳定技术

民用无人驾驶飞行器（UAV）市场正在广泛增长。事实上，这些飞行器如今已广泛应用于数据收集、农业监测和救援等领域。无人飞行器需要跟踪固定或移动物体，因此需要开发能确保系统稳定性和快速响应的跟踪控制算法。本文探讨了使用以恒定高度和恒定速度飞行的ϐ混合翼无人机监控固定目标的问题。为此，本文开发了三种控制算法。在所有算法中，无人飞行器都将以圆形轨迹围绕目标盘旋。此外，这三种方法都基于 Lyapunov-LaSalle 稳定方法。第一种跟踪算法确保无人飞行器围绕目标盘旋，但没有研究无人飞行器加入这一模式的路径。在第二种和第三种方法中，提出了两种不同的技术，使无人飞行器能够在最快的时间内截获其最终的圆形图案，从而沿着圆形图案的切线飞行。模拟结果显示并比较了所建议方法的性能。

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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来源期刊

Journal of Automation, Mobile Robotics and Intelligent Systems Engineering-Control and Systems Engineering

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Fundamentals of automation and robotics Applied automatics Mobile robots control Distributed systems Navigation Mechatronics systems in robotics Sensors and actuators Data transmission Biomechatronics Mobile computing