Finite-Time Control of Wing-Rock Motion for Delta Wing Aircraft Based on Whale-Optimization Algorithm

Q1 Earth and Planetary Sciences

Indonesian Journal of Science and Technology Pub Date : 2021-08-21 DOI:10.17509/ijost.v6i3.37922

Arif A. Al-Qassar, A. Al-Obaidi, Alaq F. Hasan, Amjad J. Humaidi, A. R. Nasser, A. Alkhayyat, I. Ibraheem

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引用次数: 14

Abstract

The rise of wing-rock motion in delta-wing aircraft has an adverse effect on the manoeuvrability of aircraft and it may result in its crash. This study presents a finite-time control design to tackle the dynamic motion due to the Wing-Rock effect in delta-wing aircraft. The control design is developed based on the methodology of Super Twisting Sliding Mode Control (STSMC). The Lyapunov stability analysis has been pursued to ensure asymptotic convergence of errors and to determine the finite time. The design of STSMC leads to the appearance of design parameters, which have a direct impact on the dynamic performance of the controlled system. To avoid the conventional tuning of these parameters and to have an optimal performance of the proposed controller, a modern optimization technique has been proposed based on Wale Optimization Algorithm. A comparison study between optimal and non-optimal finite-time super twisting sliding mode controllers has been established and their effectiveness has been verified via numerical simulation using MATLAB programming format.

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基于鲸鱼优化算法的三角翼飞机翼岩运动有限时间控制

三角翼飞机翼岩运动的增大对飞机的机动性产生不利影响，有可能导致飞机坠毁。针对三角翼飞机翼岩效应引起的动态运动，提出了一种有限时间控制设计。基于超扭滑模控制(STSMC)方法进行了控制设计。为了保证误差的渐近收敛和确定有限时间，采用了李雅普诺夫稳定性分析。STSMC的设计导致了设计参数的出现，这些参数直接影响被控系统的动态性能。为了避免这些参数的常规调谐，并使所提出的控制器具有最优的性能，提出了一种基于Wale优化算法的现代优化技术。建立了最优和非最优有限时间超扭滑模控制器的对比研究，并利用MATLAB编程格式通过数值仿真验证了其有效性。

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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