Visualized neural network-based vibration control for pigeon-like flexible flapping wings.

Hejia Gao, Jinxiang Zhu, Changyin Sun, Zi-Ang Li, Qiuyang Peng
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Abstract

This study investigates pigeon-like flexible flapping wings, which are known for their low energy consumption, high flexibility, and lightweight design. However, such flexible flapping wing systems are prone to deformation and vibration during flight, leading to performance degradation. It is thus necessary to design a control method to effectively manage the vibration of flexible wings. This paper proposes an improved rigid finite element method (IRFE) to develop a dynamic visualization model of flexible flapping wings. Subsequently, an adaptive vibration controller was designed based on non-singular terminal sliding mode (NTSM) control and fuzzy neural network (FNN) in order to effectively solve the problems of system uncertainty and actuator failure. With the proposed control, stability of the closed loop system is achieved in the context of Lyapunov's stability theory. At last, a joint simulation using MapleSim and MATLAB/Simulink was conducted to verify the effectiveness and robustness of the proposed controller in terms of trajectory tracking and vibration suppression.The obtained results have demonstrated great practical value of the proposed method in both military (low-altitude reconnaissance, urban operations, and accurate delivery, etc.) and civil (field research, monitoring, and relief for disasters, etc.) applications.

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基于可视化神经网络的鸽类柔性拍翼振动控制。
本研究调查了类似鸽子的柔性拍翼,这种拍翼以低能耗、高柔性和轻质设计而著称。然而,这种柔性拍翼系统在飞行过程中容易变形和振动,导致性能下降。因此,有必要设计一种控制方法来有效控制柔性机翼的振动。本文提出了一种改进的刚性有限元方法(IRFE)来建立柔性拍翼的动态可视化模型。随后,设计了基于非奇异终端滑动模态(NTSM)控制和模糊神经网络(FNN)的自适应振动控制器,以有效解决系统不确定性和致动器失效问题。利用所提出的控制方法,闭环系统在 Lyapunov 稳定性理论的背景下实现了稳定。最后,使用 MapleSim 和 MATLAB/Simulink 进行了联合仿真,验证了所提控制器在轨迹跟踪和振动抑制方面的有效性和鲁棒性。
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