Finite-time event-triggered tracking control for quadcopter attitude systems with zero compensation technology

IF 1.8 Q3 AUTOMATION & CONTROL SYSTEMS IFAC Journal of Systems and Control Pub Date : 2024-11-02 DOI:10.1016/j.ifacsc.2024.100289

Lian Chen , Cui Cai , Xijun Liu , Chen Wang

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Abstract

This paper primarily investigates the event-triggered tracking control problem for quadcopter attitude systems, utilizing finite-time zero compensation technology. Unlike existing research results, a zero compensation technology is proposed to solve non-affine control input problems such as saturation, dead zones, and gaps. The command filtered compensation technology is used to solve ’differential explosion’ and filtering errors. A novel Tanh type filter and a neural network are employed to approximate virtual control signals and account for un-modeled dynamics, respectively. Moreover, the finite-time convergence theory is used to prove that the state, tracking error, and filtered error compensation signals in the entire closed-loop system converge to an arbitrarily small neighborhood of the equilibrium origin. Finally, the advantages of the proposed control algorithm in improving tracking accuracy and reducing communication load were demonstrated through simulation.

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采用零补偿技术的四旋翼飞行器姿态系统的有限时间事件触发跟踪控制

本文主要利用有限时间零补偿技术研究四旋翼飞行器姿态系统的事件触发跟踪控制问题。与现有研究成果不同的是，本文提出了一种零补偿技术来解决非线性控制输入问题，如饱和、死区和间隙。指令滤波补偿技术用于解决 "差分爆炸 "和滤波误差。新颖的 Tanh 型滤波器和神经网络分别用于逼近虚拟控制信号和考虑未建模的动态。此外，利用有限时间收敛理论证明了整个闭环系统中的状态、跟踪误差和滤波误差补偿信号都会收敛到平衡原点的任意小邻域。最后，通过仿真证明了所提出的控制算法在提高跟踪精度和减少通信负荷方面的优势。

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来源期刊

IFAC Journal of Systems and Control AUTOMATION & CONTROL SYSTEMS-

CiteScore

3.70

自引率

5.30%

发文量