基于反馈线性化和模糊T-S的四轴飞行器自主垂直起降设计

2017 International Conference on Control, Electronics, Renewable Energy and Communications (ICCREC) Pub Date : 2017-09-01 DOI:10.1109/ICCEREC.2017.8226705

N. H. Chalidia, M. Nuh, E. Rusdhianto

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引用次数: 3

摘要

四轴飞行器是一种无人驾驶飞行器，经常被用来模拟飞行机器人。它的四个螺旋桨让四轴飞行器在旋转和平移中移动。旋转和平移系统都是不稳定的，在数学上是非线性的。这两个运动系统可以单独控制。在本文中，我们提出了一个自主垂直起降(VTOL)四轴飞行器使用两个控制器;每个代表一个运动系统。在旋转中，稳定时间是一个关键问题，因此采用输入状态反馈线性化来调节/稳定四轴飞行器。在转译中，跟踪误差必须接近于零。模糊高木Sugeno在翻译中用于控制四轴飞行器。模糊Takagi-Sugeno是线性控制器利用其所谓的并行分布式补偿来处理非线性系统的一种真正的方法。对四轴飞行器的非线性模型进行了线性化处理，并在一些操作点上进行了控制;因此，我们有一些线性模型和一些线性控制器。然后，利用模糊系统来决定哪个控制器工作。本文所采用的线性控制器具有H∞的抗干扰性能。所有项都以线性矩阵不等式(LMI)的形式表示，以便于求出适当的增益。利用MATLAB对算法进行了仿真。结果表明，所提出的控制器能够将四轴飞行器稳定在0度位置，实现滚转、俯仰和偏航，并跟踪给定的参考信号。由于具有H∞性能，有界扰动可以被衰减。

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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Autonomous VTOL design in quadcopter using feedback linearization and fuzzy T-S

Quadcopter is an unmanned aerial vehicle that is frequently used to model flying robot. Its four propellers let quadcopter move in rotation and in translation. Both rotation and translation systems are unstable and mathematically nonlinear. These 2 motion systems could be controlled separately. In this paper, we propose an autonomous vertical take-off and landing (VTOL) quadcopter using two controllers; each for one motion system. In rotation, settling time is critical issue, so that input-state feedback linearization is used to regulate/stabilize quadcopter. In translation, tracking error must be near to zero. Fuzzy Takagi Sugeno is used to control quadcopter in translation. Fuzzy Takagi-Sugeno is a genuine way to handle nonlinear system by linear controller using its so-called parallel distributed compensation. The nonlinear model of quadcopter is linearized and controlled at some operating points; Thus, we have some linear models and some linear controllers. Then, fuzzy system is utilized to decide which controller to work. The linear controller used in this paper has H infinity performance to attenuate disturbance. All terms are formulated in the form of linear matrix inequality (LMI) to find the appropriate gain with ease. The algorithms have been simulated with the help of MATLAB. The results show that the proposed controllers are able to stabilize quadcopter in 0 degrees' position for roll, pitch, and yaw as well as to track the given reference signal. Bounded disturbance can be attenuated thanks to H infinity performance.

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2017 International Conference on Control, Electronics, Renewable Energy and Communications (ICCREC)

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