Serret-Frenet Frame-based Path Tracking Stabilization of a Powered Paraglider Type UAV with Input Constraints

2021 International Conference on Fuzzy Theory and Its Applications (iFUZZY) Pub Date : 2021-10-05 DOI:10.1109/iFUZZY53132.2021.9605085

Yutoku Takahashi, Kai-Yi Wong, Motoyasu Tanaka, Kazuo Tanaka

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引用次数: 1

Abstract

This paper presents a practical Serret-Frenet frame-based path tracking control approach for a powered paraglider (PPG) type unmanned aerial vehicle (UAV) with input constraints. In this paper, two new attempts are achieved from real UAV control points of view. The first attempt is to consider a real control input constraint but not the kinematic model input constraint that is considered in most cases. This paper realizes it by investigating the relationship between the yaw angular velocity in a kinematics model and the steering angle of the real direction bar. The second attempt is to describe the PPG model considering the above relationship by a new type of T-S fuzzy models with a residual term and to propose a new type of fuzzy controllers with a cancellation term for the residual term. By the cancellation via the T-S fuzzy controller, the overall feedback system is reduced to the ordinary T-S fuzzy control system. As a result, we simply apply an LMI-based design framework to the T-S fuzzy model with the residual term. Finally, this paper demonstrates the utility of the proposed approach through flight control simulations for complicated paths.

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带输入约束的动力滑翔伞型无人机基于Serret-Frenet帧的路径跟踪稳定

针对动力滑翔伞(PPG)型无人机，提出了一种具有输入约束的基于Serret-Frenet框架的路径跟踪控制方法。本文从实际无人机控制的角度进行了两种新的尝试。第一个尝试是考虑一个真实的控制输入约束，而不是在大多数情况下考虑的运动学模型输入约束。本文通过研究运动学模型中横摆角速度与实际方向杆转向角之间的关系来实现。第二次尝试用一种带有残差项的新型T-S模糊模型来描述考虑上述关系的PPG模型，并提出一种带有残差项抵消项的新型模糊控制器。通过T-S模糊控制器的对消，将整个反馈系统简化为普通的T-S模糊控制系统。因此，我们简单地将基于lmi的设计框架应用于带有残差项的T-S模糊模型。最后，通过对复杂路径的飞行控制仿真验证了所提方法的实用性。

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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2021 International Conference on Fuzzy Theory and Its Applications (iFUZZY)

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