Stability Analysis of a Multirotor UAV with Robust Backstepping Controller

2014 Joint Conference on Robotics: SBR-LARS Robotics Symposium and Robocontrol Pub Date : 2014-10-18 DOI:10.1109/SBR.LARS.ROBOCONTROL.2014.24

A. Sanca, P. Alsina, Jés Jesus Fiais Cerqueira

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引用次数: 6

Abstract

In this paper, the stability analysis of an hexarotor micro-aerial vehicle for outdoor applications using IMU sensors is presented. The dynamic model of the hexarotor was expressed using the Newton-Euler laws jointly with a full state robust backstepping controller, not only when it is hovering, but also when it is taking-off, or landing, or flying to perform a task. The experimental hexarotor is equipped with an IMU/sonar sensors, which appropriately provides measurements of attitude and altitude. For the performance of the robust controller, sensors were modeled as real measurements with unknown bias and white noise. The bounded attitude/altitude controller were derived on the robust practical stability that deals with convergence and stability into a ball of the state space with non-null radius, under some assumptions. The Lyapunov analysis technique was used to prove the stability of the closed-loop system, compute bounds on control gains and guaranteeing desired bounds on attitude dynamics tracking errors in the presence of measurement disturbances.

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鲁棒反步控制器多旋翼无人机稳定性分析

本文介绍了一种采用IMU传感器的六旋翼户外微型飞行器的稳定性分析。利用牛顿-欧拉律和全状态鲁棒后步控制器对六旋翼机的动力学模型进行了表达，不仅包括悬停状态，还包括起飞、着陆和飞行执行任务时的动力学模型。实验六旋翼配备一个IMU/声纳传感器，适当地提供姿态和高度测量。为了提高鲁棒控制器的性能，将传感器建模为具有未知偏置和白噪声的实际测量值。在一定的假设条件下，基于鲁棒实用稳定性问题推导出有界姿态/高度控制器，该控制器处理非零半径状态空间球的收敛性和稳定性问题。利用李雅普诺夫分析技术证明了闭环系统的稳定性，计算了控制增益的边界，并保证了存在测量扰动时姿态动力学跟踪误差的期望边界。

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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2014 Joint Conference on Robotics: SBR-LARS Robotics Symposium and Robocontrol

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