Robust pose tracking control for a fully-actuated hexarotor UAV based on Gaussian processes

SICE journal of control, measurement, and system integration Pub Date : 2022-06-16 DOI:10.1080/18824889.2022.2125242

Tatsuya Ibuki, Hirotoshi Yoshioka, M. Sampei

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Abstract

This paper presents a robust position/attitude tracking control method for a fully-actuated hexarotor unmanned aerial vehicle (UAV) based on Gaussian processes. Multirotor UAVs suffer from modelling errors due to their structure complexity and aerodynamical disturbances whose perfect mathematical formulation is intractable. To handle this issue, this paper incorporates a data-based learning technique with model-based control. The hexarotor UAV dynamical model, considering modelling errors and aerodynamic disturbances as unknown dynamics, is first derived. Gaussian process regression is next introduced as a learning method for the unknown dynamics, which provides probabilistic distributions of the predicted values. The predicted means are regarded as deterministic information and cancelled out by feedforward control inputs. The predicted variances are considered as the bounds of the model uncertainties with high probability, and a robust control method to ensure ultimate boundedness of the tracking control error is proposed for the uncertain system. The effectiveness of the proposed method is demonstrated via experiments with a self-developed hexarotor UAV testbed.

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基于高斯过程的全驱动六旋翼无人机鲁棒姿态跟踪控制

提出了一种基于高斯过程的全驱动六旋翼无人机鲁棒位置/姿态跟踪控制方法。多旋翼无人机由于其结构复杂、气动干扰等问题而存在建模误差，其完美的数学公式难以确定。为了解决这一问题，本文将基于数据的学习技术与基于模型的控制技术相结合。首先建立了考虑建模误差和气动干扰为未知动力学的六旋翼无人机动力学模型。然后引入高斯过程回归作为未知动态的学习方法，它提供了预测值的概率分布。预测均值被视为确定性信息，并被前馈控制输入抵消。将预测方差作为高概率模型不确定性的界，提出了一种保证不确定系统跟踪控制误差最终有界性的鲁棒控制方法。在自行研制的六旋翼无人机试验台上进行了实验，验证了该方法的有效性。

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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来源期刊

SICE journal of control, measurement, and system integration

CiteScore

1.20

自引率

0.00%

发文量