Robust Control Barrier Functions Using Uncertainty Estimation With Application to Mobile Robots

IF 7 1区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS IEEE Transactions on Automatic Control Pub Date : 2025-02-04 DOI:10.1109/TAC.2025.3538742

Ersin Daş;Joel W. Burdick

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Abstract

This article proposes a safety-critical control design approach for nonlinear control affine systems in the presence of matched and unmatched uncertainties. Our constructive framework couples control barrier function (CBF) theory with a new uncertainty estimator to ensure robust safety. We use the estimated uncertainty, along with a derived upper bound on the estimation error, for synthesizing CBFs and safety-critical controllers via a quadratic program-based feedback control law that rigorously ensures robust safety while improving disturbance rejection performance. We extend the method to higher order CBFs (HOCBFs) to achieve safety under unmatched uncertainty, which may cause relative degree differences with respect to control input and disturbances. We assume the relative degree difference is at most one, resulting in a second-order cone constraint. We demonstrate the proposed robust HOCBF method through a simulation of an uncertain elastic actuator control problem and experimentally validate the efficacy of our robust CBF framework on a tracked robot with slope-induced matched and unmatched perturbations.

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基于不确定性估计的鲁棒控制障碍函数在移动机器人中的应用

针对存在匹配不确定性和不匹配不确定性的非线性仿射控制系统，提出了一种安全关键控制设计方法。我们的构造框架将控制屏障函数（CBF）理论与新的不确定性估计相结合，以确保鲁棒安全性。我们使用估计的不确定性以及估计误差的推导上界，通过基于二次程序的反馈控制律来合成cbf和安全关键控制器，该律严格确保鲁棒安全性，同时提高抗扰性能。我们将该方法扩展到高阶cbf (hocbf)，以实现在不匹配不确定性下的安全性，不匹配不确定性可能导致相对于控制输入和干扰的相对程度差异。我们假设相对度差最多为1，导致二阶锥约束。我们通过一个不确定弹性驱动器控制问题的仿真验证了所提出的鲁棒HOCBF方法，并通过实验验证了我们的鲁棒CBF框架在具有斜坡诱导的匹配和不匹配扰动的履带式机器人上的有效性。

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

IEEE Transactions on Automatic Control 工程技术-工程：电子与电气

CiteScore

11.30

自引率

5.90%

发文量

824

审稿时长

9 months

期刊介绍： In the IEEE Transactions on Automatic Control, the IEEE Control Systems Society publishes high-quality papers on the theory, design, and applications of control engineering. Two types of contributions are regularly considered: 1) Papers: Presentation of significant research, development, or application of control concepts. 2) Technical Notes and Correspondence: Brief technical notes, comments on published areas or established control topics, corrections to papers and notes published in the Transactions. In addition, special papers (tutorials, surveys, and perspectives on the theory and applications of control systems topics) are solicited.