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Autores principales: Cohen, Max H., Mann, Makai, Leahy, Kevin, Belta, Calin
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2304.01901
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author Cohen, Max H.
Mann, Makai
Leahy, Kevin
Belta, Calin
author_facet Cohen, Max H.
Mann, Makai
Leahy, Kevin
Belta, Calin
contents In this paper, we present a framework for online parameter estimation and uncertainty quantification in the context of adaptive safety-critical control. The key insight enabling our approach is that the parameter estimate generated by the continuous-time recursive least squares (RLS) algorithm at any point in time is an affine transformation of the initial parameter estimate. This property allows for parameterizing such estimates using objects that are closed under affine transformation, such as zonotopes, and enables the efficient propagation of such set-based estimates as time progresses. We illustrate how such an approach facilitates the synthesis of safety-critical controllers for systems with parametric uncertainty and additive disturbances using control barrier functions, and demonstrate the utility of our approach through illustrative examples.
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publishDate 2023
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spellingShingle Uncertainty Quantification for Recursive Estimation in Adaptive Safety-Critical Control
Cohen, Max H.
Mann, Makai
Leahy, Kevin
Belta, Calin
Systems and Control
In this paper, we present a framework for online parameter estimation and uncertainty quantification in the context of adaptive safety-critical control. The key insight enabling our approach is that the parameter estimate generated by the continuous-time recursive least squares (RLS) algorithm at any point in time is an affine transformation of the initial parameter estimate. This property allows for parameterizing such estimates using objects that are closed under affine transformation, such as zonotopes, and enables the efficient propagation of such set-based estimates as time progresses. We illustrate how such an approach facilitates the synthesis of safety-critical controllers for systems with parametric uncertainty and additive disturbances using control barrier functions, and demonstrate the utility of our approach through illustrative examples.
title Uncertainty Quantification for Recursive Estimation in Adaptive Safety-Critical Control
topic Systems and Control
url https://arxiv.org/abs/2304.01901