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Bibliographic Details
Main Authors: Savino, Mary, Lévy-Leduc, Céline, Leconte, Marc, Cochepin, Benoit
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2110.08111
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author Savino, Mary
Lévy-Leduc, Céline
Leconte, Marc
Cochepin, Benoit
author_facet Savino, Mary
Lévy-Leduc, Céline
Leconte, Marc
Cochepin, Benoit
contents In this paper, we propose a novel sequential data-driven method for dealing with equilibrium based chemical simulations, which can be seen as a specific machine learning approach called active learning. The underlying idea of our approach is to consider the function to estimate as a sample of a Gaussian process which allows us to compute the global uncertainty on the function estimation. Thanks to this estimation and with almost no parameter to tune, the proposed method sequentially chooses the most relevant input data at which the function to estimate has to be evaluated to build a surrogate model. Hence, the number of evaluations of the function to estimate is dramatically limited. Our active learning method is validated through numerical experiments and applied to a complex chemical system commonly used in geoscience.
format Preprint
id arxiv_https___arxiv_org_abs_2110_08111
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle An active learning approach for improving the performance of equilibrium based chemical simulations
Savino, Mary
Lévy-Leduc, Céline
Leconte, Marc
Cochepin, Benoit
Machine Learning
In this paper, we propose a novel sequential data-driven method for dealing with equilibrium based chemical simulations, which can be seen as a specific machine learning approach called active learning. The underlying idea of our approach is to consider the function to estimate as a sample of a Gaussian process which allows us to compute the global uncertainty on the function estimation. Thanks to this estimation and with almost no parameter to tune, the proposed method sequentially chooses the most relevant input data at which the function to estimate has to be evaluated to build a surrogate model. Hence, the number of evaluations of the function to estimate is dramatically limited. Our active learning method is validated through numerical experiments and applied to a complex chemical system commonly used in geoscience.
title An active learning approach for improving the performance of equilibrium based chemical simulations
topic Machine Learning
url https://arxiv.org/abs/2110.08111