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Autori principali: Yi, Jiaxiang, Ferreira, Bernardo P., Bessa, Miguel A.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2507.13416
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author Yi, Jiaxiang
Ferreira, Bernardo P.
Bessa, Miguel A.
author_facet Yi, Jiaxiang
Ferreira, Bernardo P.
Bessa, Miguel A.
contents Data-driven learning is generalized to consider history-dependent multi-fidelity data, while quantifying epistemic uncertainty and disentangling it from data noise (aleatoric uncertainty). This generalization is hierarchical and adapts to different learning scenarios: from training the simplest single-fidelity deterministic neural networks up to the proposed multi-fidelity variance estimation Bayesian recurrent neural networks. The versatility and generality of the proposed methodology are demonstrated by applying it to different data-driven constitutive modeling scenarios that include multiple fidelities with and without aleatoric uncertainty (noise). The method accurately predicts the response and quantifies model error while also discovering the noise distribution (when present). This opens opportunities for future real-world applications in diverse scientific and engineering domains; especially, the most challenging cases involving design and analysis under uncertainty.
format Preprint
id arxiv_https___arxiv_org_abs_2507_13416
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Single- to multi-fidelity history-dependent learning with uncertainty quantification and disentanglement: application to data-driven constitutive modeling
Yi, Jiaxiang
Ferreira, Bernardo P.
Bessa, Miguel A.
Machine Learning
Artificial Intelligence
Data-driven learning is generalized to consider history-dependent multi-fidelity data, while quantifying epistemic uncertainty and disentangling it from data noise (aleatoric uncertainty). This generalization is hierarchical and adapts to different learning scenarios: from training the simplest single-fidelity deterministic neural networks up to the proposed multi-fidelity variance estimation Bayesian recurrent neural networks. The versatility and generality of the proposed methodology are demonstrated by applying it to different data-driven constitutive modeling scenarios that include multiple fidelities with and without aleatoric uncertainty (noise). The method accurately predicts the response and quantifies model error while also discovering the noise distribution (when present). This opens opportunities for future real-world applications in diverse scientific and engineering domains; especially, the most challenging cases involving design and analysis under uncertainty.
title Single- to multi-fidelity history-dependent learning with uncertainty quantification and disentanglement: application to data-driven constitutive modeling
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2507.13416