Bayesian-EUCLID: Discovering hyperelastic material laws with uncertainties

“…The weak form is then minimized with respect to θ using a fixed-point iteration scheme (inspired by [422]), where a L p -regularization is used to promote sparsity in θ. Despite its young age, the approach has already been applied to plasticity [423], viscoelasticity [424], combinations [425], and has been extended to incorporate uncertainties through a Bayesian model [426]. Furthermore, the approach has been extended with an ensemble of input-convex NNs [413], yielding a more accurate, but less interpretable model.…”

Deep learning in computational mechanics: a review

“…The weak form is then minimized with respect to θ using a fixed-point iteration scheme (inspired by [422]), where a L p -regularization is used to promote sparsity in θ. Despite its young age, the approach has already been applied to plasticity [423], viscoelasticity [424], combinations [425], and has been extended to incorporate uncertainties through a Bayesian model [426]. Furthermore, the approach has been extended with an ensemble of input-convex NNs [413], yielding a more accurate, but less interpretable model.…”

Deep learning in computational mechanics: a review

“…In the following, we describe our novel approach to automatically discover generalized standard (hence, stable and thermodynamically consistent) material models based on full-field displacement and global force data. The backbone of the approach, which we denote as EUCLID in line with our previous work [18,30,32,41], can be outlined as follows: we start from a very wide material model space, which we construct by exploiting the flexibility and a priori thermodynamic consistency of the generalized standard material model framework; we constrain this model space by enforcing the satisfaction of momentum balance (in weak sense) on the source data; we exploit sparse regression to ensure parsimonity of the discovered model. Through these three key ingredients, we end up simultaneously performing model selection and identification of the unknown material parameters.…”

“…By leveraging sparse regression [29,39,40], it is ensured that a parsimonious and interpretable material model, i.e., one with a small number of terms and parameters, is discovered. Later works on EUCLID include a study of the problem from a Bayesian perspective for quantifying the uncertainty in the discovered models [41] and an unsupervised training framework for artificial neural networks [18]. For related works that aim to identify material parameters of an a priori known constitutive model or train uninterpretable blackbox machine learning models in an unsupervised fashion, the reader is referred to works by Man and Furukawa [42], Huang et al [43], Liu et al [44], Amores et al [45], Anton and Wessels [46].…”

Automated discovery of generalized standard material models with EUCLID

“…EUCLID can automatically discover the target model from a large library of interpretable candidate material models, with the input of full-field displacements and global reaction forces instead of labeled stress-strain data pairs. Until now, EUCLID has been successfully demonstrated for hyperelasticity (Flaschel et al, 2021c,b,a;Joshi et al, 2022;Flaschel et al, 2023b), viscoelasticity (Marino et al, 2023), pressure-insensitive associated plasticity (Flaschel et al, 2022a,c,b), and generalized standard material models (Flaschel et al, 2023a).…”

Discovering non-associated pressure-sensitive plasticity models with EUCLID