Generative Hyperelasticity with Physics-Informed Probabilistic Diffusion
Fields
- URL: http://arxiv.org/abs/2310.03745v1
- Date: Mon, 11 Sep 2023 19:35:23 GMT
- Title: Generative Hyperelasticity with Physics-Informed Probabilistic Diffusion
Fields
- Authors: Vahidullah Tac, Manuel K Rausch, Ilias Bilionis, Francisco Sahli
Costabal, Adrian Buganza Tepole
- Abstract summary: Data-driven strain energy functions possess the flexibility to capture the behavior of complex materials.
We leverage recent advances in generative models to create realistic hyperelastic material models.
We extend our approach to spatially correlated diffusion in heterogeneous material properties for arbitrary geometries.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Many natural materials exhibit highly complex, nonlinear, anisotropic, and
heterogeneous mechanical properties. Recently, it has been demonstrated that
data-driven strain energy functions possess the flexibility to capture the
behavior of these complex materials with high accuracy while satisfying
physics-based constraints. However, most of these approaches disregard the
uncertainty in the estimates and the spatial heterogeneity of these materials.
In this work, we leverage recent advances in generative models to address these
issues. We use as building block neural ordinary equations (NODE) that -- by
construction -- create polyconvex strain energy functions, a key property of
realistic hyperelastic material models. We combine this approach with
probabilistic diffusion models to generate new samples of strain energy
functions. This technique allows us to sample a vector of Gaussian white noise
and translate it to NODE parameters thereby representing plausible strain
energy functions. We extend our approach to spatially correlated diffusion
resulting in heterogeneous material properties for arbitrary geometries. We
extensively test our method with synthetic and experimental data on biological
tissues and run finite element simulations with various degrees of spatial
heterogeneity. We believe this approach is a major step forward including
uncertainty in predictive, data-driven models of hyperelasticity
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