NN-EUCLID: deep-learning hyperelasticity without stress data

TL;DR

This paper introduces NN-EUCLID, an unsupervised deep learning method for hyperelasticity that learns constitutive laws from displacement and force data without stress labels, ensuring physical consistency and broad applicability.

Contribution

It presents a physics-based neural network framework that automatically satisfies key hyperelastic constraints and discovers anisotropic fiber directions without stress data.

Findings

Accurately learns isotropic and anisotropic hyperelastic laws.

Automatically discovers fiber orientations in anisotropic models.

Demonstrates good generalization and finite element applicability.

Abstract

We propose a new approach for unsupervised learning of hyperelastic constitutive laws with physics-consistent deep neural networks. In contrast to supervised learning, which assumes the availability of stress-strain pairs, the approach only uses realistically measurable full-field displacement and global reaction force data, thus it lies within the scope of our recent framework for Efficient Unsupervised Constitutive Law Identification and Discovery (EUCLID) and we denote it as NN-EUCLID. The absence of stress labels is compensated for by leveraging a physics-motivated loss function based on the conservation of linear momentum to guide the learning process. The constitutive model is based on input-convex neural networks, which are capable of learning a function that is convex with respect to its inputs. By employing a specially designed neural network architecture, multiple physical and thermodynamic constraints for hyperelastic constitutive laws, such as material frame indifference, (poly-)convexity, and stress-free reference configuration are automatically satisfied. We demonstrate the ability of the approach to accurately learn several hidden isotropic and anisotropic hyperelastic constitutive laws - including e.g., Mooney-Rivlin, Arruda-Boyce, Ogden, and Holzapfel models - without using stress data. For anisotropic hyperelasticity, the unknown anisotropic fiber directions are automatically discovered jointly with the constitutive model. The neural network-based constitutive models show good generalization capability beyond the strain states observed during training and are readily deployable in a general finite element framework for simulating complex mechanical boundary value problems with good accuracy.