Litcius/Paper detail

Stress Representations for Tensor Basis Neural Networks: Alternative Formulations to Finger–Rivlin–Ericksen

Jan Fuhg, Nikolaos Bouklas, Reese E. Jones

2024Journal of Computing and Information Science in Engineering13 citationsDOI

Abstract

Abstract Data-driven constitutive modeling frameworks based on neural networks and classical representation theorems have recently gained considerable attention due to their ability to easily incorporate constitutive constraints and their excellent generalization performance. In these models, the stress prediction follows from a linear combination of invariant-dependent coefficient functions and known tensor basis generators. However, thus far the formulations have been limited to stress representations based on the classical Finger–Rivlin–Ericksen form, while the performance of alternative representations has yet to be investigated. In this work, we survey a variety of tensor basis neural network models for modeling hyperelastic materials in a finite deformation context, including a number of so far unexplored formulations which use theoretically equivalent invariants and generators to Finger–Rivlin–Ericksen. Furthermore, we compare potential-based and coefficient-based approaches, as well as different calibration techniques. Nine variants are tested against both noisy and noiseless datasets for three different materials. Theoretical and practical insights into the performance of each formulation are given.

Topics & Concepts

Basis (linear algebra)Tensor (intrinsic definition)Stress (linguistics)Artificial neural networkComputer scienceAlgebra over a fieldApplied mathematicsMathematicsAlgorithmArtificial intelligencePure mathematicsGeometryLinguisticsPhilosophyElasticity and Material ModelingModel Reduction and Neural NetworksComposite Material Mechanics