Related papers: Use of Deep Neural Networks for Uncertain Stress Functions with Extensions to Impact Mechanics

Use of Deep Neural Networks for Uncertain Stress Functions with Extensions to Impact Mechanics

URL: http://arxiv.org/abs/2311.16135v2
Date: Wed, 20 Dec 2023 02:47:02 GMT
Title: Use of Deep Neural Networks for Uncertain Stress Functions with Extensions to Impact Mechanics
Authors: Garrett Blum and Ryan Doris and Diego Klabjan and Horacio Espinosa and Ron Szalkowski
Abstract summary: We propose a deep neural network approach to model stress as a state function with quantile regression to capture uncertainty. We extend these models to uniaxial impact mechanics using differential equations to demonstrate a use case and provide a framework for implementing this uncertainty-aware stress function.
Score: 9.73713941604395
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Stress-strain curves, or more generally, stress functions, are an extremely important characterization of a material's mechanical properties. However, stress functions are often difficult to derive and are narrowly tailored to a specific material. Further, large deformations, high strain-rates, temperature sensitivity, and effect of material parameters compound modeling challenges. We propose a generalized deep neural network approach to model stress as a state function with quantile regression to capture uncertainty. We extend these models to uniaxial impact mechanics using stochastic differential equations to demonstrate a use case and provide a framework for implementing this uncertainty-aware stress function. We provide experiments benchmarking our approach against leading constitutive, machine learning, and transfer learning approaches to stress and impact mechanics modeling on publicly available and newly presented data sets. We also provide a framework to optimize material parameters given multiple competing impact scenarios.

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