Related papers: Exploring the ability of the Deep Ritz Method to model strain localization as a sharp discontinuity

Exploring the ability of the Deep Ritz Method to model strain localization as a sharp discontinuity

URL: http://arxiv.org/abs/2409.13241v1
Date: Fri, 20 Sep 2024 05:57:50 GMT
Title: Exploring the ability of the Deep Ritz Method to model strain localization as a sharp discontinuity
Authors: Omar León, Víctor Rivera, Angel Vázquez-Patiño, Jacinto Ulloa, Esteban Samaniego,
Abstract summary: We use a regularized strong discontinuity kinematics within a variational setting for elastoplastic solids. The corresponding mathematical model is discretized using Artificial Neural Networks (ANNs) As a proof of concept, we show through both 1D and 2D numerical examples that the computational modeling of strain localization for elastoplastic solids is feasible.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We present an exploratory study of the possibilities of the Deep Ritz Method (DRM) for the modeling of strain localization in solids as a sharp discontinuity in the displacement field. For this, we use a regularized strong discontinuity kinematics within a variational setting for elastoplastic solids. The corresponding mathematical model is discretized using Artificial Neural Networks (ANNs). The architecture takes care of the kinematics, while the variational statement of the boundary value problem is taken care of by the loss function. The main idea behind this approach is to solve both the equilibrium problem and the location of the localization band by means of trainable parameters in the ANN. As a proof of concept, we show through both 1D and 2D numerical examples that the computational modeling of strain localization for elastoplastic solids within the framework of DRM is feasible.

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