Machine Learning-Accelerated Computational Solid Mechanics: Application to Linear Elasticity
Abstract
This work presents a novel physics-informed deep learning based super-resolution framework to reconstruct high-resolution deformation fields from low-resolution counterparts, obtained from coarse mesh simulations or experiments. We leverage the governing equations and boundary conditions of the physical system to train the model without using any high-resolution labeled data. The proposed approach is applied to obtain the super-resolved deformation fields from the low-resolution stress and displacement fields obtained by running simulations on a coarse mesh for a body undergoing linear elastic deformation. We demonstrate that the super-resolved fields match the accuracy of an advanced numerical solver running at 400 times the coarse mesh resolution, while simultaneously satisfying the governing laws. A brief evaluation study comparing the performance of two deep learning based super-resolution architectures is also presented.
Cite
@article{arxiv.2112.08676,
title = {Machine Learning-Accelerated Computational Solid Mechanics: Application to Linear Elasticity},
author = {Rajat Arora},
journal= {arXiv preprint arXiv:2112.08676},
year = {2022}
}
Comments
3 figures, 9 pages, Accepted in AAAI 2022: Workshop on AI to Accelerate Science and Engineering (AI2ASE)