Litcius/Paper detail

FEM-GAN: A Physics-Supervised Deep Learning Generative Model for Elastic Porous Materials

Albert Argilaga

2023Materials10 citationsDOIOpen Access PDF

Abstract

X-ray μCT imaging is a common technique that is used to gain access to the full-field characterization of materials. Nevertheless, the process can be expensive and time-consuming, thus limiting image availability. A number of existing generative models can assist in mitigating this limitation, but they often lack a sound physical basis. This work presents a physics-supervised generative adversarial networks (GANs) model and applies it to the generation of X-ray μCT images. FEM simulations provide physical information in the form of elastic coefficients. Negative X-ray μCT images of a Hostun sand were used as the target material. During training, image batches were evaluated with nonparametric statistics to provide posterior metrics. A variety of loss functions and FEM evaluation frequencies were tested in a parametric study. The results show, that in several test scenarios, FEM-GANs-generated images proved to be better than the reference images for most of the elasticity coefficients. Although the model failed at perfectly reproducing the three out-of-axis coefficients in most cases, the model showed a net improvement with respect to the GANs reference. The generated images can be used in data augmentation, the calibration of image analysis tools, filling incomplete X-ray μCT images, and generating microscale variability in multiscale applications.

Topics & Concepts

Finite element methodParametric statisticsMicroscale chemistryGenerative modelComputer scienceElasticity (physics)Artificial intelligenceParametric modelImage (mathematics)Generative grammarPattern recognition (psychology)MathematicsMaterials scienceStructural engineeringStatisticsEngineeringMathematics educationComposite materialDrilling and Well EngineeringSeismic Imaging and Inversion TechniquesGenerative Adversarial Networks and Image Synthesis