Deep learning of multi-resolution X-Ray micro-CT images for multi-scale modelling

TL;DR

This paper presents a deep learning approach using 3D super-resolution neural networks to enhance low-resolution micro-CT images, enabling accurate multi-scale porous system modeling from pore to continuum scales.

Contribution

It introduces a novel 3D EDSR neural network for super-resolution of micro-CT images, improving multi-scale modeling accuracy in porous media analysis.

Findings

SR images are comparable to high-resolution ground truth.

Models achieve accuracy within experimental uncertainty.

Method significantly outperforms low-resolution counterparts.

Abstract

Field-of-view and resolution trade-offs in X-Ray micro-computed tomography (micro-CT) imaging limit the characterization, analysis and model development of multi-scale porous systems. To this end, we developed an applied methodology utilising deep learning to enhance low resolution images over large sample sizes and create multi-scale models capable of accurately simulating experimental fluid dynamics from the pore (microns) to continuum (centimetres) scale. We develop a 3D Enhanced Deep Super Resolution (EDSR) convolutional neural network to create super resolution (SR) images from low resolution images, which alleviates common micro-CT hardware/reconstruction defects in high-resolution (HR) images. When paired with pore-network simulations and parallel computation, we can create large 3D continuum-scale models with spatially varying flow & material properties. We quantitatively validate the workflow at various scales using direct HR/SR image similarity, pore-scale material/flow simulations and continuum scale multiphase flow experiments (drainage immiscible flow pressures and 3D fluid volume fractions). The SR images and models are comparable to the HR ground truth, and generally accurate to within experimental uncertainty at the continuum scale across a range of flow rates. They are found to be significantly more accurate than their LR counterparts, especially in cases where a wide distribution of pore-sizes are encountered. The applied methodology opens up the possibility to image, model and analyse truly multi-scale heterogeneous systems that are otherwise intractable.