Related papers: Improving Deep Learning Performance for Predicting Large-Scale Porous-Media Flow through Feature Coarsening

Improving Deep Learning Performance for Predicting Large-Scale Porous-Media Flow through Feature Coarsening

URL: http://arxiv.org/abs/2105.03752v1
Date: Sat, 8 May 2021 17:58:46 GMT
Title: Improving Deep Learning Performance for Predicting Large-Scale Porous-Media Flow through Feature Coarsening
Authors: Bicheng Yan, Dylan Robert Harp, Bailian Chen, Rajesh J. Pawar
Abstract summary: This letter describes a deep learning (DL) workflow to predict the pressure evolution as fluid flows in large-scale 3D heterogeneous porous media. We validate the DL approach that is trained from physics-based simulation data to predict pressure field in a field-scale 3D geologic CO storage reservoir.
Score: 1.4050836886292868
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Physics-based simulation for fluid flow in porous media is a computational technology to predict the temporal-spatial evolution of state variables (e.g. pressure) in porous media, and usually requires high computational expense due to its nonlinearity and the scale of the study domain. This letter describes a deep learning (DL) workflow to predict the pressure evolution as fluid flows in large-scale 3D heterogeneous porous media. In particular, we apply feature coarsening technique to extract the most representative information and perform the training and prediction of DL at the coarse scale, and further recover the resolution at the fine scale by 2D piecewise cubic interpolation. We validate the DL approach that is trained from physics-based simulation data to predict pressure field in a field-scale 3D geologic CO_2 storage reservoir. We evaluate the impact of feature coarsening on DL performance, and observe that the feature coarsening can not only decrease training time by >74% and reduce memory consumption by >75%, but also maintains temporal error <1.5%. Besides, the DL workflow provides predictive efficiency with ~1400 times speedup compared to physics-based simulation.

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