Operator learning regularization for macroscopic permeability prediction in dual-scale flow problem
Abstract
Liquid composites moulding is an important manufacturing technology for fibre reinforced composites, due to its cost-effectiveness. Challenges lie in the optimisation of the process due to the lack of understanding of key characteristic of textile fabrics - permeability. The problem of computing the permeability coefficient can be modelled as the well-known Stokes-Brinkman equation, which introduces a heterogeneous parameter distinguishing macropore regions and fibre-bundle regions. In the present work, we train a Fourier neural operator to learn the nonlinear map from the heterogeneous coefficient to the velocity field , and recover the corresponding macroscopic permeability . This is a challenging inverse problem since both the input and output fields span several order of magnitudes, we introduce different regularization techniques for the loss function and perform a quantitative comparison between them.
Cite
@article{arxiv.2412.00579,
title = {Operator learning regularization for macroscopic permeability prediction in dual-scale flow problem},
author = {Christina Runkel and Sinan Xiao and Nicolas Boullé and Yang Chen},
journal= {arXiv preprint arXiv:2412.00579},
year = {2024}
}
Comments
23 pages, 7 figures