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Hauptverfasser: Wang, Jinhong, Ignuta-Ciuncanu, Matei C., Martinez-Botas, Ricardo F., Cao, Teng
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.06762
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author Wang, Jinhong
Ignuta-Ciuncanu, Matei C.
Martinez-Botas, Ricardo F.
Cao, Teng
author_facet Wang, Jinhong
Ignuta-Ciuncanu, Matei C.
Martinez-Botas, Ricardo F.
Cao, Teng
contents Solving flow through porous media is a crucial step in the topology optimisation of cold plates, a key component in modern thermal management. Traditional computational fluid dynamics (CFD) methods, while accurate, are often prohibitively expensive for large and complex geometries. In contrast, data-driven surrogate models provide a computationally efficient alternative, enabling rapid and reliable predictions. In this study, we develop a machine-learning framework for predicting steady-state flow through porous media governed by the Navier-Stokes-Brinkman equations. We implement and compare three model architectures-convolutional autoencoder (AE), U-Net, and Fourier Neural Operator (FNO)-evaluating their predictive performance. To enhance physics consistency, we incorporate physics-informed loss functions. Our results demonstrate that FNO outperforms AE and U-Net, achieving a mean squared error (MSE) as low as 0.0017 while providing speedups of up to 1000 times compared to CFD. Additionally, the mesh-invariant property of FNO emphasizes its suitability for topology optimisation tasks, where varying mesh resolutions are required. This study highlights the potential of machine learning to accelerate fluid flow predictions in porous media, offering a scalable alternative to traditional numerical methods.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06762
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Prediction of Steady-State Flow through Porous Media Using Machine Learning Models
Wang, Jinhong
Ignuta-Ciuncanu, Matei C.
Martinez-Botas, Ricardo F.
Cao, Teng
Fluid Dynamics
Computational Engineering, Finance, and Science
Machine Learning
Computational Physics
Solving flow through porous media is a crucial step in the topology optimisation of cold plates, a key component in modern thermal management. Traditional computational fluid dynamics (CFD) methods, while accurate, are often prohibitively expensive for large and complex geometries. In contrast, data-driven surrogate models provide a computationally efficient alternative, enabling rapid and reliable predictions. In this study, we develop a machine-learning framework for predicting steady-state flow through porous media governed by the Navier-Stokes-Brinkman equations. We implement and compare three model architectures-convolutional autoencoder (AE), U-Net, and Fourier Neural Operator (FNO)-evaluating their predictive performance. To enhance physics consistency, we incorporate physics-informed loss functions. Our results demonstrate that FNO outperforms AE and U-Net, achieving a mean squared error (MSE) as low as 0.0017 while providing speedups of up to 1000 times compared to CFD. Additionally, the mesh-invariant property of FNO emphasizes its suitability for topology optimisation tasks, where varying mesh resolutions are required. This study highlights the potential of machine learning to accelerate fluid flow predictions in porous media, offering a scalable alternative to traditional numerical methods.
title Prediction of Steady-State Flow through Porous Media Using Machine Learning Models
topic Fluid Dynamics
Computational Engineering, Finance, and Science
Machine Learning
Computational Physics
url https://arxiv.org/abs/2603.06762