Strategies for multi-case physics-informed neural networks for tube flows: a study using 2D flow scenarios

Strategies for multi-case physics-informed neural networks for tube flows: a study using 2D flow scenarios

Fluid dynamics computations for tube-like geometries are crucial in biomedical evaluations of vascular and airways fluid dynamics. Physics-Informed Neural Networks (PINNs) have emerged as a promising alternative to traditional computational fluid dynamics (CFD) methods. However, vanilla PINNs often...

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Bibliographic Details
Published in:Scientific reports Vol. 14; no. 1; p. 11577
Main Authors: Wong, Hong Shen, Chan, Wei Xuan, Li, Bing Huan, Yap, Choon Hwai
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 21-05-2024
Nature Publishing Group
Nature Portfolio
Subjects:
631/114/1305
631/114/2397
639/166/985
Computer applications
Deep learning
Fluid dynamics
Fluid flow
Geometry
Humanities and Social Sciences
Hydrodynamics
Hypernetworks
multidisciplinary
Neural networks
Physics
Physics informed neural network
Science
Science (multidisciplinary)
Deep learning
Hypernetworks
Physics informed neural network
Fluid flow
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Summary:Fluid dynamics computations for tube-like geometries are crucial in biomedical evaluations of vascular and airways fluid dynamics. Physics-Informed Neural Networks (PINNs) have emerged as a promising alternative to traditional computational fluid dynamics (CFD) methods. However, vanilla PINNs often demand longer training times than conventional CFD methods for each specific flow scenario, limiting their widespread use. To address this, multi-case PINN approach has been proposed, where varied geometry cases are parameterized and pre-trained on the PINN. This allows for quick generation of flow results in unseen geometries. In this study, we compare three network architectures to optimize the multi-case PINN through experiments on a series of idealized 2D stenotic tube flows. The evaluated architectures include the ‘Mixed Network’, treating case parameters as additional dimensions in the vanilla PINN architecture; the “Hypernetwork”, incorporating case parameters into a side network that computes weights in the main PINN network; and the “Modes” network, where case parameters input into a side network contribute to the final output via an inner product, similar to DeepONet. Results confirm the viability of the multi-case parametric PINN approach, with the Modes network exhibiting superior performance in terms of accuracy, convergence efficiency, and computational speed. To further enhance the multi-case PINN, we explored two strategies. First, incorporating coordinate parameters relevant to tube geometry, such as distance to wall and centerline distance, as inputs to PINN, significantly enhanced accuracy and reduced computational burden. Second, the addition of extra loss terms, enforcing zero derivatives of existing physics constraints in the PINN (similar to gPINN), improved the performance of the Mixed Network and Hypernetwork, but not that of the Modes network. In conclusion, our work identified strategies crucial for future scaling up to 3D, wider geometry ranges, and additional flow conditions, ultimately aiming towards clinical utility.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-62117-9