Predicting transonic flowfields in non–homogeneous unstructured grids using autoencoder graph convolutional networks
Predicting transonic flowfields in non–homogeneous unstructured grids using autoencoder graph convolutional networks
This paper addresses the challenges posed by non-homogeneous unstructured grids, which are commonly used in computational fluid dynamics. The prevalence of these grids in fluid dynamics scenarios has driven the exploration of innovative approaches for generating reduced-order models. Our approach leverages geometric deep learning, specifically through the use of an autoencoder architecture built on graph convolutional networks. This architecture enhances prediction accuracy by propagating information to distant nodes and emphasizing influential points. Key innovations include a dimensionality reduction module based on pressure-gradient values, fast connectivity reconstruction using Mahalanobis distance, optimization of the network architecture, and a physics-informed loss function based on aerodynamic coefficient. These advancements result in a more robust and accurate predictive model, achieving systematically lower errors compared to previous graph-based methods. The proposed methodology is validated through two distinct test cases—wing-only and wing-body configurations—demonstrating precise reconstruction of steady-state distributed quantities within a two-dimensional parametric space.
Immordino, Gabriele
ed9626cc-aa2b-40be-b376-0868967e5e65
Vaiuso, Andrea
33f9b468-d956-486f-a181-12caf6ce3147
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Righi, Marcello
1e57534d-4519-4a93-94d6-b4f27558093b
7 January 2025
Immordino, Gabriele
ed9626cc-aa2b-40be-b376-0868967e5e65
Vaiuso, Andrea
33f9b468-d956-486f-a181-12caf6ce3147
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Righi, Marcello
1e57534d-4519-4a93-94d6-b4f27558093b
Immordino, Gabriele, Vaiuso, Andrea, Da Ronch, Andrea and Righi, Marcello
(2025)
Predicting transonic flowfields in non–homogeneous unstructured grids using autoencoder graph convolutional networks.
Journal of Computational Physics, 524.
(doi:10.1016/j.jcp.2024.113708).
Abstract
This paper addresses the challenges posed by non-homogeneous unstructured grids, which are commonly used in computational fluid dynamics. The prevalence of these grids in fluid dynamics scenarios has driven the exploration of innovative approaches for generating reduced-order models. Our approach leverages geometric deep learning, specifically through the use of an autoencoder architecture built on graph convolutional networks. This architecture enhances prediction accuracy by propagating information to distant nodes and emphasizing influential points. Key innovations include a dimensionality reduction module based on pressure-gradient values, fast connectivity reconstruction using Mahalanobis distance, optimization of the network architecture, and a physics-informed loss function based on aerodynamic coefficient. These advancements result in a more robust and accurate predictive model, achieving systematically lower errors compared to previous graph-based methods. The proposed methodology is validated through two distinct test cases—wing-only and wing-body configurations—demonstrating precise reconstruction of steady-state distributed quantities within a two-dimensional parametric space.
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Accepted/In Press date: 24 December 2024
e-pub ahead of print date: 2 January 2025
Published date: 7 January 2025
Identifiers
Local EPrints ID: 504234
URI: http://eprints.soton.ac.uk/id/eprint/504234
ISSN: 0021-9991
PURE UUID: 105b6dcb-79bc-4b86-adc3-6831ef64ea55
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Date deposited: 01 Sep 2025 16:46
Last modified: 02 Sep 2025 02:02
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Author:
Gabriele Immordino
Author:
Andrea Vaiuso
Author:
Marcello Righi
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