Standard

Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry. / Travnikov, Vladislav; Plokhikh, Ivan; Mullyadzhanov, Rustam.

In: Physics of Fluids, Vol. 36, No. 12, 127117, 01.12.2024.

Research output: Contribution to journalArticlepeer-review

Harvard

Travnikov, V, Plokhikh, I & Mullyadzhanov, R 2024, 'Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry', Physics of Fluids, vol. 36, no. 12, 127117. https://doi.org/10.1063/5.0234960

APA

Travnikov, V., Plokhikh, I., & Mullyadzhanov, R. (2024). Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry. Physics of Fluids, 36(12), [ 127117]. https://doi.org/10.1063/5.0234960

Vancouver

Travnikov V, Plokhikh I, Mullyadzhanov R. Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry. Physics of Fluids. 2024 Dec 1;36(12): 127117. doi: 10.1063/5.0234960

Author

Travnikov, Vladislav ; Plokhikh, Ivan ; Mullyadzhanov, Rustam. / Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry. In: Physics of Fluids. 2024 ; Vol. 36, No. 12.

BibTeX

@article{db7d7be0c3cd47bb86bb83404e1dfd31,
title = "Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry",
abstract = "Graph neural networks (GNNs) represent a promising instrument for surrogate modeling, capable of handling unstructured computational meshes naturally. We address a typical issue of the accuracy degradation for larger computational domains due to the limited receptive field of GNN models and long-range global interactions between nodes of the mesh. We propose a modification of the GNN architecture allowing to improve the accuracy by a factor of 3 without significant increase in computational costs. The validation tests of the model concentrate on the two-dimensional stationary fluid flow around a bluff body in a channel and corresponding heat transfer. The problem formulation includes bluff bodies of randomly generated shapes and various boundary conditions. The model shows a robust performance for the out-of-domain data, i.e., the flow over an airfoil for different angles of attack.",
author = "Vladislav Travnikov and Ivan Plokhikh and Rustam Mullyadzhanov",
note = "This work was supported by a grant for research centers provided by the Analytical Center for the Government of the Russian Federation in accordance with the subsidy agreement (agreement identifier 000000D730324P540002) and the agreement with the Novosibirsk State University dated December 27, 2023, No. 70-2023-001318.",
year = "2024",
month = dec,
day = "1",
doi = "10.1063/5.0234960",
language = "English",
volume = "36",
journal = "Physics of Fluids",
issn = "1070-6631",
publisher = "American Institute of Physics",
number = "12",

}

RIS

TY - JOUR

T1 - Advancing graph neural network architecture for fluid flow and heat transfer surrogate modeling: Variable boundary conditions and geometry

AU - Travnikov, Vladislav

AU - Plokhikh, Ivan

AU - Mullyadzhanov, Rustam

N1 - This work was supported by a grant for research centers provided by the Analytical Center for the Government of the Russian Federation in accordance with the subsidy agreement (agreement identifier 000000D730324P540002) and the agreement with the Novosibirsk State University dated December 27, 2023, No. 70-2023-001318.

PY - 2024/12/1

Y1 - 2024/12/1

N2 - Graph neural networks (GNNs) represent a promising instrument for surrogate modeling, capable of handling unstructured computational meshes naturally. We address a typical issue of the accuracy degradation for larger computational domains due to the limited receptive field of GNN models and long-range global interactions between nodes of the mesh. We propose a modification of the GNN architecture allowing to improve the accuracy by a factor of 3 without significant increase in computational costs. The validation tests of the model concentrate on the two-dimensional stationary fluid flow around a bluff body in a channel and corresponding heat transfer. The problem formulation includes bluff bodies of randomly generated shapes and various boundary conditions. The model shows a robust performance for the out-of-domain data, i.e., the flow over an airfoil for different angles of attack.

AB - Graph neural networks (GNNs) represent a promising instrument for surrogate modeling, capable of handling unstructured computational meshes naturally. We address a typical issue of the accuracy degradation for larger computational domains due to the limited receptive field of GNN models and long-range global interactions between nodes of the mesh. We propose a modification of the GNN architecture allowing to improve the accuracy by a factor of 3 without significant increase in computational costs. The validation tests of the model concentrate on the two-dimensional stationary fluid flow around a bluff body in a channel and corresponding heat transfer. The problem formulation includes bluff bodies of randomly generated shapes and various boundary conditions. The model shows a robust performance for the out-of-domain data, i.e., the flow over an airfoil for different angles of attack.

UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-85211251332&origin=inward&txGid=93cd629f72f3fdaac901c7167fad3b1e

UR - https://www.mendeley.com/catalogue/5e48eb59-bc06-37e7-8c0b-1bae1a156fe5/

U2 - 10.1063/5.0234960

DO - 10.1063/5.0234960

M3 - Article

VL - 36

JO - Physics of Fluids

JF - Physics of Fluids

SN - 1070-6631

IS - 12

M1 - 127117

ER -

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