Physics-constrained DeepONet for Surrogate CFD models: a curved backward-facing step case

Anas Jnini; Harshinee Goordoyal; Sujal Dave; Artem Korobenko; Flavio Vella; Katharine Fraser

Physics-constrained DeepONet for Surrogate CFD models: a curved backward-facing step case

Anas Jnini, Harshinee Goordoyal, Sujal Dave, Artem Korobenko, Flavio Vella, Katharine Fraser

Published: 03 Mar 2024, Last Modified: 04 May 2024AI4DiffEqtnsInSci @ ICLR 2024 PosterEveryoneRevisionsBibTeXCC BY 4.0

Keywords: Neural operators, DeepONet, Navier-Stokes equations, Surrogate model, Backward-Facing step

TL;DR: The paper introduces Physics Constrained DeepOnets (PC-DeepOnets) for efficient and accurate surrogate modeling of fluid dynamics, specifically demonstrating its effectiveness on the flow patterns over a curved backward-facing step.

Abstract: The Physics-Constrained DeepONet (PC-DeepONet), an architecture that incorporates fundamental physics knowledge into the data-driven DeepONet model, is presented in this study. This methodology is exemplified through surrogate modeling of fluid dynamics over a curved backward-facing step, a benchmark problem in computational fluid dynamics. The model was trained on computational fluid dynamics data generated for a range of parameterized geometries. The PC-DeepONet was able to learn the mapping from the parameters describing the geometry to the velocity and pressure fields. While the DeepONet is solely data-driven, the PC-DeepONet imposes the divergence constraint from the continuity equation onto the network. The PC-DeepONet demonstrates higher accuracy than the data-driven baseline, especially when trained on sparse data. Both models attain convergence with a small dataset of 50 samples and require only 50 iterations for convergence, highlighting the efficiency of neural operators in learning the dynamics governed by partial differential equations.

Submission Number: 76

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