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Finite-difference-informed graph network for solving steady-state incompressible flows on block-structured grids

Yiye Zou, Tianyu Li, Lin Lu, J.H. Wang, Shufan Zou, Laiping Zhang, Xiaogang Deng

2024Physics of Fluids9 citationsDOIOpen Access PDF

Abstract

Advances in deep learning have enabled physics-informed neural networks to solve partial differential equations. Numerical differentiation using the finite-difference (FD) method is efficient in physics-constrained designs, even in parameterized settings. In traditional computational fluid dynamics (CFD), body-fitted block-structured grids are often employed for complex flow cases when obtaining FD solutions. However, convolution operators in convolutional neural networks for FD are typically limited to single-block grids. To address this issue, graphs and graph networks are used to learn flow representations across multi-block-structured grids. A graph convolution-based FD method (GC-FDM) is proposed to train graph networks in a label-free physics-constrained manner, enabling differentiable FD operations on unstructured graph outputs. To demonstrate model performance from single- to multi-block-structured grids, the parameterized steady incompressible Navier–Stokes equations are solved for a lid-driven cavity flow and the flows around single and double circular cylinder configurations. When compared to a CFD solver under various boundary conditions, the proposed method achieves a relative error in velocity field predictions in the order of 10−3. Furthermore, the proposed method reduces training costs by approximately 20% compared to a physics-informed neural network. To further verify the effectiveness of GC-FDM in multi-block processing, a 30P30N airfoil geometry is considered, and the predicted results are reasonably compared with those given by CFD. Finally, the applicability of GC-FDM to a three-dimensional (3D) case is tested using a 3D cavity geometry.

Topics & Concepts

PhysicsCompressibilityIncompressible flowGraphFinite differenceFinite difference methodNavier–Stokes equationsApplied mathematicsSteady state (chemistry)Block (permutation group theory)MechanicsMathematical analysisTheoretical computer scienceGeometryThermodynamicsMathematicsComputer scienceChemistryPhysical chemistryModel Reduction and Neural NetworksComputational Fluid Dynamics and AerodynamicsAdvanced Numerical Methods in Computational Mathematics