Litcius/Paper detail

Graph neural networks for laminar flow prediction around random two-dimensional shapes

Junfeng Chen, Elie Hachem, Jonathan Viquerat

2021Physics of Fluids93 citationsDOI

Abstract

In recent years, the domain of fast flow field prediction has been vastly dominated by pixel-based convolutional neural networks. Yet, the recent advent of graph convolutional neural networks (GCNNs) has attracted considerable attention in the computational fluid dynamics (CFD) community. In this contribution, we proposed a GCNN structure as a surrogate model for laminar flow prediction around two-dimensional (2D) obstacles. Unlike traditional convolution on image pixels, the graph convolution can be directly applied on body-fitted triangular meshes, hence yielding an easy coupling with CFD solvers. The proposed GCNN model is trained over a dataset composed of CFD-computed laminar flows around 2000 random 2D shapes. Accuracy levels are assessed on reconstructed velocity and pressure fields around out-of-training obstacles and are compared with that of standard U-net architectures, especially in the boundary layer area.

Topics & Concepts

Laminar flowComputational fluid dynamicsConvolutional neural networkPhysicsPolygon meshAlgorithmGraphConditional random fieldPixelArtificial intelligenceConvolution (computer science)Artificial neural networkMarkov random fieldPattern recognition (psychology)Computer scienceTheoretical computer scienceMechanicsImage (mathematics)Image segmentationComputer graphics (images)Model Reduction and Neural NetworksLattice Boltzmann Simulation StudiesFluid Dynamics and Turbulent Flows