Litcius/Paper detail

An artificial viscosity augmented physics-informed neural network for incompressible flow

Yichuan He, Zhicheng Wang, Hui Xiang, Xiaomo Jiang, Dawei Tang

2023Applied Mathematics and Mechanics34 citationsDOIOpen Access PDF

Abstract

Abstract Physics-informed neural networks (PINNs) are proved methods that are effective in solving some strongly nonlinear partial differential equations (PDEs), e.g., Navier-Stokes equations, with a small amount of boundary or interior data. However, the feasibility of applying PINNs to the flow at moderate or high Reynolds numbers has rarely been reported. The present paper proposes an artificial viscosity (AV)-based PINN for solving the forward and inverse flow problems. Specifically, the AV used in PINNs is inspired by the entropy viscosity method developed in conventional computational fluid dynamics (CFD) to stabilize the simulation of flow at high Reynolds numbers. The newly developed PINN is used to solve the forward problem of the two-dimensional steady cavity flow at Re = 1 000 and the inverse problem derived from two-dimensional film boiling. The results show that the AV augmented PINN can solve both problems with good accuracy and substantially reduce the inference errors in the forward problem.

Topics & Concepts

Reynolds numberArtificial neural networkCompressibilityFlow (mathematics)Nonlinear systemComputational fluid dynamicsInverse problemViscosityBoundary value problemFluid dynamicsComputer scienceApplied mathematicsPartial differential equationMathematicsPhysicsMechanicsMathematical analysisArtificial intelligenceThermodynamicsTurbulenceQuantum mechanicsModel Reduction and Neural NetworksFluid Dynamics and Turbulent FlowsHeat Transfer Mechanisms