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Physics-informed deep learning for incompressible laminar flows

Chengping Rao, Hao Sun, Yang Liu

2020Theoretical and Applied Mechanics Letters303 citationsDOIOpen Access PDF

Abstract

Physics-informed deep learning has drawn tremendous interest in recent years to solve computational physics problems, whose basic concept is to embed physical laws to constrain/inform neural networks, with the need of less data for training a reliable model. This can be achieved by incorporating the residual of physics equations into the loss function. Through minimizing the loss function, the network could approximate the solution. In this paper, we propose a mixed-variable scheme of physics-informed neural network (PINN) for fluid dynamics and apply it to simulate steady and transient laminar flows at low Reynolds numbers. A parametric study indicates that the mixed-variable scheme can improve the PINN trainability and the solution accuracy. The predicted velocity and pressure fields by the proposed PINN approach are also compared with the reference numerical solutions. Simulation results demonstrate great potential of the proposed PINN for fluid flow simulation with a high accuracy.

Topics & Concepts

Laminar flowArtificial neural networkCompressibilityReynolds numberDeep learningTransient (computer programming)Parametric statisticsFlow (mathematics)Computer scienceResidualIncompressible flowComputational fluid dynamicsFluid dynamicsApplied mathematicsScheme (mathematics)MechanicsComputer simulationPhysicsFluid mechanicsMathematicsPhysical lawStatistical physicsArtificial intelligenceClassical mechanicsControl theory (sociology)Pressure-correction methodDirect numerical simulationNavier–Stokes equationsModel Reduction and Neural NetworksGenerative Adversarial Networks and Image SynthesisNeural Networks and Reservoir Computing
Physics-informed deep learning for incompressible laminar flows | Litcius