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Learned turbulence modelling with differentiable fluid solvers: physics-based loss functions and optimisation horizons

Bjoern List, Liwei Chen, Nils Thuerey

2022Journal of Fluid Mechanics63 citationsDOIOpen Access PDF

Abstract

In this paper, we train turbulence models based on convolutional neural networks. These learned turbulence models improve under-resolved low-resolution solutions to the incompressible Navier–Stokes equations at simulation time. Our study involves the development of a differentiable numerical solver that supports the propagation of optimisation gradients through multiple solver steps. The significance of this property is demonstrated by the superior stability and accuracy of those models that unroll more solver steps during training. Furthermore, we introduce loss terms based on turbulence physics that further improve the model accuracy. This approach is applied to three two-dimensional turbulence flow scenarios, a homogeneous decaying turbulence case, a temporally evolving mixing layer and a spatially evolving mixing layer. Our models achieve significant improvements of long-term a posteriori statistics when compared with no-model simulations, without requiring these statistics to be directly included in the learning targets. At inference time, our proposed method also gains substantial performance improvements over similarly accurate, purely numerical methods.

Topics & Concepts

SolverTurbulenceComputer scienceTurbulence modelingMixing (physics)Differentiable functionApplied mathematicsK-epsilon turbulence modelComputational fluid dynamicsDirect numerical simulationStatistical physicsPhysicsMechanicsMathematicsReynolds numberMathematical analysisProgramming languageQuantum mechanicsModel Reduction and Neural NetworksFluid Dynamics and Turbulent FlowsLattice Boltzmann Simulation Studies
Learned turbulence modelling with differentiable fluid solvers: physics-based loss functions and optimisation horizons | Litcius