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Data-driven subgrid-scale modeling of forced Burgers turbulence using deep learning with generalization to higher Reynolds numbers via transfer learning

Adam Subel, Ashesh Chattopadhyay, Yifei Guan, Pedram Hassanzadeh

2021Physics of Fluids62 citationsDOIOpen Access PDF

Abstract

Developing data-driven subgrid-scale (SGS) models for large eddy simulations (LESs) has received substantial attention recently. Despite some success, particularly in a priori (offline) tests, challenges have been identified that include numerical instabilities in a posteriori (online) tests and generalization (i.e., extrapolation) of trained data-driven SGS models, for example, to higher Reynolds numbers. Here, using the stochastically forced Burgers turbulence as the test-bed, we show that deep neural networks trained using properly pre-conditioned (augmented) data yield stable and accurate a posteriori LES models. Furthermore, we show that transfer learning enables accurate/stable generalization to a flow with 10× higher Reynolds number.

Topics & Concepts

GeneralizationReynolds numberA priori and a posterioriPhysicsTurbulenceLarge eddy simulationArtificial neural networkApplied mathematicsStatistical physicsDeep learningArtificial intelligenceFlow (mathematics)Turbulence modelingTransfer of learningReynolds stress equation modelMechanicsComputational fluid dynamicsBurgers' equationMathematical analysisReynolds stressReynolds equationTransfer (computing)Direct numerical simulationClassical mechanicsModel Reduction and Neural NetworksFluid Dynamics and Turbulent FlowsGenerative Adversarial Networks and Image Synthesis
Data-driven subgrid-scale modeling of forced Burgers turbulence using deep learning with generalization to higher Reynolds numbers via transfer learning | Litcius