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On the Generalizability of Machine-Learning-Assisted Anisotropy Mappings for Predictive Turbulence Modelling

Ryley McConkey, Eugene Yee, Fue‐Sang Lien

2022International journal of computational fluid dynamics17 citationsDOI

Abstract

Several machine learning frameworks for augmenting turbulence closure models have been recently proposed. However, the generalizability of an augmented turbulence model remains an open question. We investigate this question by systematically varying the training and test sets of several models. An optimal three-term tensor basis expansion is used to develop a model-agnostic data-driven turbulence closure approximation. Then, hyperparameter optimization is performed for a random forest, a neural network, and an eXtreme Gradient Boosting (XGBoost) model. We recommend XGBoost for data-driven turbulence closure modelling owing to its low-tuning cost and good performance. We also find that machine learning models generalize well to new parametric variations of flows seen in the training dataset, but lack generalizability to new flow types. This generalizability gap suggests that machine learning methods are most suited for developing specialized models for a given flow type, a problem often encountered in industrial applications.

Topics & Concepts

Generalizability theoryMachine learningComputer scienceArtificial intelligenceHyperparameterArtificial neural networkParametric statisticsTurbulenceClosure (psychology)Parametric modelMathematical optimizationMathematicsPhysicsStatisticsMarket economyEconomicsThermodynamicsFluid Dynamics and Turbulent FlowsFluid Dynamics and Vibration AnalysisModel Reduction and Neural Networks
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