An iterative data-driven turbulence modeling framework based on Reynolds stress representation

TL;DR

This paper introduces an iterative, data-driven turbulence modeling framework that enhances Reynolds stress representation and coupling with flow solvers, improving accuracy and generalization in flow predictions.

Contribution

It develops a complete tensor representation for Reynolds stress and proposes an iterative coupling framework for better integration with flow solvers.

Findings

High consistency with direct numerical simulation results

Effective tensor representation improves physical interpretability

Iterative coupling enhances convergence and accuracy

Abstract

Data-driven turbulence modeling studies have reached such a stage that the fundamental framework is basically settled, but several essential issues remain that strongly affect the performance, including accuracy, smoothness, and generalization capacity. Two problems are studied in the current research: (1) the processing of the Reynolds stress tensor and (2) the coupling method between the machine learning turbulence model and flow solver. The first determines the form of predicting targets and the resulting physical completeness and interpretability. The second determines the training process and intrinsic relevance between the mean flow features and Reynolds stress. For the Reynolds stress processing issue, we perform the theoretical derivation to extend the relevant tensor arguments of Reynolds stress in addition to the strain rate and rotation rate. Then, the tensor representation theorem is employed to give the complete irreducible invariants and integrity basis. In addition, an adaptive regularization term is employed to enhance the representation performance. For the coupling issue, an iterative coupling data-driven turbulence modeling framework with consistent convergence is proposed. The training data preparation, predicting target selection, and computation platform are illustrated. The framework is then applied to a canonical separated flow for verification. The mean flow results obtained by coupling computation of the trained machine learning model and flow solver have high consistency with the direct numerical simulation true values, which proves the validity of the current approach.