Bayesian Optimization of the GEKO Turbulence Model for Predicting Flow Separation Over a Smooth Surface
Abstract
This paper applies Bayesian-optimization-RANS (turbo-RANS) to improve Reynolds-averaged Navier-Stokes (RANS) turbulence models for a converging-diverging channel, a case with adverse pressure gradients and flow separation. Using Bayesian optimization, the Generalized k-ω (GEKO) model was calibrated by tuning CSEP and CNW with sparse direct numerical simulation (DNS) data at Re = 12,600. The calibration followed the Generalized Error Distribution-based Calibration Procedure (GEDCP), optimizing coefficients based on pressure recovery (Cp) and skin friction (Cf). The optimized model was evaluated beyond training data. Streamwise velocity (U) predictions at Re = 12,600 were compared to DNS to assess improvements in Cp and Cf. To test robustness, comparisons were made against large-eddy simulation (LES) data at Re = 20,580 for velocity and skin friction. Results show that optimized GEKO (turbo-RANS) improves wall quantity predictions, particularly reattachment. Improved velocity profiles at both Reynolds numbers suggest Bayesian-optimized coefficients enhance adverse pressure gradient modeling. The model retains accuracy across different Re, showing turbo-RANS' potential in turbulence model corrections that generalize across flows. While skin friction predictions showed limited improvement due to constraints of two-equation models, this study highlights the role of machine learning-assisted RANS calibration in improving predictive accuracy for complex flows. The results suggest optimized coefficients from a single dataset can be applied across moderate Re variations, improving turbo-RANS' applicability for turbulence model tuning.
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