Abstract
Abstract Accurate prediction of laminar-turbulent transition is a critical element of computational fluid dynamics simulations for aerodynamic design across multiple flow regimes. Traditional methods of transition prediction cannot be easily extended to flow configurations where the transition process depends on a large set of parameters. In comparison, neural network methods allow higher dimensional input features to be considered without compromising the efficiency and accuracy of the traditional data-driven models. Neural network methods proposed earlier follow a cumbersome methodology of predicting instability growth rates over a broad range of frequencies, which are then processed to obtain the N-factor envelope, and then, the transition location based on the correlating N-factor. This paper presents an end-to-end transition model based on a recurrent neural network, which sequentially processes the mean boundary-layer profiles along the surface of the aerodynamic body to directly predict the N-factor envelope and the transition locations over a two-dimensional airfoil. The proposed transition model has been developed and assessed using a large database of 53 airfoils over a wide range of chord Reynolds numbers and angles of attack. The large universe of airfoils encountered in various applications causes additional difficulties. As such, we provide further insights on selecting training datasets from large amounts of available data. Although the proposed model has been analyzed for two-dimensional boundary layers in this paper, it can be easily generalized to other flows due to embedded feature extraction capability of convolutional neural network in the model.
Highlights
Impact Statement The recurrent neural network (RNN) proposed here represents a significant step toward an end-to-end prediction of laminar-turbulent transition in boundary-layer flows
A sequence-to-sequence modeling approach based on a recurrent neural network has been proposed to predict the location of laminar-turbulent transition via linear amplification characteristics of hydrodynamic instabilities in boundary-layer flows
The results demonstrate that the RNN model is able to predict the transition location at various test flow conditions and for the entire range of airfoil contours with good accuracy despite being trained by a small subsample of the complete database
Summary
Impact Statement The recurrent neural network (RNN) proposed here represents a significant step toward an end-to-end prediction of laminar-turbulent transition in boundary-layer flows. Several methods have been proposed as simplifications or surrogate models of the eN methods, including database query techniques (Drela and Giles, 1987; van Ingen, 2008; Perraud and Durant, 2016) and data fitting techniques (Dagenhart, 1981; Stock and Degenhart, 1989; Gaster and Jiang, 1995; Langlois et al, 2002; Krumbein, 2008; Rajnarayan and Sturdza, 2013; Begou et al, 2017; Pinna et al, 2018) These methods are generally based on a small set of scalar input parameters representing the mean flow parameters and relevant disturbance characteristics. The shape factor cannot be computed for many practical flows such as high speed flows
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