Xiangyu Hu scite author profile

With this study we investigate the accuracy of deep learning models for the inference of Reynolds-Averaged Navier-Stokes solutions. We focus on a modernized Unet architecture, and evaluate a large number of trained neural networks with respect to their accuracy for the calculation of pressure and velocity distributions. In particular, we illustrate how training data size and the number of weights influence the accuracy of the solutions. With our best models we arrive at a mean relative pressure and velocity error of less than 3% across a range of previously unseen airfoil shapes. In addition all source code is publicly available in order to ensure reproducibility and to provide a starting point for researchers interested in deep learning methods for physics problems. While this work focuses on RANS solutions, the neural network architecture and learning setup are very generic, and applicable to a wide range of PDE boundary value problems on Cartesian grids.

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Xiangyu Hu

A multi-phase SPH method for macroscopic and mesoscopic flows

A generalized wall boundary condition for smoothed particle hydrodynamics

An incompressible multi-phase SPH method

Deep Learning Methods for Reynolds-Averaged Navier–Stokes Simulations of Airfoil Flows

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