Abstract
We present a single-layer feed-forward artificial neural network architecture trained through a supervised learning approach for the deconvolution of flow variables from their coarse-grained computations such as those encountered in large eddy simulations. We stress that the deconvolution procedure proposed in this investigation is blind, i.e. the deconvolved field is computed without any pre-existing information about the filtering procedure or kernel. This may be conceptually contrasted to the celebrated approximate deconvolution approaches where a filter shape is predefined for an iterative deconvolution process. We demonstrate that the proposed blind deconvolution network performs exceptionally well in the a priori testing of two-dimensional Kraichnan, three-dimensional Kolmogorov and compressible stratified turbulence test cases, and shows promise in forming the backbone of a physics-augmented data-driven closure for the Navier–Stokes equations.
Publisher
Cambridge University Press (CUP)
Subject
Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics
Reference48 articles.
1. Estimating the effective Reynolds number in implicit large-eddy simulation;Zhou;Phys. Rev. E,2014
2. Machine learning methods for data-driven turbulence modeling;Zhang;AIAA Paper,2015
3. A novel evolutionary algorithm applied to algebraic modifications of the RANS stress–strain relationship
4. Image deblurring with filters learned by extreme learning machine
5. Wang, J. , Wu, J. & Xiao, H. 2016 Physics-informed machine learning for predictive turbulence modeling: Using data to improve RANS modeled Reynolds stresses. arXiv:1606.07987.
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