Influence of adversarial training on super-resolution turbulence reconstruction
Influence of adversarial training on super-resolution turbulence reconstruction
Supervised super-resolution deep convolutional neural networks (CNNs) have gained significant attention for their potential in reconstructing velocity and scalar fields in turbulent flows. Despite their popularity, CNNs currently lack the ability to accurately produce high-frequency and small-scale features, and tests of their generalizability to out-of-sample flows are not widespread. Generative adversarial networks (GANs), which consist of two distinct neural networks (NNs), a generator and discriminator, are a promising alternative, allowing for both semisupervised and unsupervised training. The difference in the flow fields produced by these two NN architectures has not been thoroughly investigated, and a comprehensive understanding of the discriminator's role has yet to be developed. This study assesses the effectiveness of the unsupervised adversarial training in GANs for turbulence reconstruction in forced homogeneous isotropic turbulence. GAN-based architectures are found to outperform supervised CNNs for turbulent flow reconstruction for in-sample cases. The reconstruction accuracy of both architectures diminishes for out-of-sample cases, though the GAN's discriminator network significantly improves the generator's out-of-sample robustness using either an additional unsupervised training step with large eddy simulation input fields or a dynamic selection of the most suitable upsampling factor. These enhance the generator's ability to reconstruct small-scale gradients, turbulence intermittency, and velocity-gradient probability density functions. Conversely, the supervised super-resolution CNN network lacks the capability to reconstruct these statistics. The extrapolation capability of the GAN-based model is demonstrated for out-of-sample flows at higher Reynolds numbers. Based on these findings, incorporating discriminator-based training is recommended to enhance the reconstruction capability of super-resolution CNNs.
Nista, Ludovico
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Pitsch, Heinz
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Schumann, Christoph D.K.
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Bode, Mathis
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Grenga, Temistocle
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MacArt, Jonathan F.
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Attili, Antonio
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4 June 2024
Nista, Ludovico
a93303b2-3e96-484b-a8d1-cf11e1588814
Pitsch, Heinz
3dc0eb6e-deca-4742-98a1-f0cdd62ff8b8
Schumann, Christoph D.K.
4b993966-a0c3-438b-a2f0-0151e87d42cf
Bode, Mathis
50cb6909-eaa8-4a7c-b24e-5be18240a6a5
Grenga, Temistocle
be0eba30-74b5-4134-87e7-3a2d6dd3836f
MacArt, Jonathan F.
1384a548-486e-4fae-9d5c-4177b0ed7825
Attili, Antonio
cd357d33-94e2-4a14-9aa0-9126a18687d0
Nista, Ludovico, Pitsch, Heinz, Schumann, Christoph D.K., Bode, Mathis, Grenga, Temistocle, MacArt, Jonathan F. and Attili, Antonio
(2024)
Influence of adversarial training on super-resolution turbulence reconstruction.
Physical Review Fluids, 9 (6), [064601].
(doi:10.1103/PhysRevFluids.9.064601).
Abstract
Supervised super-resolution deep convolutional neural networks (CNNs) have gained significant attention for their potential in reconstructing velocity and scalar fields in turbulent flows. Despite their popularity, CNNs currently lack the ability to accurately produce high-frequency and small-scale features, and tests of their generalizability to out-of-sample flows are not widespread. Generative adversarial networks (GANs), which consist of two distinct neural networks (NNs), a generator and discriminator, are a promising alternative, allowing for both semisupervised and unsupervised training. The difference in the flow fields produced by these two NN architectures has not been thoroughly investigated, and a comprehensive understanding of the discriminator's role has yet to be developed. This study assesses the effectiveness of the unsupervised adversarial training in GANs for turbulence reconstruction in forced homogeneous isotropic turbulence. GAN-based architectures are found to outperform supervised CNNs for turbulent flow reconstruction for in-sample cases. The reconstruction accuracy of both architectures diminishes for out-of-sample cases, though the GAN's discriminator network significantly improves the generator's out-of-sample robustness using either an additional unsupervised training step with large eddy simulation input fields or a dynamic selection of the most suitable upsampling factor. These enhance the generator's ability to reconstruct small-scale gradients, turbulence intermittency, and velocity-gradient probability density functions. Conversely, the supervised super-resolution CNN network lacks the capability to reconstruct these statistics. The extrapolation capability of the GAN-based model is demonstrated for out-of-sample flows at higher Reynolds numbers. Based on these findings, incorporating discriminator-based training is recommended to enhance the reconstruction capability of super-resolution CNNs.
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e-pub ahead of print date: 4 June 2024
Published date: 4 June 2024
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Local EPrints ID: 499345
URI: http://eprints.soton.ac.uk/id/eprint/499345
ISSN: 2469-990X
PURE UUID: f97f6127-25eb-4ed0-9730-cb49c2d71253
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Date deposited: 17 Mar 2025 17:56
Last modified: 18 Mar 2025 03:11
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Author:
Ludovico Nista
Author:
Heinz Pitsch
Author:
Christoph D.K. Schumann
Author:
Mathis Bode
Author:
Temistocle Grenga
Author:
Jonathan F. MacArt
Author:
Antonio Attili
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