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Auteurs principaux: Granero-Belinchon, Carlos, Gallucci, Manuel Cabeza
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2307.16580
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author Granero-Belinchon, Carlos
Gallucci, Manuel Cabeza
author_facet Granero-Belinchon, Carlos
Gallucci, Manuel Cabeza
contents This article introduces a new Neural Network stochastic model to generate a 1-dimensional stochastic field with turbulent velocity statistics. Both the model architecture and training procedure ground on the Kolmogorov and Obukhov statistical theories of fully developed turbulence, so guaranteeing descriptions of 1) energy distribution, 2) energy cascade and 3) intermittency across scales in agreement with experimental observations. The model is a Generative Adversarial Network with multiple multiscale optimization criteria. First, we use three physics-based criteria: the variance, skewness and flatness of the increments of the generated field that retrieve respectively the turbulent energy distribution, energy cascade and intermittency across scales. Second, the Generative Adversarial Network criterion, based on reproducing statistical distributions, is used on segments of different length of the generated field. Furthermore, to mimic multiscale decompositions frequently used in turbulence's studies, the model architecture is fully convolutional with kernel sizes varying along the multiple layers of the model. To train our model we use turbulent velocity signals from grid turbulence at Modane wind tunnel.
format Preprint
id arxiv_https___arxiv_org_abs_2307_16580
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A multiscale and multicriteria Generative Adversarial Network to synthesize 1-dimensional turbulent fields
Granero-Belinchon, Carlos
Gallucci, Manuel Cabeza
Machine Learning
Signal Processing
Fluid Dynamics
This article introduces a new Neural Network stochastic model to generate a 1-dimensional stochastic field with turbulent velocity statistics. Both the model architecture and training procedure ground on the Kolmogorov and Obukhov statistical theories of fully developed turbulence, so guaranteeing descriptions of 1) energy distribution, 2) energy cascade and 3) intermittency across scales in agreement with experimental observations. The model is a Generative Adversarial Network with multiple multiscale optimization criteria. First, we use three physics-based criteria: the variance, skewness and flatness of the increments of the generated field that retrieve respectively the turbulent energy distribution, energy cascade and intermittency across scales. Second, the Generative Adversarial Network criterion, based on reproducing statistical distributions, is used on segments of different length of the generated field. Furthermore, to mimic multiscale decompositions frequently used in turbulence's studies, the model architecture is fully convolutional with kernel sizes varying along the multiple layers of the model. To train our model we use turbulent velocity signals from grid turbulence at Modane wind tunnel.
title A multiscale and multicriteria Generative Adversarial Network to synthesize 1-dimensional turbulent fields
topic Machine Learning
Signal Processing
Fluid Dynamics
url https://arxiv.org/abs/2307.16580