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 acr...
The problem of classifying turbulent environments from partial observation is key for some theoretic...
This study proposes a newly-developed deep-learning-based method to generate turbulent inflow condit...
International audienceClosed-loop turbulence control has current and future engineering applications...
This article introduces a new Neural Network stochastic model to generate a 1-dimensional stochastic...
We define and study a fully-convolutional neural network stochastic model, NN-Turb, which generates ...
We define and study a fully-convolutional neural network stochastic model, NN-Turb, which generates ...
International audienceWe define and study a fully-convolutional neural network stochastic model, NN-...
Data sets for the two numerical examples in the paper Multi-fidelity Generative Deep Learning Turbul...
Though turbulence is often thought to have universal behavior regardless of origin, it may be possib...
In this article, we demonstrate the use of artificial neural networks as optimal maps which are util...
In this paper, deep learning (DL) methods are evaluated in the context of turbulent flows. Various g...
The goal of the study was to generate, from a simple set of rules, a stochastic signal in space-time...
Turbulence remains a problem that is yet to be fully understood, with experimental and numerical stu...
The problem of classifying turbulent environments from partial observation is key for some theoretic...
The problem of classifying turbulent environments from partial observation is key for some theoretic...
This study proposes a newly-developed deep-learning-based method to generate turbulent inflow condit...
International audienceClosed-loop turbulence control has current and future engineering applications...
This article introduces a new Neural Network stochastic model to generate a 1-dimensional stochastic...
We define and study a fully-convolutional neural network stochastic model, NN-Turb, which generates ...
We define and study a fully-convolutional neural network stochastic model, NN-Turb, which generates ...
International audienceWe define and study a fully-convolutional neural network stochastic model, NN-...
Data sets for the two numerical examples in the paper Multi-fidelity Generative Deep Learning Turbul...
Though turbulence is often thought to have universal behavior regardless of origin, it may be possib...
In this article, we demonstrate the use of artificial neural networks as optimal maps which are util...
In this paper, deep learning (DL) methods are evaluated in the context of turbulent flows. Various g...
The goal of the study was to generate, from a simple set of rules, a stochastic signal in space-time...
Turbulence remains a problem that is yet to be fully understood, with experimental and numerical stu...
The problem of classifying turbulent environments from partial observation is key for some theoretic...
The problem of classifying turbulent environments from partial observation is key for some theoretic...
This study proposes a newly-developed deep-learning-based method to generate turbulent inflow condit...
International audienceClosed-loop turbulence control has current and future engineering applications...