Add to ORKGWe introduce in this paper new, efficient numerical methods based on neural networks for the approximation of the mean curvature flow of either oriented or non-orientable surfaces. To learn the correct interface evolution law, our neural networks are trained on phase field representations of exact evolving interfaces. The structure of the networks draws inspiration from splitting schemes used for the discretization of the Allen-Cahn equation. But when the latter approximates the mean curvature motion of oriented interfaces only, the approach we propose extends very naturally to the non-orientable case. In addition, although trained on smooth flows only, our networks can handle singularities as well. Furthermore, they can be coupled easily w...
A neural network-based system for recovering 3-D motion information of curved surfaces from 2-D opti...
The highly non-linear nature of deep neural networks causes them to be susceptible to adversarial ex...
This thesis is devoted to the rigorous study of approximations for (multi-phase) mean curvature flow...
We introduce in this paper new, efficient numerical methods based on neural networks for the approxi...
International audienceWe introduce in this paper new and very effective numerical methods based on n...
The complex flow modeling based on machine learning is becoming a promising way to describe multipha...
The volume of fluid (VOF) method is widely used to simulate the flow of immiscible fluids. It uses a...
The volume of fluid (VOF) method is widely used to simulate the flow of immiscible fluids. It uses a...
The volume of fluid (VoF) method is widely used in multi-phase flow simulations to track and locate ...
This review concerns the computation of curvature-dependent interface motion governed by geometric p...
We present a machine learning framework that blends image super-resolution technologies with passive...
International audienceThis paper is concerned with the numerical approximation of mean curvature flo...
Neural networks are increasingly used in complex (data-driven) simulations as surrogates or for acce...
Phase-field models such as the Allen-Cahn equation may give rise to the formation and evolution of g...
A neural network-based system for recovering 3-D motion information of curved surfaces from 2-D opti...
The highly non-linear nature of deep neural networks causes them to be susceptible to adversarial ex...
This thesis is devoted to the rigorous study of approximations for (multi-phase) mean curvature flow...
We introduce in this paper new, efficient numerical methods based on neural networks for the approxi...
International audienceWe introduce in this paper new and very effective numerical methods based on n...
The complex flow modeling based on machine learning is becoming a promising way to describe multipha...
The volume of fluid (VOF) method is widely used to simulate the flow of immiscible fluids. It uses a...
The volume of fluid (VOF) method is widely used to simulate the flow of immiscible fluids. It uses a...
The volume of fluid (VoF) method is widely used in multi-phase flow simulations to track and locate ...
This review concerns the computation of curvature-dependent interface motion governed by geometric p...
We present a machine learning framework that blends image super-resolution technologies with passive...
International audienceThis paper is concerned with the numerical approximation of mean curvature flo...
Neural networks are increasingly used in complex (data-driven) simulations as surrogates or for acce...
Phase-field models such as the Allen-Cahn equation may give rise to the formation and evolution of g...
A neural network-based system for recovering 3-D motion information of curved surfaces from 2-D opti...
The highly non-linear nature of deep neural networks causes them to be susceptible to adversarial ex...
This thesis is devoted to the rigorous study of approximations for (multi-phase) mean curvature flow...