The goal of generative models is to learn the intricate relations between the data to create new simulated data, but current approaches fail in very high dimensions. When the true data-generating process is based on physical processes, these impose symmetries and constraints, and the generative model can be created by learning an effective description of the underlying physics, which enables scaling of the generative model to very high dimensions. In this work, we propose Lagrangian deep learning (LDL) for this purpose, applying it to learn outputs of cosmological hydrodynamical simulations. The model uses layers of Lagrangian displacements of particles describing the observables to learn the effective physical laws. The displacements are m...
Running hydrodynamical simulations to produce mock data of large-scale structure and baryonic probes...
The thermal Sunyaev–Zel'dovich (tSZ) and the kinematic Sunyaev–Zel'dovich (kSZ) effects trace the di...
We explore the capability of deep learning to classify cosmic structures. In cosmological simulation...
The goal of generative models is to learn the intricate relations between the data to create new sim...
Matter evolved under the influence of gravity from minuscule density fluctuations. Nonperturbative s...
We address Lagrangian drift simulation in geophysical dynamics and explore deep learning approaches ...
Cosmological data is comprised of dark matter and ordinary matter forming halos, filaments, sheets a...
Deep learning has achieved astonishing results on many tasks with large amounts of data and generali...
International audienceWe present a deep learning model trained to emulate the radiative transfer dur...
Deep learning has achieved astonishing results on many tasks with large amounts of data and general...
We present an extension of our recently developed Wasserstein optimized model to emulate accurate hi...
The linear matter power spectrum is an essential ingredient in all theoretical models for interpreti...
Cosmological simulations of galaxy formation are limited by finite computational resources. We draw ...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
There is ample evidence for the existence of dark matter (DM) from cosmological observations. Howeve...
Running hydrodynamical simulations to produce mock data of large-scale structure and baryonic probes...
The thermal Sunyaev–Zel'dovich (tSZ) and the kinematic Sunyaev–Zel'dovich (kSZ) effects trace the di...
We explore the capability of deep learning to classify cosmic structures. In cosmological simulation...
The goal of generative models is to learn the intricate relations between the data to create new sim...
Matter evolved under the influence of gravity from minuscule density fluctuations. Nonperturbative s...
We address Lagrangian drift simulation in geophysical dynamics and explore deep learning approaches ...
Cosmological data is comprised of dark matter and ordinary matter forming halos, filaments, sheets a...
Deep learning has achieved astonishing results on many tasks with large amounts of data and generali...
International audienceWe present a deep learning model trained to emulate the radiative transfer dur...
Deep learning has achieved astonishing results on many tasks with large amounts of data and general...
We present an extension of our recently developed Wasserstein optimized model to emulate accurate hi...
The linear matter power spectrum is an essential ingredient in all theoretical models for interpreti...
Cosmological simulations of galaxy formation are limited by finite computational resources. We draw ...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
There is ample evidence for the existence of dark matter (DM) from cosmological observations. Howeve...
Running hydrodynamical simulations to produce mock data of large-scale structure and baryonic probes...
The thermal Sunyaev–Zel'dovich (tSZ) and the kinematic Sunyaev–Zel'dovich (kSZ) effects trace the di...
We explore the capability of deep learning to classify cosmic structures. In cosmological simulation...