Emulation of cosmological mass maps with conditional generative
adversarial networks
- URL: http://arxiv.org/abs/2004.08139v2
- Date: Thu, 6 May 2021 09:32:38 GMT
- Title: Emulation of cosmological mass maps with conditional generative
adversarial networks
- Authors: Nathana\"el Perraudin, Sandro Marcon, Aurelien Lucchi, Tomasz Kacprzak
- Abstract summary: We propose a novel conditional GAN model that is able to generate mass maps for any pair of matter density $Omega_m$ and matter clustering strength $sigma_8$.
Our results show that our conditional GAN can interpolate efficiently within the space of simulated cosmologies.
This contribution is a step towards building emulators of mass maps directly, capturing both the cosmological signal and its variability.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Weak gravitational lensing mass maps play a crucial role in understanding the
evolution of structures in the universe and our ability to constrain
cosmological models. The prediction of these mass maps is based on expensive
N-body simulations, which can create a computational bottleneck for
cosmological analyses. Modern deep generative models, such as Generative
Adversarial Networks (GAN), have demonstrated their potential to achieve this
goal. Most existing GAN approaches produce simulations for a fixed value of the
cosmological parameters, which limits their practical applicability. We propose
a novel conditional GAN model that is able to generate mass maps for any pair
of matter density $\Omega_m$ and matter clustering strength $\sigma_8$,
parameters which have the largest impact on the evolution of structures in the
universe. Our results show that our conditional GAN can interpolate efficiently
within the space of simulated cosmologies, and generate maps anywhere inside
this space with good visual quality high statistical accuracy. We perform an
extensive quantitative comparison of the N-body and GAN -generated maps using a
range of metrics: the pixel histograms, peak counts, power spectra, bispectra,
Minkowski functionals, correlation matrices of the power spectra, the
Multi-Scale Structural Similarity Index (MS-SSIM) and our equivalent of the
Fr\'echet Inception Distance (FID). We find a very good agreement on these
metrics, with typical differences are <5% at the centre of the simulation grid,
and slightly worse for cosmologies at the grid edges. The agreement for the
bispectrum is slightly worse, on the <20% level. This contribution is a step
towards building emulators of mass maps directly, capturing both the
cosmological signal and its variability. We make the code and the data publicly
available: https://renkulab.io/gitlab/nathanael.perraudin/darkmattergan
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