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. Simulation-based emulators of map summary statistics, such as the matter power spectrum and its covariance, are starting to play increasingly important role, as the analytical predictions are expected to reach their precision limits for upcoming experiments. Creating an emulator of the cosmological mass maps themselves, rather than their summary statistics, is a more challenging task. 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 Ωm and matter clustering strength σ 8, parameters which have the largest impact on the evolution of structures in the Universe, for a given source galaxy redshift distribution n(z). 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 Fréchet Inception Distance. We find a very good agreement on these metrics, with typical differences are <5% at the center 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 toward building emulators of mass maps directly, capturing both the cosmological signal and its variability. We make the code 1 and the data 2 publicly available.
Highlights
The N-body technique simulates the evolution of the Universe from soon after the big bang, where the mass distribution was approximately a Gaussian random field, to today, where, under the action of gravity, it becomes highly non-Gaussian
We proposed a new conditional Generative Adversarial Networks (GAN) model for continuous parameters where conditioning is done in the latent space
We demonstrated the ability of this model to generate sky convergence maps when conditioning on the cosmological parameters Ωm and σ8
Summary
The N-body technique simulates the evolution of the Universe from soon after the big bang, where the mass distribution was approximately a Gaussian random field, to today, where, under the action of gravity, it becomes highly non-Gaussian. Emulators have so far focused on: (a) the power spectrum, which is commonly used in cosmology (Knabenhans et al, 2019; Heitmann et al, 2016; Knabenhans et al, 2020; Angulo et al, 2020), (b) covariance matrices of 2-pt functions (Sgier et al, 2019; Taylor et al, 2013; Sato et al, 2011), and (c) non-Gaussian statistics of mass maps, which can be a source of significant additional cosmological information (Pires et al, 2009; Petri et al, 2013; Zürcher et al, 2020; Fluri et al, 2018) These approaches, always considered a specific summary statistic, which limits the type of analysis that can be performed using the massmap data. Appendix A contains the architectures of the neural networks used in this work
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