From Dark Matter to Galaxies with Convolutional Networks

TL;DR

This paper introduces a deep learning approach using convolutional networks to rapidly generate galaxy catalogs from dark matter simulations, offering a computationally efficient alternative to traditional methods.

Contribution

The authors develop a two-phase convolutional neural network that models the complex mapping between dark matter and galaxy distributions, outperforming or matching standard cosmological techniques.

Findings

Outperforms traditional cosmological methods in accuracy.

Achieves comparable speed to the fastest existing benchmarks.

Provides a scalable approach for analyzing large cosmological datasets.

Abstract

Cosmological surveys aim at answering fundamental questions about our Universe, including the nature of dark matter or the reason of unexpected accelerated expansion of the Universe. In order to answer these questions, two important ingredients are needed: 1) data from observations and 2) a theoretical model that allows fast comparison between observation and theory. Most of the cosmological surveys observe galaxies, which are very difficult to model theoretically due to the complicated physics involved in their formation and evolution; modeling realistic galaxies over cosmological volumes requires running computationally expensive hydrodynamic simulations that can cost millions of CPU hours. In this paper, we propose to use deep learning to establish a mapping between the 3D galaxy distribution in hydrodynamic simulations and its underlying dark matter distribution. One of the major challenges in this pursuit is the very high sparsity in the predicted galaxy distribution. To this end, we develop a two-phase convolutional neural network architecture to generate fast galaxy catalogues, and compare our results against a standard cosmological technique. We find that our proposed approach either outperforms or is competitive with traditional cosmological techniques. Compared to the common methods used in cosmology, our approach also provides a nice trade-off between time-consumption (comparable to fastest benchmark in the literature) and the quality and accuracy of the predicted simulation. In combination with current and upcoming data from cosmological observations, our method has the potential to answer fundamental questions about our Universe with the highest accuracy.