Neural networks optimized by genetic algorithms in cosmology

The applications of artificial neural networks in the cosmological field have shone successfully during the past decade, this is due to their great ability of modeling large amounts of datasets and complex nonlinear functions. However, in some cases, their use still remains controversial because their ease of producing inaccurate results when the hyperparameters are not carefully selected. In this paper, to find the optimal combination of hyperparameters to artificial neural networks, we propose to take advantage of the genetic algorithms. As a proof of the concept, we analyze three different cosmological cases to test the performance of the architectures achieved with the genetic algorithms and compare them with the standard process, consisting of a grid with all possible configurations. First, we carry out a model-independent reconstruction of the distance modulus using a type Ia supernovae compilation. Second, the neural networks learn to infer the equation of state for the quintessence model, and finally with the data from a combined redshift catalog the neural networks predict the photometric redshift given six photometric bands (urgizy). We found that the genetic algorithms improve considerably the generation of the neural network architectures, which can ensure more confidence in their physical results because of the better performance in the metrics with respect to the grid method.

Automated summary

The applications of artificial neural networks in cosmology have been successful due to their ability to model large datasets and nonlinear functions. However, their use can be controversial due to the potential for inaccurate results when hyperparameters are not carefully selected. In this paper, the use of genetic algorithms to find optimal hyperparameter combinations for neural networks is proposed and tested on three different cosmological cases, showing improved performance compared to a standard grid method.