Using machine learning to compress the matter transfer function $T(k)$
Abstract
The linear matter power spectrum connects theory with large scale structure observations in cosmology. Its scale dependence is entirely encoded in the matter transfer function , which can be computed numerically by Boltzmann solvers, and can also be computed semi-analytically by using fitting functions such as the well-known Bardeen-Bond-Kaiser-Szalay (BBKS) and Eisenstein-Hu (EH) formulae. However, both the BBKS and EH formulae have some significant drawbacks. On the one hand, although BBKS is a simple expression, it is only accurate up to , which is well above the precision goal of forthcoming surveys. On the other hand, while EH is as accurate as required by upcoming experiments, it is a rather long and complicated expression. Here, we use the Genetic Algorithms (GAs), a particular machine learning technique, to derive simple and accurate fitting formulae for the transfer function . When the effects of massive neutrinos are also considered, our expression slightly improves over the EH formula, while being notably shorter in comparison.
Cite
@article{arxiv.2211.06393,
title = {Using machine learning to compress the matter transfer function $T(k)$},
author = {J. Bayron Orjuela-Quintana and Savvas Nesseris and Wilmar Cardona},
journal= {arXiv preprint arXiv:2211.06393},
year = {2023}
}
Comments
12 pages, 7 figures, 2 tables. Changes match published version