Neural network reconstructions for the Hubble parameter, growth rate and distance modulus

Isidro Gómez-Vargas; Ricardo Medel-Esquivel; Ricardo García-Salcedo; J. Alberto Vázquez

doi:10.1140/epjc/s10052-023-11435-9

Neural network reconstructions for the Hubble parameter, growth rate and distance modulus

Isidro Gómez-Vargas, Ricardo Medel-Esquivel, Ricardo García-Salcedo, J. Alberto Vázquez

Centro de Investigación en Ciencia Aplicada y Tecnología Avanzada (CICATA), Unidad Legaria

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

This paper introduces a new approach to reconstruct cosmological functions using artificial neural networks based on observational measurements with minimal theoretical and statistical assumptions. By using neural networks, we can generate computational models of observational datasets, and then we compare them with the original ones to verify the consistency of our method. This methodology is applicable to even small-size datasets. In particular, we test the proposed method with data coming from cosmic chronometers, fσ₈ measurements, and the distance modulus of the Type Ia supernovae. Furthermore, we introduce a first approach to generate synthetic covariance matrices through a variational autoencoder, using the systematic covariance matrix of the Type Ia supernova compilation.

Original language	English
Article number	304
Journal	European Physical Journal C
Volume	83
Issue number	4
DOIs	https://doi.org/10.1140/epjc/s10052-023-11435-9
State	Published - Apr 2023

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title = "Neural network reconstructions for the Hubble parameter, growth rate and distance modulus",

abstract = "This paper introduces a new approach to reconstruct cosmological functions using artificial neural networks based on observational measurements with minimal theoretical and statistical assumptions. By using neural networks, we can generate computational models of observational datasets, and then we compare them with the original ones to verify the consistency of our method. This methodology is applicable to even small-size datasets. In particular, we test the proposed method with data coming from cosmic chronometers, fσ8 measurements, and the distance modulus of the Type Ia supernovae. Furthermore, we introduce a first approach to generate synthetic covariance matrices through a variational autoencoder, using the systematic covariance matrix of the Type Ia supernova compilation.",

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AU - Gómez-Vargas, Isidro

AU - Medel-Esquivel, Ricardo

AU - García-Salcedo, Ricardo

AU - Vázquez, J. Alberto

PY - 2023/4

Y1 - 2023/4

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AB - This paper introduces a new approach to reconstruct cosmological functions using artificial neural networks based on observational measurements with minimal theoretical and statistical assumptions. By using neural networks, we can generate computational models of observational datasets, and then we compare them with the original ones to verify the consistency of our method. This methodology is applicable to even small-size datasets. In particular, we test the proposed method with data coming from cosmic chronometers, fσ8 measurements, and the distance modulus of the Type Ia supernovae. Furthermore, we introduce a first approach to generate synthetic covariance matrices through a variational autoencoder, using the systematic covariance matrix of the Type Ia supernova compilation.

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Neural network reconstructions for the Hubble parameter, growth rate and distance modulus

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