# The miniJPAS survey quasar selection II: Machine learning classification   with photometric measurements and uncertainties

**Authors:** Nat\'alia V.N. Rodrigues, L. Raul Abramo, Carolina Queiroz, Gin\'es, Mart\'inez-Solaeche, Ignasi P\'erez-R\`afols, Silvia Bonoli, Jon\'as, Chaves-Montero, Matthew M. Pieri, Rosa M. Gonz\'alez Delgado, Sean S., Morrison, Valerio Marra, Isabel M\'arquez, A. Hern\'an-Caballero, L.A., D\'iaz-Garc\'ia, Narciso Ben\'itez, A. Javier Cenarro, Renato A. Dupke,, Alessandro Ederoclite, Carlos L\'opez-Sanjuan, Antonio Mar\'in-Franch,, Claudia Mendes de Oliveira, Mariano Moles, Laerte Sodr\'e Jr., Jes\'us, Varela, H\'ector V\'azquez Rami\'o, Keith Taylor

arXiv: 2303.00489 · 2023-03-02

## TL;DR

This paper introduces a CNN-based machine learning method that incorporates measurement errors to classify stars, galaxies, and quasars in the miniJPAS survey, demonstrating improved accuracy over traditional methods.

## Contribution

It presents a novel CNN approach that uses photometric uncertainties for source classification, validated on miniJPAS data and mock catalogs, enhancing quasar detection capabilities.

## Key findings

- CNNs outperform decision trees when errors are included
- Classification results align with expected luminosity functions
- Method proves effective for large-scale quasar identification

## Abstract

Astrophysical surveys rely heavily on the classification of sources as stars, galaxies or quasars from multi-band photometry. Surveys in narrow-band filters allow for greater discriminatory power, but the variety of different types and redshifts of the objects present a challenge to standard template-based methods. In this work, which is part of larger effort that aims at building a catalogue of quasars from the miniJPAS survey, we present a Machine Learning-based method that employs Convolutional Neural Networks (CNNs) to classify point-like sources including the information in the measurement errors. We validate our methods using data from the miniJPAS survey, a proof-of-concept project of the J-PAS collaboration covering $\sim$ 1 deg$^2$ of the northern sky using the 56 narrow-band filters of the J-PAS survey. Due to the scarcity of real data, we trained our algorithms using mocks that were purpose-built to reproduce the distributions of different types of objects that we expect to find in the miniJPAS survey, as well as the properties of the real observations in terms of signal and noise. We compare the performance of the CNNs with other well-established Machine Learning classification methods based on decision trees, finding that the CNNs improve the classification when the measurement errors are provided as inputs. The predicted distribution of objects in miniJPAS is consistent with the putative luminosity functions of stars, quasars and unresolved galaxies. Our results are a proof-of-concept for the idea that the J-PAS survey will be able to detect unprecedented numbers of quasars with high confidence.

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/2303.00489/full.md

## References

69 references — full list in the complete paper: https://tomesphere.com/paper/2303.00489/full.md

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Source: https://tomesphere.com/paper/2303.00489