CzSL: Learning from citizen science, experts, and unlabelled data in astronomical image classification
Metadatos
Mostrar el registro completo del ítemEditorial
Oxford University Press
Materia
Galaxies: general Methods: data analysis Software: development
Fecha
2023-09-19Referencia bibliográfica
Manuel Jiménez, Emilio J Alfaro, Mercedes Torres Torres, Isaac Triguero, CzSL: Learning from citizen science, experts, and unlabelled data in astronomical image classification, Monthly Notices of the Royal Astronomical Society, Volume 526, Issue 2, December 2023, Pages 1742–1756, [https://doi.org/10.1093/mnras/stad2852]
Patrocinador
Center of Excellence Severo Ochoa’ award to the Instituto de Astrof ´ısica de Andaluc ´ıa (grant no. SEV-2017-0709); A-TIC-434-UGR20 and PID2020-119478GB-I00; NVIDIA CorporationResumen
Citizen science is gaining popularity as a valuable tool for labelling large collections of astronomical images by the general public. This is often achieved at the cost of poorer quality classifications made by amateur participants, which are usually verified by employing smaller data sets labelled by professional astronomers. Despite its success, citizen science alone will not be able to handle the classification of current and upcoming surv e ys. To alleviate this issue, citizen science projects have been coupled with machine learning techniques in pursuit of a more robust automated classification. Ho we v er, e xisting approaches have neglected the fact that, apart from the data labelled by amateurs, (limited) expert knowledge of the problem is also available along with vast amounts of unlabelled data that have not yet been exploited within a unified learning framework. This paper presents an innov ati ve learning methodology for citizen science capable of taking advantage of expert- and amateur-labelled data, featuring a transfer of labels between experts and amateurs. The proposed approach first learns from unlabelled data with a convolutional auto-encoder and then exploits amateur and expert labels via the pre-training and fine-tuning of a convolutional neural network, respectively. We focus on the classification of galaxy images from the Galaxy Zoo project, from which we test binary, multiclass, and imbalanced classification scenarios. The results demonstrate that our solution is able to impro v e classification performance compared to a set of baseline approaches, deploying a promising methodology for learning from different confidence levels in data labelling.