A Machine Learning Approach to Galactic Emission-Line Region Classification
Abstract
Diagnostic diagrams of emission-line ratios have been used extensively to categorize extragalactic emission regions; however, these diagnostics are occasionally at odds with each other due to differing definitions. In this work, we study the applicability of supervised machine-learning techniques to systematically classify emission-line regions from the ratios of certain emission lines. Using the Million Mexican Model database, which contains information from grids of photoionization models using \texttt{cloudy}, and from shock models, we develop training and test sets of emission line fluxes for three key diagnostic ratios. The sets are created for three classifications: classic \hii{} regions, planetary nebulae, and supernova remnants. We train a neural network to classify a region as one of the three classes defined above given three key line ratios that are present both in the SITELLE and MUSE instruments' band-passes: [{\sc O\,iii}]/H, [{\sc N\,ii}]/H, ([{\sc S\,ii}]+[{\sc S\,ii}])/H. We also tested the impact of the addition of the [{\sc O\,ii}]/[{\sc O\,iii}] line ratio when available for the classification. A maximum luminosity limit is introduced to improve the classification of the planetary nebulae. Furthermore, the network is applied to SITELLE observations of a prominent field of M33. We discuss where the network succeeds and why it fails in certain cases. Our results provide a framework for the use of machine learning as a tool for the classification of extragalactic emission regions. Further work is needed to build more comprehensive training sets and adapt the method to additional observational constraints.
Cite
@article{arxiv.2306.11545,
title = {A Machine Learning Approach to Galactic Emission-Line Region Classification},
author = {Carter Lee Rhea and Laurie Rousseau-Nepton and Ismael Moumen and Simon Prunet and Julie Hlavacek-Larrondo and Kathryn Grasha and Carmelle Roberts and Christophe Morisset and Grazyna Stasinska and Natalia Vale-Asari and Justine Giroux and Anna McLeod and Marie-Lou Gendron-Marsolais and Junfeng Wang and Joe Lyman and Laurent Chemin},
journal= {arXiv preprint arXiv:2306.11545},
year = {2023}
}
Comments
17 pages; 17 figures; Accepted to RASTI