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Autores principales: Bjerkeli, Per, Kainulainen, Jouni, Toribio, Maria Carmen, Boschman, Leon, Lucas, Otoniel Maya
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2602.09223
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author Bjerkeli, Per
Kainulainen, Jouni
Toribio, Maria Carmen
Boschman, Leon
Lucas, Otoniel Maya
author_facet Bjerkeli, Per
Kainulainen, Jouni
Toribio, Maria Carmen
Boschman, Leon
Lucas, Otoniel Maya
contents Modern telescopes generate increasingly large and diverse datasets, often consisting of complex and morphologically rich structures. To efficiently explore such data requires automated methods that can extract and organize physically meaningful information, ideally without the need for extensive manual interaction. We aim to provide a user-friendly implementation of a self-supervised machine learning framework to explore morphological properties of large datasets, based on the BYOL (Bootstrap Your Own Latents) method. By enabling the generation of meaningful image embeddings without manually labelled data, the framework will enable key tasks such as clustering, anomaly detection, and similarity based exploration. In contrast to existing BYOL implementations, astromorph accommodates data of varying dimensions and resolutions, including both single-channel FITS images and multi-channel spectral cubes. The package is built with usability in mind, offering streamlined pipeline scripts for ease of use as well as deeper customization options via PyTorch-based classes. To demonstrate the utility of astromorph, we apply it in two contrasting science cases representing different astronomical domains: images of protoplanetary disks observed with ALMA, and infrared dark clouds observed with Spitzer and Herschel. In both cases, we demonstrate how astromorph produces scientifically meaningful embeddings that capture morphological differences and similarities across large samples. astromorph enables users to apply a robust, label-free approach for uncovering morphological patterns in astronomical datasets. The successful application to two markedly different datasets suggest that the pipeline is broadly applicable across a wide range of imaging-rich astronomical context, providing a user friendly tool for advancing discovery in observational astronomy.
format Preprint
id arxiv_https___arxiv_org_abs_2602_09223
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle astromorph: Self-supervised machine learning pipeline for astronomical morphology analysis
Bjerkeli, Per
Kainulainen, Jouni
Toribio, Maria Carmen
Boschman, Leon
Lucas, Otoniel Maya
Instrumentation and Methods for Astrophysics
Modern telescopes generate increasingly large and diverse datasets, often consisting of complex and morphologically rich structures. To efficiently explore such data requires automated methods that can extract and organize physically meaningful information, ideally without the need for extensive manual interaction. We aim to provide a user-friendly implementation of a self-supervised machine learning framework to explore morphological properties of large datasets, based on the BYOL (Bootstrap Your Own Latents) method. By enabling the generation of meaningful image embeddings without manually labelled data, the framework will enable key tasks such as clustering, anomaly detection, and similarity based exploration. In contrast to existing BYOL implementations, astromorph accommodates data of varying dimensions and resolutions, including both single-channel FITS images and multi-channel spectral cubes. The package is built with usability in mind, offering streamlined pipeline scripts for ease of use as well as deeper customization options via PyTorch-based classes. To demonstrate the utility of astromorph, we apply it in two contrasting science cases representing different astronomical domains: images of protoplanetary disks observed with ALMA, and infrared dark clouds observed with Spitzer and Herschel. In both cases, we demonstrate how astromorph produces scientifically meaningful embeddings that capture morphological differences and similarities across large samples. astromorph enables users to apply a robust, label-free approach for uncovering morphological patterns in astronomical datasets. The successful application to two markedly different datasets suggest that the pipeline is broadly applicable across a wide range of imaging-rich astronomical context, providing a user friendly tool for advancing discovery in observational astronomy.
title astromorph: Self-supervised machine learning pipeline for astronomical morphology analysis
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2602.09223