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Main Authors: Vera-Casanova., Alex, Gonzalez, Nicolas Monsalves, Gómez, Facundo A., Arancibia., Marcelo Jaque, Fontirroig, Valentina, Pallero., Diego, Pakmor., Rüdiger, van de Voort., Freeke, Grand., Robert J. J., Bieri., Rebekka, Marinacci, Federico
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.17202
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author Vera-Casanova., Alex
Gonzalez, Nicolas Monsalves
Gómez, Facundo A.
Arancibia., Marcelo Jaque
Fontirroig, Valentina
Pallero., Diego
Pakmor., Rüdiger
van de Voort., Freeke
Grand., Robert J. J.
Bieri., Rebekka
Marinacci, Federico
author_facet Vera-Casanova., Alex
Gonzalez, Nicolas Monsalves
Gómez, Facundo A.
Arancibia., Marcelo Jaque
Fontirroig, Valentina
Pallero., Diego
Pakmor., Rüdiger
van de Voort., Freeke
Grand., Robert J. J.
Bieri., Rebekka
Marinacci, Federico
contents Context. Galactic halos host faint substructures, such as stellar streams and shells, which provide insights into the hierarchical assembly history of galaxies. To date, such features have been identified in external galaxies by visual inspection. However, with the advent of larger and deeper surveys and the associated increase in data volume, this methodology is becoming impractical. Aims. Here we aim to develop an automated method to detect low surface brightness features in galactic stellar halos. Moreover, we seek to quantify its performance when considering progressively more complex data sets, including different stellar disc orientations and redshifts. Methods. We develop the Stream Automatic Detection with Convolutional Neural Networks, SAD-CNN. This tool is trained on mock surface brightness maps obtained from simulations of the Auriga Project. The model incorporates transfer learning, data augmentation and balanced datasets to optimise its detection capabilities at surface brightness limiting magnitudes ranging from 27 to 31 mag arcsec^-2. Results. The iterative training approach, coupled with transfer learning, allowed the model to adapt to increasingly challenging datasets, achieving precision and recall metrics above 80% in all considered scenarios. The use of a well-balanced training dataset is critical for mitigating biases, ensuring that the CNN accurately distinguishes between galaxies with and without streams. Conclusions. SAD-CNN is a reliable and scalable tool for automating the detection of faint substructures in galactic halos. Its adaptability makes it well-suited for future applications, including the analysis of data from upcoming large astronomical surveys (such as LSST, JWT).
format Preprint
id arxiv_https___arxiv_org_abs_2503_17202
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stream Automatic Detection with Convolutional Neural Network (SAD-CNN)
Vera-Casanova., Alex
Gonzalez, Nicolas Monsalves
Gómez, Facundo A.
Arancibia., Marcelo Jaque
Fontirroig, Valentina
Pallero., Diego
Pakmor., Rüdiger
van de Voort., Freeke
Grand., Robert J. J.
Bieri., Rebekka
Marinacci, Federico
Astrophysics of Galaxies
Context. Galactic halos host faint substructures, such as stellar streams and shells, which provide insights into the hierarchical assembly history of galaxies. To date, such features have been identified in external galaxies by visual inspection. However, with the advent of larger and deeper surveys and the associated increase in data volume, this methodology is becoming impractical. Aims. Here we aim to develop an automated method to detect low surface brightness features in galactic stellar halos. Moreover, we seek to quantify its performance when considering progressively more complex data sets, including different stellar disc orientations and redshifts. Methods. We develop the Stream Automatic Detection with Convolutional Neural Networks, SAD-CNN. This tool is trained on mock surface brightness maps obtained from simulations of the Auriga Project. The model incorporates transfer learning, data augmentation and balanced datasets to optimise its detection capabilities at surface brightness limiting magnitudes ranging from 27 to 31 mag arcsec^-2. Results. The iterative training approach, coupled with transfer learning, allowed the model to adapt to increasingly challenging datasets, achieving precision and recall metrics above 80% in all considered scenarios. The use of a well-balanced training dataset is critical for mitigating biases, ensuring that the CNN accurately distinguishes between galaxies with and without streams. Conclusions. SAD-CNN is a reliable and scalable tool for automating the detection of faint substructures in galactic halos. Its adaptability makes it well-suited for future applications, including the analysis of data from upcoming large astronomical surveys (such as LSST, JWT).
title Stream Automatic Detection with Convolutional Neural Network (SAD-CNN)
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2503.17202