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Main Authors: Centofanti, Ezequiel, Farrens, Samuel, Starck, Jean-Luc, Liaudat, Tobias, Szapiro, Alex, Pollack, Jennifer
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.16151
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author Centofanti, Ezequiel
Farrens, Samuel
Starck, Jean-Luc
Liaudat, Tobias
Szapiro, Alex
Pollack, Jennifer
author_facet Centofanti, Ezequiel
Farrens, Samuel
Starck, Jean-Luc
Liaudat, Tobias
Szapiro, Alex
Pollack, Jennifer
contents The spectral energy distribution (SED) of observed stars in wide-field images is crucial for chromatic point spread function (PSF) modelling methods, which use unresolved stars as integrated spectral samples of the PSF across the field of view. This is particularly important for weak gravitational lensing studies, where precise PSF modelling is essential to get accurate shear measurements. Previous research has demonstrated that the SED of stars can be inferred from low-resolution observations using machine-learning classification algorithms. However, a degeneracy exists between the PSF size, which can vary significantly across the field of view, and the spectral type of stars, leading to strong limitations of such methods. We propose a new SED classification method that incorporates stellar spectral information by using a preliminary PSF model, thereby breaking this degeneracy and enhancing the classification accuracy. Our method involves calculating a set of similarity features between an observed star and a preliminary PSF model at different wavelengths and applying a support vector machine to these similarity features to classify the observed star into a specific stellar class. The proposed approach achieves a 91\% top-two accuracy, surpassing machine-learning methods that do not consider the spectral variation of the PSF. Additionally, we examined the impact of PSF modelling errors on the spectral classification accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2501_16151
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Breaking the degeneracy in stellar spectral classification from single wide-band images
Centofanti, Ezequiel
Farrens, Samuel
Starck, Jean-Luc
Liaudat, Tobias
Szapiro, Alex
Pollack, Jennifer
Instrumentation and Methods for Astrophysics
The spectral energy distribution (SED) of observed stars in wide-field images is crucial for chromatic point spread function (PSF) modelling methods, which use unresolved stars as integrated spectral samples of the PSF across the field of view. This is particularly important for weak gravitational lensing studies, where precise PSF modelling is essential to get accurate shear measurements. Previous research has demonstrated that the SED of stars can be inferred from low-resolution observations using machine-learning classification algorithms. However, a degeneracy exists between the PSF size, which can vary significantly across the field of view, and the spectral type of stars, leading to strong limitations of such methods. We propose a new SED classification method that incorporates stellar spectral information by using a preliminary PSF model, thereby breaking this degeneracy and enhancing the classification accuracy. Our method involves calculating a set of similarity features between an observed star and a preliminary PSF model at different wavelengths and applying a support vector machine to these similarity features to classify the observed star into a specific stellar class. The proposed approach achieves a 91\% top-two accuracy, surpassing machine-learning methods that do not consider the spectral variation of the PSF. Additionally, we examined the impact of PSF modelling errors on the spectral classification accuracy.
title Breaking the degeneracy in stellar spectral classification from single wide-band images
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2501.16151