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Main Authors: Fuchs, Richard, Knollmüller, Jakob, Roth, Jakob, Eberle, Vincent, Frank, Philipp, Enßlin, Torsten A., Heinrich, Lukas
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.04840
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author Fuchs, Richard
Knollmüller, Jakob
Roth, Jakob
Eberle, Vincent
Frank, Philipp
Enßlin, Torsten A.
Heinrich, Lukas
author_facet Fuchs, Richard
Knollmüller, Jakob
Roth, Jakob
Eberle, Vincent
Frank, Philipp
Enßlin, Torsten A.
Heinrich, Lukas
contents Modern radio interferometers deliver large volumes of data containing high-sensitivity sky maps over wide fields-of-view. These large area observations can contain various and superposed structures such as point sources, extended objects, and large-scale diffuse emission. To fully realize the potential of these observations, it is crucial to build appropriate sky emission models which separate and reconstruct the underlying astrophysical components. We introduce aim-resolve, an automatic and iterative method that combines the Bayesian imaging algorithm resolve with deep learning and clustering algorithms in order to jointly solve the reconstruction and source extraction problem. The method identifies and models different astrophysical components in radio observations while providing uncertainty quantification of the results. By using different model descriptions for point sources, extended objects, and diffuse background emission, the method efficiently separates the individual components and improves the overall reconstruction. We demonstrate the effectiveness of this method on synthetic image data containing multiple different sources. We further show the application of aim-resolve to an L-band (856 - 1712 MHz) MeerKAT observation of the radio galaxy ESO 137-006 and other radio galaxies in that environment. We observe a reasonable object identification for both applications, yielding a clean separation of the individual components and precise reconstructions of point sources and extended objects along with detailed uncertainty quantification. In particular, the method enables the creation of catalogs containing source positions and brightnesses and the corresponding uncertainties. The full decoupling of sky emission model and instrument response makes the method applicable to a wide variety of instruments or wavelength bands.
format Preprint
id arxiv_https___arxiv_org_abs_2512_04840
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle aim-resolve: Automatic Identification and Modeling for Bayesian Radio Interferometric Imaging
Fuchs, Richard
Knollmüller, Jakob
Roth, Jakob
Eberle, Vincent
Frank, Philipp
Enßlin, Torsten A.
Heinrich, Lukas
Instrumentation and Methods for Astrophysics
Modern radio interferometers deliver large volumes of data containing high-sensitivity sky maps over wide fields-of-view. These large area observations can contain various and superposed structures such as point sources, extended objects, and large-scale diffuse emission. To fully realize the potential of these observations, it is crucial to build appropriate sky emission models which separate and reconstruct the underlying astrophysical components. We introduce aim-resolve, an automatic and iterative method that combines the Bayesian imaging algorithm resolve with deep learning and clustering algorithms in order to jointly solve the reconstruction and source extraction problem. The method identifies and models different astrophysical components in radio observations while providing uncertainty quantification of the results. By using different model descriptions for point sources, extended objects, and diffuse background emission, the method efficiently separates the individual components and improves the overall reconstruction. We demonstrate the effectiveness of this method on synthetic image data containing multiple different sources. We further show the application of aim-resolve to an L-band (856 - 1712 MHz) MeerKAT observation of the radio galaxy ESO 137-006 and other radio galaxies in that environment. We observe a reasonable object identification for both applications, yielding a clean separation of the individual components and precise reconstructions of point sources and extended objects along with detailed uncertainty quantification. In particular, the method enables the creation of catalogs containing source positions and brightnesses and the corresponding uncertainties. The full decoupling of sky emission model and instrument response makes the method applicable to a wide variety of instruments or wavelength bands.
title aim-resolve: Automatic Identification and Modeling for Bayesian Radio Interferometric Imaging
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2512.04840