Radio astronomical images object detection and segmentation: a benchmark on deep learning methods

Renato Sortino; Daniel Magro; Giuseppe Fiameni; Eva Sciacca; Simone Riggi; Andrea DeMarco; Concetto Spampinato; Andrew M. Hopkins; Filomena Bufano; Francesco Schillirò; Cristobal Bordiu; Carmelo Pino

doi:10.1007/s10686-023-09893-w

Radio astronomical images object detection and segmentation: a benchmark on deep learning methods

Renato Sortino^*, Daniel Magro, Giuseppe Fiameni, Eva Sciacca, Simone Riggi, Andrea DeMarco, Concetto Spampinato, Andrew M. Hopkins, Filomena Bufano, Francesco Schillirò, Cristobal Bordiu, Carmelo Pino

^*Corresponding author for this work

Australian Astronomical Optics

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

In recent years, deep learning has been successfully applied in various scientific domains. Following these promising results and performances, it has recently also started being evaluated in the domain of radio astronomy. In particular, since radio astronomy is entering the Big Data era, with the advent of the largest telescope in the world - the Square Kilometre Array (SKA), the task of automatic object detection and instance segmentation is crucial for source finding and analysis. In this work, we explore the performance of the most affirmed deep learning approaches, applied to astronomical images obtained by radio interferometric instrumentation, to solve the task of automatic source detection. This is carried out by applying models designed to accomplish two different kinds of tasks: object detection and semantic segmentation. The goal is to provide an overview of existing techniques, in terms of prediction performance and computational efficiency, to scientists in the astrophysics community who would like to employ machine learning in their research.

Original language	English
Pages (from-to)	293-331
Number of pages	39
Journal	Experimental Astronomy
Volume	56
Issue number	1
DOIs	https://doi.org/10.1007/s10686-023-09893-w
Publication status	Published - Aug 2023

Keywords

Deep learning
Source finding
Object detection
Transformers
Astrophysics

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abstract = "In recent years, deep learning has been successfully applied in various scientific domains. Following these promising results and performances, it has recently also started being evaluated in the domain of radio astronomy. In particular, since radio astronomy is entering the Big Data era, with the advent of the largest telescope in the world - the Square Kilometre Array (SKA), the task of automatic object detection and instance segmentation is crucial for source finding and analysis. In this work, we explore the performance of the most affirmed deep learning approaches, applied to astronomical images obtained by radio interferometric instrumentation, to solve the task of automatic source detection. This is carried out by applying models designed to accomplish two different kinds of tasks: object detection and semantic segmentation. The goal is to provide an overview of existing techniques, in terms of prediction performance and computational efficiency, to scientists in the astrophysics community who would like to employ machine learning in their research.",

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AU - Magro, Daniel

AU - Fiameni, Giuseppe

AU - Sciacca, Eva

AU - Riggi, Simone

AU - DeMarco, Andrea

AU - Spampinato, Concetto

AU - Hopkins, Andrew M.

AU - Bufano, Filomena

AU - Schillirò, Francesco

AU - Bordiu, Cristobal

AU - Pino, Carmelo

PY - 2023/8

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N2 - In recent years, deep learning has been successfully applied in various scientific domains. Following these promising results and performances, it has recently also started being evaluated in the domain of radio astronomy. In particular, since radio astronomy is entering the Big Data era, with the advent of the largest telescope in the world - the Square Kilometre Array (SKA), the task of automatic object detection and instance segmentation is crucial for source finding and analysis. In this work, we explore the performance of the most affirmed deep learning approaches, applied to astronomical images obtained by radio interferometric instrumentation, to solve the task of automatic source detection. This is carried out by applying models designed to accomplish two different kinds of tasks: object detection and semantic segmentation. The goal is to provide an overview of existing techniques, in terms of prediction performance and computational efficiency, to scientists in the astrophysics community who would like to employ machine learning in their research.

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KW - Deep learning

KW - Source finding

KW - Object detection

KW - Transformers

KW - Astrophysics

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JO - Experimental Astronomy

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Radio astronomical images object detection and segmentation: a benchmark on deep learning methods

Abstract

Keywords

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