The FIRST Classifier: compact and extended radio galaxy classification using deep Convolutional Neural Networks

Alhassan, Wathela

doi:10.31730/osf.io/9d2h3

Cited by 2 publications

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“…An advantage of CNNs is their ability to be re-trained on custom data sets, which allows for more flexibility while classical machine learning methods tend to be more domain-specific (O'Mahony et al 2019). It is not only widely used in the field of computer vision but has recently become a popular method for source-finding in 21 cm astronomy images (Gheller et al 2018;Lukic et al 2019;Aniyan and Thorat 2017), and is found to out-perform other machine learning methods when used for optical 2D galaxy classification (Cheng et al 2020;Alhassan et al 2018).…”

Section: Deep Learning Methodsmentioning

confidence: 99%

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

Barkai

Verheijen

Martínez

et al. 2023

A&A

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Context. The 21 cm spectral line emission of atomic neutral hydrogen (H i) is one of the primary wavelengths observed in radio astronomy. However, the signal is intrinsically faint and the H i content of galaxies depends on the cosmic environment, requiring large survey volumes and survey depth to investigate the H i Universe. As the amount of data coming from these surveys continues to increase with technological improvements, so does the need for automatic techniques for identifying and characterising H i sources while considering the tradeoff between completeness and purity.Aims. This study aimed to find the optimal pipeline for finding and masking the most sources with the best mask quality and the fewest artefacts in 3D neutral hydrogen cubes. Various existing methods were explored, including the traditional statistical approaches and machine learning techniques, in an attempt to create a pipeline to optimally identify and mask the sources in 3D neutral hydrogen (H i) 21 cm spectral line data cubes. Methods. Two traditional source-finding methods were tested first: the well-established H i source-finding software SoFiA and one of the most recent, best performing optical source-finding pieces of software, MTObjects. A new supervised deep learning approach was also tested, in which a 3D convolutional neural network architecture, known as V-Net, which was originally designed for medical imaging, was used. These three source-finding methods were further improved by adding a classical machine learning classifier as a post-processing step to remove false positive detections. The pipelines were tested on H i data cubes from the Westerbork Synthesis Radio Telescope with additional inserted mock galaxies. Results. Following what has been learned from work in other fields, such as medical imaging, it was expected that the best pipeline would involve the V-Net network combined with a random forest classifier. This, however, was not the case: SoFiA combined with a random forest classifier provided the best results, with the V-Net-random forest combination a close second. We suspect this is due to the fact that there are many more mock sources in the training set than real sources. There is, therefore, room to improve the quality of the V-Net network with better-labelled data such that it can potentially outperform SoFiA.

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Section: Deep Learning Methodsmentioning

confidence: 99%

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

Barkai

Verheijen

Martínez

et al. 2023

A&A

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“…This is designed to learn the different geometry of large-scale features on the Sun such that, after the model has been trained, a dataset of solar images can be passed to the network and it will identify which images contain which relevant feature in a very short time. This process has already been used for galaxy classification in cosmology (Dai and Tong, 2018;Alhassan, Taylor, and Vaccari, 2018) and we propose adopting a similar algorithm for solar purposes.…”

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confidence: 99%

Fast Solar Image Classification Using Deep Learning and Its Importance for Automation in Solar Physics

Armstrong

Fletcher

2019

Sol Phys

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The volume of data being collected in solar physics has exponentially increased over the past decade and with the introduction of the Daniel K. Inouye Solar Telescope (DKIST) we will be entering the age of petabyte solar data. Automated feature detection will be an invaluable tool for post-processing of solar images to create catalogues of data ready for researchers to use. We propose a deep learning model to accomplish this; a deep convolutional neural network is adept at feature extraction and processing images quickly. We train our network using data from Hinode/Solar Optical Telescope (SOT) Hα images of a small subset of solar features with different geometries: filaments, prominences, flare ribbons, sunspots and the quiet Sun (i.e. the absence of any of the other four features). We achieve near perfect performance on classifying unseen images from SOT (≈ 99.9%) in 4.66 seconds. We also for the first time explore transfer learning in a solar context. Transfer learning uses pre-trained deep neural networks to help train new deep learning models i.e. it teaches a new model. We show that our network is robust to changes in resolution by degrading images from SOT resolution (≈ 0.33 at λ = 6563 Å) to Solar Dynamics Observatory/Atmospheric Imaging Assembly (SDO/AIA) resolution (≈ 1.2) without a change in performance of our network. However, we also observe where the network fails to generalise to sunspots from SDO/AIA bands 1600/1700 Å due to small-scale brightenings around the sunspots and prominences in SDO/AIA 304 Å due to coronal emission. Keywords Instrumentation and data management 1. Introduction With each new solar physics mission/telescope, instruments are improving in spatial, temporal and/or wavelength resolution. Increased resolution in any of these three categories B J.A. Armstrong

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The FIRST Classifier: compact and extended radio galaxy classification using deep Convolutional Neural Networks

Cited by 2 publications

References 0 publications

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

Fast Solar Image Classification Using Deep Learning and Its Importance for Automation in Solar Physics

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The FIRST Classifier: compact and extended radio galaxy classification using deep Convolutional Neural Networks

Cited by 2 publications

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A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

Fast Solar Image Classification Using Deep Learning and Its Importance for Automation in Solar Physics

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A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning

A comparative study of source-finding techniques in H I emission line cubes using SoFiA, MTObjects, and supervised deep learning