Surveying the reach and maturity of machine learning and artificial intelligence in astronomy

Fluke, Christopher J.; Jacobs, Colin

doi:10.1002/widm.1349

Cited by 93 publications

(51 citation statements)

References 274 publications

(561 reference statements)

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“…An excellent introduction to the classification algorithms for astronomical tasks, including the morphological galaxy classification, is given in various studies (Ball & Brunner (2010); Way et al (2012); VanderPlas et al (2012); Ivezic & Babu (2014); Al-Jarrah et al (2015); Fluke & Jacobs (2020); El Bouchefry & de Souza (2020), and Vavilova et al (2020). We also refer to the classical work by Buta (2011), and to a good pedagogical review by Conselice et al (2014) with a discussion of principal methods in which galaxies are studied morphologically and structurally.…”

Section: Introductionmentioning

confidence: 99%

Machine learning technique for morphological classification of galaxies from the SDSS

Vavilova

Dobrycheva

Vasylenko

et al. 2021

A&A

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Context. Machine learning methods are effective tools in astronomical tasks for classifying objects by their individual features. One of the promising utilities is related to the morphological classification of galaxies at different redshifts. Aims. We use the photometry-based approach for the SDSS data 1) to exploit five supervised machine learning techniques and define the most effective among them for the automated galaxy morphological classification; 2) to test the influence of photometry data on morphology classification; 3) to discuss problem points of supervised machine learning and labeling bias; and 4) to apply the best fitting machine learning methods for revealing the unknown morphological types of galaxies from the SDSS DR9 at z < 0.1. Methods. We used different galaxy classification techniques: human labeling, multi-photometry diagrams, naive Bayes, logistic regression, support-vector machine, random forest, k-nearest neighbors. Results. We present the results of a binary automated morphological classification of galaxies conducted by human labeling, multiphotometry, and five supervised machine learning methods. We applied it to the sample of galaxies from the SDSS DR9 with redshifts of 0.02 < z < 0.1 and absolute stellar magnitudes of −24 m < M r < −19.4 m . For the analysis we used absolute magnitudes M

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Section: Introductionmentioning

confidence: 99%

Machine learning technique for morphological classification of galaxies from the SDSS

Vavilova

Dobrycheva

Vasylenko

et al. 2021

A&A

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“…In general, the ML-based techniques are able to produce a high-quality photo-z estimation within the photometric ranges imposed by the spectroscopic training set but are less capable of reaching the same photo-z estimation quality outside those ranges. Nevertheless, the positive contribution of data-driven methodologies to the estimation of distances for galaxies and peculiar objects, such as quasars (Baron, 2019;Fluke and Jacobs, 2020), is well-known. Without claiming to be exhaustive, we can cite the following methods proposed in the literature, which testify to their diversity of approach:…”

Section: General Aspects Of the Photo-z Estimation With MLmentioning

confidence: 99%

Photometric Redshifts With Machine Learning, Lights and Shadows on a Complex Data Science Use Case

Brescia

Cavuoti

Razim

et al. 2021

Front. Astron. Space Sci.

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The importance of the current role of data-driven science is constantly increasing within Astrophysics, due to the huge amount of multi-wavelength data collected every day, characterized by complex and high-volume information requiring efficient and, as much as possible, automated exploration tools. Furthermore, to accomplish main and legacy science objectives of future or incoming large and deep survey projects, such as James Webb Space Telescope (JWST), James Webb Space Telescope (LSST), and Euclid, a crucial role is played by an accurate estimation of photometric redshifts, whose knowledge would permit the detection and analysis of extended and peculiar sources by disentangling low-z from high-z sources and would contribute to solve the modern cosmological discrepancies. The recent photometric redshift data challenges, organized within several survey projects, like LSST and Euclid, pushed the exploitation of the observed multi-wavelength and multi-dimensional data or ad hoc simulated data to improve and optimize the photometric redshifts prediction and statistical characterization based on both Spectral Energy Distribution (SED) template fitting and machine learning methodologies. They also provided a new impetus in the investigation of hybrid and deep learning techniques, aimed at conjugating the positive peculiarities of different methodologies, thus optimizing the estimation accuracy and maximizing the photometric range coverage, which are particularly important in the high-z regime, where the spectroscopic ground truth is poorly available. In such a context, we summarize what was learned and proposed in more than a decade of research.

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“…During our recent astrophysics workshops, many astronomers voiced their desires as well as concerns about using machine learning techniques (ML), and in particular, deep learning in the astrophysics discovery processes, mostly surrounding the interpretability of “black box” ML models. Active discussions have concerned the maturity of ML in astronomy, and a number of surveys have been created to assess this maturity [BB10, FJ20, NAB∗19].…”

Section: Challenges and Opportunitiesmentioning

confidence: 99%

Visualization in Astrophysics: Developing New Methods, Discovering Our Universe, and Educating the Earth

Lan

Young

Anderson

et al. 2021

Computer Graphics Forum

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We present a state‐of‐the‐art report on visualization in astrophysics. We survey representative papers from both astrophysics and visualization and provide a taxonomy of existing approaches based on data analysis tasks. The approaches are classified based on five categories: data wrangling, data exploration, feature identification, object reconstruction, as well as education and outreach. Our unique contribution is to combine the diverse viewpoints from both astronomers and visualization experts to identify challenges and opportunities for visualization in astrophysics. The main goal is to provide a reference point to bring modern data analysis and visualization techniques to the rich datasets in astrophysics.

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Surveying the reach and maturity of machine learning and artificial intelligence in astronomy

Cited by 93 publications

References 274 publications

Machine learning technique for morphological classification of galaxies from the SDSS

Machine learning technique for morphological classification of galaxies from the SDSS

Photometric Redshifts With Machine Learning, Lights and Shadows on a Complex Data Science Use Case

Visualization in Astrophysics: Developing New Methods, Discovering Our Universe, and Educating the Earth

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