KiDS-SQuaD

Khramtsov, Vladislav; Sergeyev, A.; Spiniello, C.; Tortora, C.; Napolitano, N. R.; Agnello, Adriano; Getman, F.; Jong, J. T. A. de; Kuijken, Konrad; Radovich, M.; Shan, Huanyuan; Shulga, V. M.

doi:10.1051/0004-6361/201936006

Cited by 45 publications

(41 citation statements)

References 112 publications

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“…The accuracy of each applied machine learning method for the two-parameter classification is written in the left corner of each panel. photometric redshift estimation (Mu et al 2020), prediction of galaxy halo masses (Calderon & Berlind 2019), gravitational lenses search (Khramtsov et al 2019b), automating discovery and classification of variable stars (Bloom et al 2012), and for analyzing huge observational surveys, for example the Zwicky Transient Facility (Mahabal et al 2019), or finding planets and exocomets from the Kepler and TESS surveys (Kohler 2018).…”

Section: Discussionmentioning

confidence: 99%

“…photometric redshift estimation(Mu et al 2020), prediction of galaxy halo masses(Calderon & Berlind 2019), gravitational lenses search(Khramtsov et al 2019b), automating discovery and classification of variable stars(Bloom et al 2012), and for analyzing huge observational surveys, for example the Zwicky Transient Facility(Mahabal et al 2019), or finding planets and exocomets from the Kepler and TESS surveys(Kohler 2018).Among other recent examples, we also note the determination of physical properties of galaxies (density, metallicity, column density, ionization) from their emission-line spectra with support-vector machine algorithms employed and developed in a new GAME numerical code byUcci et al (2017); prediction of the HI content of massive galaxies at z < 2 based on optical photometry data (SDSS) and environmental parameters, which was performed byRafieferantsoa et al (2018) with regressors and deep neural network (see also examples of applications of the AstroML Python module 5 for the large-scale observational extragalactic surveys 3 ). In addition to the traditional approach for classifying the galaxy types automatically in the optical range, the machine learning methods also demonstrate a strong utility for classifying the radio galaxy types and peculiarities(Aniyan & Thorat (2017);Alger et al (2018); Wagner et al (2019);Lukic et al (2019), andRalph et al (2019)).…”

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confidence: 99%

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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: Discussionmentioning

confidence: 99%

mentioning

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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“…Bottom: Late type (Spirals). work (DL) to the images of redshift-limited (z < 0.1) sample of ∼ 300 000 galaxies from the SDSS DR9 by [Khramtsov et al (2019)] with the same aim of binary morphological classification has been shown, for example, that DL method can classify rounded sources as Ellipticals but it can not catch the spectral energy distribution properties of galaxies more clearly than SVM, trained on the photometric features of galaxies.…”

Section: Results and Conclusionmentioning

confidence: 99%

Verification of Machine Learning Methods for Binary Morphological Classification of Galaxies From SDSS

Vasylenko

Dobrycheva

Vavilova

et al. 2019

OAP

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We present a study on the verification of Machine Learning methods to be applied for binary morphological classification of galaxies. With this aim we used the sample of 60 561 galaxies from the SDSS DR9 survey with a redshift of 0.02 < z < 0.06 and absolute magnitudes of −24 m < M r < −19.4 m. We applied the following classification methods using own code in Python to predict correctly the morphology of Late and Early galaxies: Naive Bayes, Random Forest, Support Vector Machines, Logistic Regression, and k-Nearest Neighbor algorithm. To study the classifier, we used absolute magnitudes M

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“…The VISTA-Kilo-Degree Infrared Galaxy Survey (VIKING, Sutherland 2012;Edge et al 2013) covers 1500 square degrees overlapping the Kilo Degree Survey (KiDS, Kuijken et al 2015) for the optical counterpart, ensuring a uniform coverage on ∼1350 deg 2 with intermediate depth in nine bands (grizY JHK s, with limiting magnitude J = 21 in the Vega system), enabling accurate photometric redshift measurements for weak-lensing studies (Hildebrandt et al 2017). The science goals of the KiDS and VIKING include the following: the characterisation of galaxy clusters up to z ∼ 1 (Maturi et al 2019), the search for high-z objects (Venemans et al 2015) and new strong gravitational lenses (Spiniello et al 2018;Petrillo et al 2019;Khramtsov et al 2019), and the study of galaxy structural parameters and stellar masses for a statistically large sample of galaxies (Roy et al 2018).…”

Section: The Vista-kilo-degree Infrared Galaxy Surveymentioning

confidence: 99%

VEXAS: VISTA EXtension to Auxiliary Surveys

Spiniello

Agnello²

2019

A&A

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Context. We present the first public data release of the VISTA EXtension to Auxiliary Surveys (VEXAS), comprising nine cross-matched multi-wavelength photometric catalogues where each object has a match in at least two surveys. Aims. Our aim is to provide spatial coverage that is as uniform as possible in the multi-wavelength sky and to provide the astronomical community with reference magnitudes and colours for various scientific uses: object classification (e.g. quasars, galaxies, and stars; high-z galaxies, white dwarfs); photometric redshifts of large galaxy samples; searches of exotic objects (e.g. extremely red objects and lensed quasars). Methods. We cross-matched the wide-field VISTA catalogues (the VISTA Hemisphere Survey and the VISTA Kilo Degree Infrared Galaxy Survey) with the AllWISE mid-infrared Survey, requiring a match within 10″. We have further matched this table with X-ray and radio data (ROSAT, XMM, SUMSS). We also performed a second cross-match between VISTA and AllWISE, with a smaller matching radius (3″), including WISE magnitudes. We then cross-matched this resulting table (≈138 × 106 objects) with three photometric wide-sky optical deep surveys (DES, SkyMapper, PanSTARRS). We finally included matches to objects with spectroscopic follow-up by the SDSS and 6dFGS. Results. To demonstrate the power of all-sky multi-wavelength cross-match tables, we show two examples of scientific applications of VEXAS, in particular using the publicly released tables to discover strong gravitational lenses (beyond the reach of previous searches) and to build a statistically large sample of extremely red objects. Conclusions. The VEXAS catalogue is currently the widest and deepest public optical-to-IR photometric and spectroscopic database in the southern hemisphere.

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KiDS-SQuaD

Cited by 45 publications

References 112 publications

Machine learning technique for morphological classification of galaxies from the SDSS

Machine learning technique for morphological classification of galaxies from the SDSS

Verification of Machine Learning Methods for Binary Morphological Classification of Galaxies From SDSS

VEXAS: VISTA EXtension to Auxiliary Surveys

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