Catalog of quasars from the Kilo-Degree Survey Data Release 3

Nakoneczny, Szymon; Bilicki, Maciej; Solarz, A.; Pollo, A.; Maddox, Natasha; Spiniello, C.; Brescia, M.; Napolitano, N. R.

doi:10.1051/0004-6361/201834794

Cited by 41 publications

(42 citation statements)

References 77 publications

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“…It is clear that the verification procedure of Pâris et al (2018) has removed a lot of interlopers, particularly sources with starlike colours. Nakoneczny et al (2019) used KIDS DR3 to search for quasars using ug r i colours and magnitudes, and the stellarity morphological index. They created a parent catalogue of 3.4 10 6 sources and using SDSS DR14 spectroscopic labels, they identified a total of 190,000 quasar candidates (r <22).…”

Section: Comparison To Dr14qmentioning

confidence: 99%

“…Out of the 837,624 sources in common, we examined the overlap of quasar positive classifications. We selected KIDS-DR3 quasars using a threshold of Pr[QSO]>0.7 suggested for optimized completeness in Nakoneczny et al (2019). Using the matched sample, we find that the KIDS-DR3 catalogue identifies 29,878 quasar candidates while the KiDS-VW sam- ple identifies 40,621 quasars.…”

Section: Comparison To the Kids-dr3 Qso Cataloguementioning

confidence: 99%

“…According to the feature importance ranking discussed in Nakoneczny et al (2019), the stellarity index carried the highest weight. Hence, we conclude that the ug r i colours where suffiencent to disentangle between stars and quasars leading to the creation of a pure quasar catalogue.…”

Section: Comparison To the Kids-dr3 Qso Cataloguementioning

confidence: 99%

“…In §6 we discuss the impact of the input attributes, including colours and half light radii, as well as the photometric depth and photometric uncertainties. In §8 we compare our results to the automatic labels of the Sloan Digital Sky Survey (SDSS DR14), the refined labels of the SDSS Quasars catalogue of Pâris et al (2018), and the KIDS DR3 quasar catalogue of Nakoneczny et al (2019). Finally, we apply and publicly release our classifications on the Kilo Degree Survey, matched with the VIKING and ALLWISE surveys (∼3 million sources).…”

Section: Introductionmentioning

confidence: 99%

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Unsupervised star, galaxy, QSO classification

Logan

Fotopoulou

2020

A&A

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Context. Classification will be an important first step for upcoming surveys that will detect billions of new sources such as LSST and Euclid, as well as DESI, 4MOST and MOONS. The application of traditional methods of model fitting and colour-colour selections will face significant computational constraints, while machine-learning methods offer a viable approach to tackle datasets of that volume. Aims. While supervised learning methods can perform very well for classification tasks, the creation of representative and accurate training sets is a resource and time consuming task. We present a viable alternative using an unsupervised machine learning method to separate stars, galaxies and QSOs using photometric data.Methods. The heart of our work uses Hierarchical Density-Based Spatial Clustering of Applications with Noise (HDBSCAN) to find the star, galaxy and QSO clusters in a multidimensional colour space. We optimized the hyperparameters and input attributes of three separate HDBSCAN runs, each to select a particular object class, and thus treat the output of each separate run as a binary classifier. We subsequently consolidate the output to give our final classifications, optimized on the basis of their F1 scores. We explore the use of Random Forest and PCA as part of the pre-processing stage for feature selection and dimensionality reduction. Results. Using our dataset of ∼ 50,000 spectroscopically labelled objects we obtain an F1 score of 98.9, 98.9 and 93.13 respectively for star, galaxy and QSO selection using our unsupervised learning method. We find that careful attribute selection is a vital part of accurate classification with HDBSCAN. We applied our classification to a subset of the SDSS spectroscopic catalogue and demonstrate the potential of our approach in correcting misclassified spectra useful for DESI and 4MOST. Finally, we created a multiwavelength catalogue of 2.7 million sources using the KiDS, VIKING and ALLWISE surveys and publish corresponding classifications and photometric redshifts.

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Section: Comparison To Dr14qmentioning

confidence: 99%

Section: Comparison To the Kids-dr3 Qso Cataloguementioning

confidence: 99%

Section: Comparison To the Kids-dr3 Qso Cataloguementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Unsupervised star, galaxy, QSO classification

Logan

Fotopoulou

2020

A&A

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“…New methods are being developed to find anomalous objects in astronomical datasets, such as the work by Baron and Poznanski () using an unsupervised RF to find outliers among SDSS galaxies. Promising avenues involve a combination of unsupervised learning methods, such as isolation forests (Liu, Ting, & Zhou, ); dimensionality reduction, such as PCA, t‐Distributed Stochastic Neighbor Embedding (van der Maaten & Hinton, ), for example, Reis, Poznanski, Baron, Zasowski, and Shahaf () and Nakoneczny et al (), self‐organizing maps (SOMs; Kohonen, ), for example, Carrasco Kind and Brunner () and Armstrong et al (), or the latent space of a variational encoder (e.g., Ma et al, ; Yang & Li, ). Novel visualization techniques are also contributing.…”

Section: Machine Learning and Artificial Intelligence In Astronomymentioning

confidence: 99%

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

Fluke

Jacobs

2019

WIREs Data Min & Knowl

102

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Machine learning (automated processes that learn by example in order to classify, predict, discover, or generate new data) and artificial intelligence (methods by which a computer makes decisions or discoveries that would usually require human intelligence) are now firmly established in astronomy. Every week, new applications of machine learning and artificial intelligence are added to a growing corpus of work. Random forests, support vector machines, and neural networks are now having a genuine impact for applications as diverse as discovering extrasolar planets, transient objects, quasars, and gravitationally lensed systems, forecasting solar activity, and distinguishing between signals and instrumental effects in gravitational wave astronomy. This review surveys contemporary, published literature on machine learning and artificial intelligence in astronomy and astrophysics. Applications span seven main categories of activity: classification, regression, clustering, forecasting, generation, discovery, and the development of new scientific insights. These categories form the basis of a hierarchy of maturity, as the use of machine learning and artificial intelligence emerges, progresses, or becomes established. This article is categorized under: Application Areas > Science and Technology Fundamental Concepts of Data and Knowledge > Motivation and Emergence of Data Mining Technologies > Machine Learning

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