Evaluating the Classification of Fermi BCUs from the 4FGL Catalog Using Machine Learning

Kang, S. J.; Li, Enze; Ou, W.; Zhu, Kongfu; Fan, J. H.; Wu, Qingwen; Yin, Yue

doi:10.3847/1538-4357/ab558b

Cited by 21 publications

(32 citation statements)

References 70 publications

(78 reference statements)

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“…For example, the source numbered as 4FGL J0531.7+1241c is obtained as uncertain type, while it is evaluated as an AGN in ANN classifier and evaluated as an other γ-ray source in RF classifier. Hence, the accuracy is improved, although the number of candidates is reduced (e.g., Kang et al 2019b). The combined test results of the two algorithms are shown in Table 4.…”

Section: Individual Algorithm Resultsmentioning

confidence: 99%

“…Since different features play different roles in the classifiers, the selection of suitable input features for the SML is necessary. Noticing that, i) More input features do not always result in higher accuracy (Kang et al 2019b); ii) More features need more computation; iii) The favorable features for the selection of the AGNs are different from those for pulsars, we further select the features for the two steps from the 36 usable features.…”

Section: Dataset Preparationmentioning

confidence: 99%

See 1 more Smart Citation

Searching for AGN and Pulsar Candidates in 4FGL Unassociated Sources Using Machine Learning

Zhu,

Kang,

Zheng

2020

Preprint

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In a new release of the fourth Fermi Large Area Telescope source catalog (4FGL) in September a) , 5065 γ-ray sources are reported, including 3207 active galactic nuclei (AGNs), 239 pulsars, 190 other sources and 1429 unassociated sources. We employ two different supervised machine learning classifiers, combined with the direct observation parameters given by the 4FGL fits table b) , to search for sources potentially classified as AGNs and pulsars in the 1429 unassociated sources. In order to reduce the error caused by the large difference in the sizes of samples, we divide the classification process into two separate steps in order to identify the AGNs and the pulsars. First, we select the identified AGNs from all of the samples, and then select the identified pulsars from the remaining. Using the 4FGL sources associated or identified as AGNs, pulsars, and other sources with the features selected through the K-S test, we trained, optimized, and tested our classifier models. Then, the models are applied to classify the 1429 unassociated sources. According to the direct calculation results of the two classifiers, we show the sensitivity, specificity, accuracy in each step, and the class of unassociated sources given by each classifier. The accuracy obtained in the first step is approximately 95%; in the second step, the obtained overall accuracy is approximately 80%. Combining the results of the two classifiers, we predict that there are 674 AGN-type candidates, 86 pulsar-type candidates, 177 other types of γ-ray candidates, and 492 of uncertain type.

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Section: Individual Algorithm Resultsmentioning

confidence: 99%

Section: Dataset Preparationmentioning

confidence: 99%

Searching for AGN and Pulsar Candidates in 4FGL Unassociated Sources Using Machine Learning

Zhu,

Kang,

Zheng

2020

Preprint

Self Cite

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“…• Active galactic nuclei and quasars. A common theme in this field is the need for classification and detection methods, including assigning morphological types to radio-detected active galactic nuclei with a CNN (Ma et al, 2019), identifying blazar candidates in the Fermi-LAT (3LAC) Clean Sample (Kang et al, 2019), detecting rare high-redshift, extremely luminous quasars (Schindler et al, 2017), and discriminating populations of broad absorption line quasars (BALQs) from non-BALQs in SDSS data releases (Yong et al, 2018). • Cosmological simulations.…”

Section: Progressingmentioning

confidence: 99%

“…Duev et al () trained a CNN to discover fast‐moving candidates from ZTF observations in order to more reliably identify potentially hazardous near‐Earth objects. Active galactic nuclei and quasars . A common theme in this field is the need for classification and detection methods, including assigning morphological types to radio‐detected active galactic nuclei with a CNN (Ma et al, ), identifying blazar candidates in the Fermi‐LAT (3LAC) Clean Sample (Kang et al, ), detecting rare high‐redshift, extremely luminous quasars (Schindler et al, ), and discriminating populations of broad absorption line quasars (BALQs) from non‐BALQs in SDSS data releases (Yong et al, ). Cosmological simulations . ML is providing new methods for examining the outputs of cosmological simulations, leading to new insights about the connections between physical properties of galaxies, dark matter halos and the cosmic environment.…”

Section: Assessing the Maturity Of Adoptionmentioning

confidence: 99%

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

Fluke

Jacobs

2019

WIREs Data Min & Knowl

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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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“…Indeed, some potential BL Lac or FSRQ candidates can be identified from the BCUs sample in the 2FGL/3FGL catalogues using different approaches such as supervised machine learning (e.g., support vector machine [SVM] and random forest [RF]; Hassan et al (2013)), neural network (Chiaro et al 2016), artificial neural network (ANN; Salvetti et al 2017), multivariate classification method (Lefaucheur & Pita 2017), and by statisical analysis of the broadband spectral properties (including spectral indices in the gamma-ray, X-ray, optical, and radio bands; Yi et al 2017). In addition, we've identified potential BL Lacs and FS-RQs candidates from the 3LAC Clean sample using 4 different SML algorithms (Mclust Gaussian finite mixture models, Decision trees, RF, and SVM; Kang et al 2019a [Paper I]) and from the 4FGL catalogue using 3 different SML algorithms (ANN, RF, and SVM; Kang et al 2019b). Nevertheless, the final confirmation of the BCU nature of candidates in all above approaches is subject to the observations of optical spectroscopy or counterparts in other wavelength (e.g., Massaro et al 2014;Álvarez Crespo et al 2016a,b,c;Massaro et al 2016;Marchesini et al 2016;Klindt et al 2017;Peña-Herazo et al 2017;Marchesi et al 2018;Desai et al 2019;Marchesini et al 2019;Peña-Herazo et al 2019), or broadband spectral features (e.g., Fermi/LAT collaboration, Massaro et al 2009Massaro et al , 2012Massaro et al , 2016Álvarez Crespo et al 2016a,b,c).…”

Section: Introductionmentioning

confidence: 99%

An Empirical “High-confidence” Candidate Zone for Fermi BL Lacertae Objects

Kang

Zhu

Feng

et al. 2020

ApJ

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In the third catalog of active galactic nuclei detected by the F ermi Large Area Telescope Clean (3LAC) sample, there are 402 blazars candidates of uncertain type (BCU). The proposed analysis will help to evaluate the potential optical classification flat spectrum radio quasars (FSRQs) versus BL Lacertae (BL Lacs) objects of BCUs, which can help to understand which is the most elusive class of blazar hidden in the Fermi sample. By studying the 3LAC sample, we found some critical values of γ-ray photon spectral index (Γ ph ), variability index (VI) and radio flux (F R ) of the sources separate known FSRQs and BL Lac objects. We further utilize those values to defined an empirical "highconfidence" candidate zone that can be used to classify the BCUs. Within such a zone (Γ ph < 2.187, logF R < 2.258 and logVI < 1.702), we found that 120 BCUs can be classified BL Lac candidates with a higher degree of confidence (with a misjudged rate < 1%). Our results suggest that an empirical "high confidence" diagnosis is possible to distinguish the BL Lacs from the Fermi observations based on only on the direct observational data of Γ ph , VI and F R .

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Evaluating the Classification of Fermi BCUs from the 4FGL Catalog Using Machine Learning

Cited by 21 publications

References 70 publications

Searching for AGN and Pulsar Candidates in 4FGL Unassociated Sources Using Machine Learning

Searching for AGN and Pulsar Candidates in 4FGL Unassociated Sources Using Machine Learning

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

An Empirical “High-confidence” Candidate Zone for Fermi BL Lacertae Objects

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