Evaluating the Optical Classification of Fermi BCUs Using Machine Learning

Kang, S. J.; Jiang, Fan; Mao, Weiming; Wu, Qingwen; Feng, Jian‐Chao; Yin, Yue

doi:10.3847/1538-4357/ab0383

Cited by 39 publications

(34 citation statements)

References 69 publications

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“…We then compared our 120 identified BL Lac candidates with some other recent studies. We found that our results are mostly consistent with previous works presented in Chiaro et al (2016); Lefaucheur & Pita (2017); Yi et al (2017) and Kang et al (2019a) which utilize different statistical (e.g., SML) algorithms (see Table 4 and Table 3). The exceptions are as follows: 2 sources do not find matching sources and 2 sources did not provide a clear classification in Lefaucheur & Pita (2017).…”

Section: Comparison With Literature Resultssupporting

confidence: 91%

“…The exceptions are as follows: 2 sources do not find matching sources and 2 sources did not provide a clear classification in Lefaucheur & Pita (2017). In addition, only 3 sources are classified as FSRQs in M clust Gaussian Mixture Modelling (M 8 ), and two are classified as FRSQs using support vector machine (SVM 8 ) using 8 parameters in Kang et al 2019a; 1 source is classified as an FSRQ in Chiaro et al 2016 (Chi16), whereas two sources are classified as FRSQs in Yi et al 2017 (Y17). The results, provided in Table 4, indicate the highest mismatch rate (e.g., rate = 3/120% ∼2.5%) is less than 3%.…”

Section: Comparison With Literature Resultsmentioning

confidence: 99%

“…The BL Lac candidates using the "ai < X candidate zone" are listed in Column 7. Columns 8-11 (M8, DT8, RF8, and SVM8) indicate the BL Lac -type ("bll") candidates identified by 4 different supervised machine learning (SML) algorithms (Mclust Gaussian finite mixture models (M8), Decision trees (DT8), Random forests (RF8) and support vector machines (SVM8)) with 8 parameters in Kang et al 2019a. Column 12 (LP17) lists the classifications ("bll" for BL Lac, "unc" for uncertain and "-" for a mismatched source by cross comparison) in Lefaucheur 36 118 109 110 108 105 4 bll 120 117 120 120 118 119 116 118 24 41 2 11 10 12 15 63 74 fsrq 0 3 0 0 2 1 0 2 0 0 0 0 0 0 0 1 unc 2 43 52 Note-Column 1 shows the classifications (− represents the number of mismatch by cross comparison, "bll" ,"fsrq" and "unc" indicate BL Lac, FSRQ and uncertain type respectively).…”

Section: Data Selection and Analysismentioning

confidence: 99%

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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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Section: Comparison With Literature Resultssupporting

confidence: 91%

Section: Comparison With Literature Resultsmentioning

confidence: 99%

Section: Data Selection and Analysismentioning

confidence: 99%

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

Kang

Zhu

Feng

et al. 2020

ApJ

Self Cite

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“…In addition, we also should note that all of the default settings (e.g., the probabilities: p > 0.5 in each classifier to consider a correct classification, see Table 3) for each of the three classification functions (e.g., randomF orest(), svm() and nnet() function) are used in Section 4. For each different classification method, choosing the calculation model and setting each parameter in the fitting function can also affect the predictive models, accuracy, and results (e.g., see the discussions in Kang et al 2019). The selections of the appropriate parameter settings need further investigation; this is beyond the scope of the current work.…”

Section: Discussionmentioning

confidence: 99%

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

Kang¹,

Li²,

Ou³

et al. 2019

ApJ

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The recently published fourth Fermi Large Area Telescope source catalog (4FGL) a)b) , reports 5065 gamma-ray sources in terms of direct observational gamma-ray properties. Among the sources, the largest population is the Active Galactic Nuclei (AGN), which consists of 3137 blazars, 42 radio galaxies, and 28 other AGNs. The blazar sample comprises 694 flat-spectrum radio quasars (FSRQs), 1131 BL Lac-type objects (BL Lacs), and 1312 blazar candidates of an unknown type (BCUs). The classification of blazars is difficult using optical spectroscopy given the limited knowledge with respect to their intrinsic properties, and the limited availability of astronomical observations. To overcome these challenges, machine learning algorithms are being investigated as alternative approaches. Using the 4FGL catalog, a sample of 3137 Fermi blazars with 23 parameters is systematically selected. Three established supervised machine learning algorithms (random forests (RFs), support vector machines (SVMs), artificial neural networks (ANNs)) are employed to general predictive models to classify the BCUs. We analyze the results for all of the different combinations of parameters. Interestingly, a previously reported trend the use of more parameters leading to higher accuracy is not found. Considering the least number of parameters used, combinations of eight, 12 or 10 parameters in the SVM, ANN, or RF generated models achieve the highest accuracy (Accuracy ≃ 91.8%, or ≃ 92.9%). Using the combined classification results from the optimal combinations of parameters, 724 BL Lac type candidates and 332 FSRQ type candidates are predicted; however, 256 remain without a clear prediction.

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“…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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Evaluating the Optical Classification of Fermi BCUs Using Machine Learning

Cited by 39 publications

References 69 publications

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

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

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

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

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