Comparative performance of selected variability detection techniques in photometric time series data

Comparative performance of selected variability detection techniques in photometric time series data

Photometric measurements are prone to systematic errors presenting a challenge to low-amplitude variability detection. In search for a general-purpose variability detection technique able to recover a broad range of variability types including currently unknown ones, we test 18 statistical character...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 464; no. 1; p. 274
Main Authors: Sokolovsky, K V, Gavras, P, Karampelas, A, Antipin, S V, Bellas-Velidis, I, Benni, P, Bonanos, A Z, Burdanov, A Y, Derlopa, S, Hatzidimitriou, D, Khokhryakova, A D, Kolesnikova, D M, Korotkiy, S A, Lapukhin, E G, Moretti, M I, Popov, A A, Pouliasis, E, Samus, N N, Spetsieri, Z, Veselkov, S A, Volkov, K V, Yang, M, Zubareva, A M
Format: Journal Article Web Resource
Language:English
Published: London Oxford University Press 01-01-2017
Subjects:
Astronomy
Aérospatiale, astronomie & astrophysique
Brightness
Comparative analysis
Light
Mathematical models
Methods: data analysis
Methods: statistical
Outliers (statistics)
Photometry
Physical, chemical, mathematical & earth Sciences
Physique, chimie, mathématiques & sciences de la terre
Principal components analysis
Sampling
Searching
Space science, astronomy & astrophysics
Stars: variables: general
Time series
Variable stars
Variables
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Summary:Photometric measurements are prone to systematic errors presenting a challenge to low-amplitude variability detection. In search for a general-purpose variability detection technique able to recover a broad range of variability types including currently unknown ones, we test 18 statistical characteristics quantifying scatter and/or correlation between brightness measurements. We compare their performance in identifying variable objects in seven time series data sets obtained with telescopes ranging in size from a telephoto lens to 1 m-class and probing variability on time-scales from minutes to decades. The test data sets together include light curves of 127 539 objects, among them 1251 variable stars of various types and represent a range of observing conditions often found in ground-based variability surveys. The real data are complemented by simulations. We propose a combination of two indices that together recover a broad range of variability types from photometric data characterized by a wide variety of sampling patterns, photometric accuracies and percentages of outlier measurements. The first index is the interquartile range (IQR) of magnitude measurements, sensitive to variability irrespective of a time-scale and resistant to outliers. It can be complemented by the ratio of the light-curve variance to the mean square successive difference, 1/..., which is efficient in detecting variability on time-scales longer than the typical time interval between observations. Variable objects have larger 1/... and/or IQR values than non-variable objects of similar brightness. Another approach to variability detection is to combine many variability indices using principal component analysis. We present 124 previously unknown variable stars found in the test data. (ProQuest: ... denotes formulae/symbols omitted.)
Bibliography:ObjectType-Article-1
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content type line 23
scopus-id:2-s2.0-85014779471
ISSN:0035-8711
1365-2966
1365-2966
DOI:10.1093/mnras/stw2262