Autoregressive Planet Search: Application to the Kepler Mission
Abstract
The 4 yr light curves of 156,717 stars observed with NASA's Kepler mission are analyzed using the autoregressive planet search (ARPS) methodology described by Caceres et al. The three stages of processing are maximum-likelihood ARIMA modeling of the light curves to reduce stellar brightness variations, constructing the transit comb filter periodogram to identify transit-like periodic dips in the ARIMA residuals, and Random Forest classification trained on Kepler team confirmed planets using several dozen features from the analysis. Orbital periods between 0.2 and 100 days are examined. The result is a recovery of 76% of confirmed planets, 97% when period and transit depth constraints are added. The classifier is then applied to the full Kepler data set; 1004 previously noticed and 97 new stars have light-curve criteria consistent with the confirmed planets, after subjective vetting removes clear false alarms and false positive cases. The 97 Kepler ARPS candidate transits mostly have periods of P < 10 days; many are ultrashort period hot planets with radii <1% of the host star. Extensive tabular and graphical output from the ARPS time series analysis is provided to assist in other research relating to the Kepler sample.
Más información
Título según WOS: | Autoregressive Planet Search: Application to the Kepler Mission |
Título según SCOPUS: | Autoregressive Planet Search: Application to the Kepler Mission |
Título de la Revista: | ASTRONOMICAL JOURNAL |
Volumen: | 158 |
Número: | 2 |
Editorial: | IOP PUBLISHING LTD |
Fecha de publicación: | 2019 |
Idioma: | English |
DOI: |
10.3847/1538-3881/ab26ba |
Notas: | ISI, SCOPUS |