Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates

Liang Yu; Andrew Vanderburg; Chelsea Huang; Christopher J. Shallue; Ian J.M. Crossfield; B. Scott Gaudi; Tansu Daylan; Anne Dattilo; David J. Armstrong; George R. Ricker; Roland K. Vanderspek; David W. Latham; Sara Seager; Jason Dittmann; John P. Doty; Ana Glidden; Samuel N. Quinn

doi:10.3847/1538-3881/ab21d6

Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates

Liang Yu
, Andrew Vanderburg
, Chelsea Huang
, Christopher J. Shallue
, Ian J.M. Crossfield
, B. Scott Gaudi
, Tansu Daylan
, Anne Dattilo
, David J. Armstrong
, George R. Ricker
, Roland K. Vanderspek
, David W. Latham
, Sara Seager
, Jason Dittmann
, John P. Doty
, Ana Glidden
, Samuel N. Quinn

Department of Physics

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

NASA's Transiting Exoplanet Survey Satellite (TESS) presents us with an unprecedented volume of space-based photometric observations that must be analyzed in an efficient and unbiased manner. With at least ∼1,000,000 new light curves generated every month from full-frame images alone, automated planet candidate identification has become an attractive alternative to human vetting. Here we present a deep learning model capable of performing triage and vetting on TESS candidates. Our model is modified from an existing neural network designed to automatically classify Kepler candidates, and is the first neural network to be trained and tested on real TESS data. In triage mode, our model can distinguish transit-like signals (planet candidates and eclipsing binaries) from stellar variability and instrumental noise with an average precision (the weighted mean of precisions over all classification thresholds) of 97.0% and an accuracy of 97.4%. In vetting mode, the model is trained to identify only planet candidates with the help of newly added scientific domain knowledge, and achieves an average precision of 69.3% and an accuracy of 97.8%. We apply our model on new data from Sector 6, and present 288 new signals that received the highest scores in triage and vetting and were also identified as planet candidates by human vetters. We also provide a homogeneously classified set of TESS candidates suitable for future training.

Original language	English
Article number	25
Journal	Astronomical Journal
Volume	158
Issue number	1
DOIs	https://doi.org/10.3847/1538-3881/ab21d6
State	Published - 2019

Keywords

methods: data analysis
planets and satellites: detection
techniques: photometric

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10.3847/1538-3881/ab21d6

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Yu, L., Vanderburg, A., Huang, C., Shallue, C. J., Crossfield, I. J. M., Gaudi, B. S., Daylan, T., Dattilo, A., Armstrong, D. J., Ricker, G. R., Vanderspek, R. K., Latham, D. W., Seager, S., Dittmann, J., Doty, J. P., Glidden, A., & Quinn, S. N. (2019). Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates. Astronomical Journal, 158(1), Article 25. https://doi.org/10.3847/1538-3881/ab21d6

@article{2a2883d089f941afb24b9d5962e2f869,

title = "Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates",

abstract = "NASA's Transiting Exoplanet Survey Satellite (TESS) presents us with an unprecedented volume of space-based photometric observations that must be analyzed in an efficient and unbiased manner. With at least ∼1,000,000 new light curves generated every month from full-frame images alone, automated planet candidate identification has become an attractive alternative to human vetting. Here we present a deep learning model capable of performing triage and vetting on TESS candidates. Our model is modified from an existing neural network designed to automatically classify Kepler candidates, and is the first neural network to be trained and tested on real TESS data. In triage mode, our model can distinguish transit-like signals (planet candidates and eclipsing binaries) from stellar variability and instrumental noise with an average precision (the weighted mean of precisions over all classification thresholds) of 97.0\% and an accuracy of 97.4\%. In vetting mode, the model is trained to identify only planet candidates with the help of newly added scientific domain knowledge, and achieves an average precision of 69.3\% and an accuracy of 97.8\%. We apply our model on new data from Sector 6, and present 288 new signals that received the highest scores in triage and vetting and were also identified as planet candidates by human vetters. We also provide a homogeneously classified set of TESS candidates suitable for future training.",

keywords = "methods: data analysis, planets and satellites: detection, techniques: photometric",

author = "Liang Yu and Andrew Vanderburg and Chelsea Huang and Shallue, \{Christopher J.\} and Crossfield, \{Ian J.M.\} and Gaudi, \{B. Scott\} and Tansu Daylan and Anne Dattilo and Armstrong, \{David J.\} and Ricker, \{George R.\} and Vanderspek, \{Roland K.\} and Latham, \{David W.\} and Sara Seager and Jason Dittmann and Doty, \{John P.\} and Ana Glidden and Quinn, \{Samuel N.\}",

year = "2019",

doi = "10.3847/1538-3881/ab21d6",

language = "English",

volume = "158",

journal = "Astronomical Journal",

issn = "0004-6256",

number = "1",

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Yu, L, Vanderburg, A, Huang, C, Shallue, CJ, Crossfield, IJM, Gaudi, BS, Daylan, T, Dattilo, A, Armstrong, DJ, Ricker, GR, Vanderspek, RK, Latham, DW, Seager, S, Dittmann, J, Doty, JP, Glidden, A & Quinn, SN 2019, 'Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates', Astronomical Journal, vol. 158, no. 1, 25. https://doi.org/10.3847/1538-3881/ab21d6

TY - JOUR

T1 - Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates

AU - Yu, Liang

AU - Vanderburg, Andrew

AU - Huang, Chelsea

AU - Shallue, Christopher J.

AU - Crossfield, Ian J.M.

AU - Gaudi, B. Scott

AU - Daylan, Tansu

AU - Dattilo, Anne

AU - Armstrong, David J.

AU - Ricker, George R.

AU - Vanderspek, Roland K.

AU - Latham, David W.

AU - Seager, Sara

AU - Dittmann, Jason

AU - Doty, John P.

AU - Glidden, Ana

AU - Quinn, Samuel N.

PY - 2019

Y1 - 2019

N2 - NASA's Transiting Exoplanet Survey Satellite (TESS) presents us with an unprecedented volume of space-based photometric observations that must be analyzed in an efficient and unbiased manner. With at least ∼1,000,000 new light curves generated every month from full-frame images alone, automated planet candidate identification has become an attractive alternative to human vetting. Here we present a deep learning model capable of performing triage and vetting on TESS candidates. Our model is modified from an existing neural network designed to automatically classify Kepler candidates, and is the first neural network to be trained and tested on real TESS data. In triage mode, our model can distinguish transit-like signals (planet candidates and eclipsing binaries) from stellar variability and instrumental noise with an average precision (the weighted mean of precisions over all classification thresholds) of 97.0% and an accuracy of 97.4%. In vetting mode, the model is trained to identify only planet candidates with the help of newly added scientific domain knowledge, and achieves an average precision of 69.3% and an accuracy of 97.8%. We apply our model on new data from Sector 6, and present 288 new signals that received the highest scores in triage and vetting and were also identified as planet candidates by human vetters. We also provide a homogeneously classified set of TESS candidates suitable for future training.

AB - NASA's Transiting Exoplanet Survey Satellite (TESS) presents us with an unprecedented volume of space-based photometric observations that must be analyzed in an efficient and unbiased manner. With at least ∼1,000,000 new light curves generated every month from full-frame images alone, automated planet candidate identification has become an attractive alternative to human vetting. Here we present a deep learning model capable of performing triage and vetting on TESS candidates. Our model is modified from an existing neural network designed to automatically classify Kepler candidates, and is the first neural network to be trained and tested on real TESS data. In triage mode, our model can distinguish transit-like signals (planet candidates and eclipsing binaries) from stellar variability and instrumental noise with an average precision (the weighted mean of precisions over all classification thresholds) of 97.0% and an accuracy of 97.4%. In vetting mode, the model is trained to identify only planet candidates with the help of newly added scientific domain knowledge, and achieves an average precision of 69.3% and an accuracy of 97.8%. We apply our model on new data from Sector 6, and present 288 new signals that received the highest scores in triage and vetting and were also identified as planet candidates by human vetters. We also provide a homogeneously classified set of TESS candidates suitable for future training.

KW - methods: data analysis

KW - planets and satellites: detection

KW - techniques: photometric

UR - https://www.scopus.com/pages/publications/85072404153

U2 - 10.3847/1538-3881/ab21d6

DO - 10.3847/1538-3881/ab21d6

M3 - Article

AN - SCOPUS:85072404153

SN - 0004-6256

VL - 158

JO - Astronomical Journal

JF - Astronomical Journal

IS - 1

M1 - 25

ER -

Identifying Exoplanets with Deep Learning. III. Automated Triage and Vetting of TESS Candidates

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Keywords

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