TY - JOUR
T1 - IMPROVING EXOPLANET DETECTION POWER
T2 - MULTIVARIATE GAUSSIAN PROCESS MODELS FOR STELLAR ACTIVITY
AU - Jones, David E.
AU - Stenning, David C.
AU - Ford, Eric B.
AU - Wolpert, Robert L.
AU - Loredo, Thomas J.
AU - Gilbertson, Christian
AU - Dumusque, Xavier
N1 - Funding Information:
Funding. This material is based upon work supported by the National Science Foundation under Grants No. DMS-1127914 (to the Statistical and Applied Mathematical Sciences Institute), AST-1616086 (to E.B.F.), AST-1312903 (to T.J.L), and DMS-1622403, SES-1521855, and ACI-1550225 (to R.L.W.). Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation. E.B.F. acknowledges support from the Penn State Eberly College of Science and Department of Astronomy & Astrophysics, the Center for Astrostatistics, the Institute for CyberScience, and the Center for Exoplanets and Habitable Worlds which is supported by Pennsylvania State University, the Eberly College of Science, and the Pennsylvania Space Grant Consortium. E.B.F. also acknowledges support from NASA Exoplanets Research Program grant #NNX15AE21G and supporting collaborations within NASA’s Nexus for Exoplanet System Science (NExSS). NASA Exo-planets Research Program #NNX15AE21G. This research was supported by Heising-Simons Foundation Grant #2019-1177 and by a grant from the Simons Foundation/SFARI (675601, E.B.F.). T.J.L. acknowledges support from NASA Astrophysics Data Analysis Program grant #NNX16AL02G. X.D. acknowledges the Society in Science’s Branco Weiss Fellowship for its financial support. X.D. also acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement SCORE No 851555). D.C.S. acknowledges the support of the Natural Sciences and Engineering Research Council of Canada (NSERC), RGPIN-2021-03985.
Publisher Copyright:
© Institute of Mathematical Statistics, 2022.
PY - 2022/6
Y1 - 2022/6
N2 - The radial velocity method is one of the most successful techniques for detecting exoplanets. It works by detecting the velocity of a host star, induced by the gravitational effect of an orbiting planet, specifically, the velocity along our line of sight which is called the radial velocity of the star. Low-mass planets typically cause their host star to move with radial velocities of 1 m/s or less. By analyzing a time series of stellar spectra from a host star, modern astronomical instruments can, in theory, detect such planets. However, in practice, intrinsic stellar variability (e.g., star spots, convective motion, pulsa-tions) affects the spectra and often mimics a radial velocity signal. This signal contamination makes it difficult to reliably detect low-mass planets. A prin-cipled approach to recovering planet radial velocity signals in the presence of stellar activity was proposed by Rajpaul et al. (Mon. Not. R. Astron. Soc. 452 (2015) 2269–2291). It uses a multivariate Gaussian process model to jointly capture time series of the apparent radial velocity and multiple indicators of stellar activity. We build on this work in two ways: (i) we propose using dimension reduction techniques to construct new high-information stellar activity indicators; and (ii) we extend the Rajpaul et al. (Mon. Not. R. Astron. Soc. 452 (2015) 2269–2291) model to a larger class of models and use a power-based model comparison procedure to select the best model. Despite significant interest in exoplanets, previous efforts have not performed large-scale stellar activity model selection or attempted to evaluate models based on planet detection power. In the case of main sequence G2V stars, we find that our method substantially improves planet detection power, compared to previous state-of-the-art approaches.
AB - The radial velocity method is one of the most successful techniques for detecting exoplanets. It works by detecting the velocity of a host star, induced by the gravitational effect of an orbiting planet, specifically, the velocity along our line of sight which is called the radial velocity of the star. Low-mass planets typically cause their host star to move with radial velocities of 1 m/s or less. By analyzing a time series of stellar spectra from a host star, modern astronomical instruments can, in theory, detect such planets. However, in practice, intrinsic stellar variability (e.g., star spots, convective motion, pulsa-tions) affects the spectra and often mimics a radial velocity signal. This signal contamination makes it difficult to reliably detect low-mass planets. A prin-cipled approach to recovering planet radial velocity signals in the presence of stellar activity was proposed by Rajpaul et al. (Mon. Not. R. Astron. Soc. 452 (2015) 2269–2291). It uses a multivariate Gaussian process model to jointly capture time series of the apparent radial velocity and multiple indicators of stellar activity. We build on this work in two ways: (i) we propose using dimension reduction techniques to construct new high-information stellar activity indicators; and (ii) we extend the Rajpaul et al. (Mon. Not. R. Astron. Soc. 452 (2015) 2269–2291) model to a larger class of models and use a power-based model comparison procedure to select the best model. Despite significant interest in exoplanets, previous efforts have not performed large-scale stellar activity model selection or attempted to evaluate models based on planet detection power. In the case of main sequence G2V stars, we find that our method substantially improves planet detection power, compared to previous state-of-the-art approaches.
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U2 - 10.1214/21-AOAS1471
DO - 10.1214/21-AOAS1471
M3 - Article
AN - SCOPUS:85132791106
SN - 1932-6157
VL - 16
SP - 652
EP - 679
JO - Annals of Applied Statistics
JF - Annals of Applied Statistics
IS - 2
ER -