Exoplanets and Stellar Physics

FINDING EXTRATERRESTRIAL LIFE USING GROUND-BASED HIGH-DISPERSION SPECTROSCOPY

The Astrophysical Journal American Astronomical Society 764:2 (2013) 182

Authors:

IAG Snellen, RJ de Kok, R le Poole, M Brogi, J Birkby

Finding extraterrestrial life using ground-based high-resolution spectroscopy

(2013)

Authors:

Ignas Snellen, Remco de Kok, Rudolf Le Poole, Matteo Brogi, Jayne Birkby

A Gemini ground-based transmission spectrum of WASP-29b: a featureless spectrum from 515 to 720 nm

Monthly Notices of the Royal Astronomical Society 428 (2013) 3680-3692-3680-3692

Authors:

NP Gibson, S Aigrain, JK Barstow, TM Evans, LN Fletcher, PGJ Irwin

Strange news from other stars

Nature Geoscience Springer Nature 6:2 (2013) 81-83

Astrophysically robust systematics removal using variational inference: Application to the first month of kepler data

Monthly Notices of the Royal Astronomical Society 435:4 (2013) 3639-3653

Authors:

S Roberts, A McQuillan, S Reece, S Aigrain

Abstract:

Space-based transit search missions such as Kepler are collecting large numbers of stellar light curves of unprecedented photometric precision and time coverage. However, before this scientific goldmine can be exploited fully, the data must be cleaned of instrumental artefacts. We present a new method to correct common-mode systematics in large ensembles of very high precision light curves. It is based on a Bayesian linear basis model and uses shrinkage priors for robustness, variational inference for speed and a de-noising step based on empirical mode decomposition to prevent the introduction of spurious noise into the corrected light curves. After demonstrating the performance of our method on a synthetic data set, we apply it to the first month of Kepler data. We compare the results, which are publicly available, to the output of the Kepler pipeline's pre-search data conditioning, and show that the two generally give similar results, but the light curves corrected using our approach have lower scatter, on average, on both long and short time-scales. We finish by discussing some limitations of our method and outlining some avenues for further development. The trend-corrected data produced by our approach are publicly available. © 2013 The Authors Published by Oxford University Press on behalf of the Royal Astronomical Society.