exocartographer: A Bayesian Framework for Mapping Exoplanets in Reflected Light
Abstract
Future space telescopes will directly image extrasolar planets at visible wavelengths. Time-resolved reflected light from an exoplanet encodes information about atmospheric and surface inhomogeneities. Previous research has shown that the light curve of an exoplanet can be inverted to obtain a low-resolution map of the planet, as well as constraints on its spin orientation. Estimating the uncertainty on 2D albedo maps has so far remained elusive. Here we present exocartographer, a flexible open-source Bayesian framework for solving the exo-cartography inverse problem. The map is parameterized with equal-area HEALPix pixels. For a fiducial map resolution of 192 pixels, a four-parameter Gaussian process describing the spatial scale of albedo variations, and two unknown planetary spin parameters, exocartographer explores a 198-dimensional parameter space. To test the code, we produce a light curve for a cloudless Earth in a face-on orbit with a 90 obliquity. We produce synthetic white light observations of the planet: 5 epochs of observations throughout the planet's orbit, each consisting of 24 hourly observations with a photometric uncertainty of (120 data). We retrieve an albedo map andfor the first timeits uncertainties, along with spin constraints. The albedo map is recognizably of Earth, with typical uncertainty of . The retrieved characteristic length scale is 88, or 9800 km. The obliquity is recovered with a uncertainty of . Despite the uncertainty in the retrieved albedo map, we robustly identify a high albedo region (the Sahara desert) and a large low-albedo region (the Pacific Ocean).
Cite
@article{arxiv.1802.06805,
title = {exocartographer: A Bayesian Framework for Mapping Exoplanets in Reflected Light},
author = {Ben Farr and Will M. Farr and Nicolas B. Cowan and Hal M. Haggard and Tyler Robinson},
journal= {arXiv preprint arXiv:1802.06805},
year = {2018}
}
Comments
6 pages, 3 figures