Implicit biases in transit models using stellar pseudo-density

Abstract

The transit technique is responsible for the majority of exoplanet discoveries to date. Characterizing these planets involves careful modeling of their transit profiles. A common technique involves expressing the transit duration using a density-like parameter, , often called the "circular density." Most notably, the Kepler project -- the largest analysis of transit lightcurves to date -- adopted a linear prior on . Here, we show that such a prior biases measurements of impact parameter, b, due to the non-linear relationship between and transit duration. This bias slightly favors low values (b 0.3) and strongly disfavors high values (b 0.7) unless transit signal-to-noise ratio is sufficient to provide an independent constraint on b, a criterion that is not satisfied for the majority of Kepler planets. Planet-to-star radius ratio, r, is also biased due to r-b covariance. Consequently, the median Kepler DR25 target suffers a 1.6\% systematic underestimate of r. We present a techniques for correcting these biases and for avoiding them in the first place.