UNITY: Confronting Supernova Cosmology's Statistical and Systematic Uncertainties in a Unified Bayesian Framework
Abstract
While recent supernova cosmology research has benefited from improved measurements, current analysis approaches are not statistically optimal and will prove insufficient for future surveys. This paper discusses the limitations of current supernova cosmological analyses in treating outliers, selection effects, shape- and color-standardization relations, unexplained dispersion, and heterogeneous observations. We present a new Bayesian framework, called UNITY (Unified Nonlinear Inference for Type-Ia cosmologY), that incorporates significant improvements in our ability to confront these effects. We apply the framework to real supernova observations and demonstrate smaller statistical and systematic uncertainties. We verify earlier results that SNe Ia require nonlinear shape and color standardizations, but we now include these nonlinear relations in a statistically well-justified way. This analysis was primarily performed blinded, in that the basic framework was first validated on simulated data before transitioning to real data. We also discuss possible extensions of the method.
Cite
@article{arxiv.1507.01602,
title = {UNITY: Confronting Supernova Cosmology's Statistical and Systematic Uncertainties in a Unified Bayesian Framework},
author = {David Rubin and Greg Aldering and Kyle Barbary and Kyle Boone and Greta Chappell and Miles Currie and Susana Deustua and Parker Fagrelius and Andrew Fruchter and Brian Hayden and Chris Lidman and Jakob Nordin and Saul Perlmutter and Clare Saunders and Caroline Sofiatti},
journal= {arXiv preprint arXiv:1507.01602},
year = {2016}
}
Comments
Minor fix in PGM