Standardizing Type Ia Supernova Absolute Magnitudes Using Gaussian Process Data Regression
Abstract
We present a novel class of models for Type Ia supernova time-evolving spectral energy distributions (SED) and absolute magnitudes: they are each modeled as stochastic functions described by Gaussian processes. The values of the SED and absolute magnitudes are defined through well-defined regression prescriptions, so that data directly inform the models. As a proof of concept, we implement a model for synthetic photometry built from the spectrophotometric time series from the Nearby Supernova Factory. Absolute magnitudes at peak brightness are calibrated to 0.13 mag in the -band and to as low as 0.09 mag in the blueshifted -band, where the dispersion includes contributions from measurement uncertainties and peculiar velocities. The methodology can be applied to spectrophotometric time series of supernovae that span a range of redshifts to simultaneously standardize supernovae together with fitting cosmological parameters.
Keywords
Cite
@article{arxiv.1302.2925,
title = {Standardizing Type Ia Supernova Absolute Magnitudes Using Gaussian Process Data Regression},
author = {A. G. Kim and R. C. Thomas and G. Aldering and P. Antilogus and C. Aragon and S. Bailey and C. Baltay and S. Bongard and C. Buton and A. Canto and F. Cellier-Holzem and M. Childress and N. Chotard and Y. Copin and H. K. Fakhouri and E. Gangler and J. Guy and M. Kerschhaggl and M. Kowalski and J. Nordin and P. Nugent and K. Paech and R. Pain and E. Pécontal and R. Pereira and S. Perlmutter and D. Rabinowitz and M. Rigault and K. Runge and C. Saunders and R. Scalzo and G. Smadja and C. Tao and B. A. Weaver and C. Wu},
journal= {arXiv preprint arXiv:1302.2925},
year = {2015}
}
Comments
47 pages, 15 figures, accepted for publication by Astrophysical Journal