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Steve: a hierarchical Bayesian model for supernova cosmology

Research output: Contribution to journalArticle

  • S. R. Hilton
  • T. M. Davis
  • Alex G. Kim
  • D. Brout
  • Christopher Brian D'Andrea
  • Richard Kessler
  • J. Lasker
  • Christopher E. Lidman
  • Edward Robert Mark Macaulay
  • A. Möller
  • M. Sako
  • Daniel M. Scolnic
  • M. Smith
  • R. C. Wolf
  • Michael J. Childress
  • E. P. Morganson
  • S. Allam
  • James T. Annis
  • S. Avila
  • Emmanuel Bertin
  • D. Brooks
  • David L. Burke
  • Aurelio Carnero Rosell
  • M. Carrasco Kind
  • C. E. Cunha
  • Luiz Alberto Nicolaci da Costa
  • Clare Davis
  • Juan De Vicente
  • D. L. DePoy
  • Peter Doel
  • Tim F. Eifler
  • B. Flaugher
  • P. Fosalba
  • Joshua A. Frieman
  • J. García-Bellido
  • Enrique Gaztanaga
  • David W. Gerdes
  • Robert A. Gruendl
  • Julia Gschwend
  • G. Gutierrez
  • William G. Hartley
  • Devon L. Hollowood
  • Klaus Honscheid
  • E. Krause
  • Kyler Kuehn
  • Nikolay Kuropatkin
  • Ofer Lahav
  • M. Lima
  • Marcio Antonio Geimba Maia
  • M. March
  • Jennifer L. Marshall
  • Felipe Menanteau
  • Ramon Miquel
  • Ricardo L. C. Ogando
  • Andres A. Plazas
  • Eusebio Sanchez
  • Vic Scarpine
  • R. Schindler
  • Michael Schubnell
  • Santiago Serrano
  • Ignacio Sevilla-Noarbe
  • Marcelle Soares-Santos
  • F. Sobreira
  • Eric Suchyta
  • Gregory Tarle
  • V. Vikram
  • Y. Zhang
We present a new Bayesian hierarchical model (BHM) named Steve for performing Type Ia supernova (SN Ia) cosmology fits. This advances previous works by including an improved treatment of Malmquist bias, accounting for additional sources of systematic uncertainty, and increasing numerical efficiency. Given light-curve fit parameters, redshifts, and host-galaxy masses, we fit Steve simultaneously for parameters describing cosmology, SN Ia populations, and systematic uncertainties. Selection effects are characterized using Monte Carlo simulations. We demonstrate its implementation by fitting realizations of SN Ia data sets where the SN Ia model closely follows that used in Steve. Next, we validate on more realistic SNANA simulations of SN Ia samples from the Dark Energy Survey and low-redshift surveys (DES Collaboration et al. 2018). These simulated data sets contain more than 60,000 SNe Ia, which we use to evaluate biases in the recovery of cosmological parameters, specifically the equation of state of dark energy, w. This is the most rigorous test of a BHM method applied to SN Ia cosmology fitting and reveals small w biases that depend on the simulated SN Ia properties, in particular the intrinsic SN Ia scatter model. This w bias is less than 0.03 on average, less than half the statistical uncertainty on w. These simulation test results are a concern for BHM cosmology fitting applications on large upcoming surveys; therefore, future development will focus on minimizing the sensitivity of Steve to the SN Ia intrinsic scatter model.
Original languageEnglish
Article number15
Pages (from-to)1-21
Number of pages21
JournalThe Astrophysical Journal
Volume876
Issue number1
DOIs
Publication statusPublished - 29 Apr 2019

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  • Hinton_2019_ApJ_876_15

    Rights statement: S. R. Hinton et al. 2019 ApJ 876:1. © 2019 The American Astronomical Society. All rights reserved. Reproduced by permission of the AAS.

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