English

Optimal prior for Bayesian inference in a constrained parameter space

Cosmology and Nongalactic Astrophysics 2019-02-25 v2

Abstract

Bayesian parameter inference depends on a choice of prior probability distribution for the parameters in question. The prior which makes the posterior distribution maximally sensitive to data is called the Jeffreys prior, and it is completely determined by the response of the likelihood to changes in parameters. Under the assumption that the likelihood is a Gaussian distribution, the Jeffreys prior is a constant, i.e. flat. However, if one parameter is constrained by physical considerations, the Gaussian approximation fails and the flat prior is no longer the Jeffreys prior. In this paper we compute the correct Jeffreys prior for a multivariate normal distribution constrained in one dimension, and we apply it to the sum of neutrino masses Σmν\Sigma m_\nu and the tensor-to-scalar ratio rr. We find that one-dimensional marginalised posteriors for these two parameters change considerably and that the 68% and 95% Bayesian upper limits increase by 9% and 4% respectively for Σmν\Sigma m_\nu and 22% and 3% for rr. Adding the prior to an existing chain can be done as a trivial importance sampling in the final step of the analysis proces.

Keywords

Cite

@article{arxiv.1710.08899,
  title  = {Optimal prior for Bayesian inference in a constrained parameter space},
  author = {Steen Hannestad and Thomas Tram},
  journal= {arXiv preprint arXiv:1710.08899},
  year   = {2019}
}

Comments

As it was pointed out in 1802.09450 and later in 1902.07667, the Jeffreys prior is unchanged by restricting a parameter based on physical considerations. This breaks our assumption of a truncated Gaussian in Eq. 2.10 and thus invalidates our conclusions. (In situations where Eq. 2.10 is a good model of the data, the calculation may still be useful.)

R2 v1 2026-06-22T22:24:25.702Z