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General Bayesian loss function selection and the use of improper models

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  • Jack Jewson
  • David Rossell

Abstract

Statisticians often face the choice between using probability models or a paradigm defined by minimising a loss function. Both approaches are useful and, if the loss can be re‐cast into a proper probability model, there are many tools to decide which model or loss is more appropriate for the observed data, in the sense of explaining the data's nature. However, when the loss leads to an improper model, there are no principled ways to guide this choice. We address this task by combining the Hyvärinen score, which naturally targets infinitesimal relative probabilities, and general Bayesian updating, which provides a unifying framework for inference on losses and models. Specifically we propose the ℋ$$ \mathscr{H} $$‐score, a general Bayesian selection criterion and prove that it consistently selects the (possibly improper) model closest to the data‐generating truth in Fisher's divergence. We also prove that an associated ℋ$$ \mathscr{H} $$‐posterior consistently learns optimal hyper‐parameters featuring in loss functions, including a challenging tempering parameter in generalised Bayesian inference. As salient examples, we consider robust regression and non‐parametric density estimation where popular loss functions define improper models for the data and hence cannot be dealt with using standard model selection tools. These examples illustrate advantages in robustness‐efficiency trade‐offs and enable Bayesian inference for kernel density estimation, opening a new avenue for Bayesian non‐parametrics.

Suggested Citation

  • Jack Jewson & David Rossell, 2022. "General Bayesian loss function selection and the use of improper models," Journal of the Royal Statistical Society Series B, Royal Statistical Society, vol. 84(5), pages 1640-1665, November.
    • Handle: RePEc:bla:jorssb:v:84:y:2022:i:5:p:1640-1665
    DOI: 10.1111/rssb.12553
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    1. Christis Katsouris, 2023. "High Dimensional Time Series Regression Models: Applications to Statistical Learning Methods," Papers 2308.16192, arXiv.org.
    2. Akifumi Okuno, 2024. "Minimizing robust density power-based divergences for general parametric density models," Annals of the Institute of Statistical Mathematics, Springer;The Institute of Statistical Mathematics, vol. 76(5), pages 851-875, October.

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