Nonparametric predictive inference for discrete data via Metropolis-adjusted Dirichlet sequences
Abstract
This article is motivated by challenges in conducting Bayesian inferences on unknown discrete distributions, with a particular focus on count data. To avoid the computational disadvantages of traditional mixture models, we develop a novel Bayesian predictive approach. In particular, our Metropolis-adjusted Dirichlet (MAD) sequence model characterizes the predictive measure as a mixture of a base measure and Metropolis-Hastings kernels centered on previous data points. The resulting MAD sequence is asymptotically exchangeable and the posterior on the data generator takes the form of a martingale posterior. This structure leads to straightforward algorithms for inference on count distributions, with easy extensions to multivariate, regression, and binary data cases. We obtain a useful asymptotic Gaussian approximation and illustrate the methodology on a variety of applications.
Cite
@article{arxiv.2507.08629,
title = {Nonparametric predictive inference for discrete data via Metropolis-adjusted Dirichlet sequences},
author = {Davide Agnoletto and Tommaso Rigon and David B. Dunson},
journal= {arXiv preprint arXiv:2507.08629},
year = {2025}
}