English

Tractable Bayesian Density Regression via Logit Stick-Breaking Priors

Computation 2020-05-06 v5

Abstract

There is a growing interest in learning how the distribution of a response variable changes with a set of predictors. Bayesian nonparametric dependent mixture models provide a flexible approach to address this goal. However, several formulations require computationally demanding algorithms for posterior inference. Motivated by this issue, we study a class of predictor-dependent infinite mixture models, which relies on a simple representation of the stick-breaking prior via sequential logistic regressions. This formulation maintains the same desirable properties of popular predictor-dependent stick-breaking priors, and leverages a recent P\'olya-gamma data augmentation to facilitate the implementation of several computational methods for posterior inference. These routines include Markov chain Monte Carlo via Gibbs sampling, expectation-maximization algorithms, and mean-field variational Bayes for scalable inference, thereby stimulating a wider implementation of Bayesian density regression by practitioners. The algorithms associated with these methods are presented in detail and tested in a toxicology study.

Keywords

Cite

@article{arxiv.1701.02969,
  title  = {Tractable Bayesian Density Regression via Logit Stick-Breaking Priors},
  author = {Tommaso Rigon and Daniele Durante},
  journal= {arXiv preprint arXiv:1701.02969},
  year   = {2020}
}
R2 v1 2026-06-22T17:47:16.510Z