English

Quantile Importance Sampling

Computation 2026-03-24 v3 Methodology

Abstract

In Bayesian inference, the approximation of integrals of the form ψ=EFl(X)=χl(x)dF(x)\psi = \mathbb{E}_{F}{l(X)} = \int_{\chi} l(\mathbf{x}) d F(\mathbf{x}) is a fundamental challenge. Such integrals are crucial for evidence estimation, which is important for various purposes, including model selection and numerical analysis. The existing strategies for evidence estimation are classified into four categories: deterministic approximation, density estimation, importance sampling, and vertical representation (Llorente et al., 2020). In this paper, we show that the Riemann sum estimator due to Yakowitz (1978) can be used in the context of nested sampling (Skilling, 2006) to achieve a O(n4)O(n^{-4}) rate of convergence, faster than the usual Ergodic Central Limit Theorem. We provide a brief overview of the literature on the Riemann sum estimators and the nested sampling algorithm and its connections to vertical likelihood Monte Carlo. We provide theoretical and numerical arguments to show how merging these two ideas may result in improved and more robust estimators for evidence estimation, especially in higher dimensional spaces. We also briefly discuss the idea of simulating the Lorenz curve that avoids the problem of intractable Λ\Lambda functions, essential for the vertical representation and nested sampling.

Keywords

Cite

@article{arxiv.2305.03158,
  title  = {Quantile Importance Sampling},
  author = {Jyotishka Datta and Nicholas G. Polson},
  journal= {arXiv preprint arXiv:2305.03158},
  year   = {2026}
}

Comments

Fixed a few typos and errors, and added a real data example

R2 v1 2026-06-28T10:26:11.441Z