English

Weighted Bayesian Conformal Prediction

Machine Learning 2026-04-09 v1 Applied Physics Machine Learning

Abstract

Conformal prediction provides distribution-free prediction intervals with finite-sample coverage guarantees, and recent work by Snell \& Griffiths reframes it as Bayesian Quadrature (BQ-CP), yielding powerful data-conditional guarantees via Dirichlet posteriors over thresholds. However, BQ-CP fundamentally requires the i.i.d. assumption -- a limitation the authors themselves identify. Meanwhile, weighted conformal prediction handles distribution shift via importance weights but remains frequentist, producing only point-estimate thresholds. We propose \textbf{Weighted Bayesian Conformal Prediction (WBCP)}, which generalizes BQ-CP to arbitrary importance-weighted settings by replacing the uniform Dirichlet \Dir(1,,1)\Dir(1,\ldots,1) with a weighted Dirichlet \Dir(\neffw~1,,\neffw~n)\Dir(\neff \cdot \tilde{w}_1, \ldots, \neff \cdot \tilde{w}_n), where \neff\neff is Kish's effective sample size. We prove four theoretical results: (1)~\neff\neff is the unique concentration parameter matching frequentist and Bayesian variances; (2)~posterior standard deviation decays as O(1/\neff)O(1/\sqrt{\neff}); (3)~BQ-CP's stochastic dominance guarantee extends to per-weight-profile data-conditional guarantees; (4)~the HPD threshold provides O(1/\neff)O(1/\sqrt{\neff}) improvement in conditional coverage. We instantiate WBCP for spatial prediction as \emph{Geographical BQ-CP}, where kernel-based spatial weights yield per-location posteriors with interpretable diagnostics. Experiments on synthetic and real-world spatial datasets demonstrate that WBCP maintains coverage guarantees while providing substantially richer uncertainty information.

Keywords

Cite

@article{arxiv.2604.06464,
  title  = {Weighted Bayesian Conformal Prediction},
  author = {Xiayin Lou and Peng Luo},
  journal= {arXiv preprint arXiv:2604.06464},
  year   = {2026}
}
R2 v1 2026-07-01T11:58:21.013Z