English

The L\'evy combination test

Methodology 2021-05-05 v1

Abstract

A novel class of methods for combining pp-values to perform aggregate hypothesis tests has emerged that exploit the properties of heavy-tailed Stable distributions. These methods offer important practical advantages including robustness to dependence and better-than-Bonferroni scaleability, and they reveal theoretical connections between Bayesian and classical hypothesis tests. The harmonic mean pp-value (HMP) procedure is based on the convergence of summed inverse pp-values to the Landau distribution, while the Cauchy combination test (CCT) is based on the self-similarity of summed Cauchy-transformed pp-values. The CCT has the advantage that it is analytic and exact. The HMP has the advantage that it emulates a model-averaged Bayes factor, is insensitive to pp-values near 1, and offers multilevel testing via a closed testing procedure. Here I investigate whether other Stable combination tests can combine these benefits, and identify a new method, the L\'evy combination test (LCT). The LCT exploits the self-similarity of sums of L\'evy random variables transformed from pp-values. Under arbitrary dependence, the LCT possesses better robustness than the CCT and HMP, with two-fold worst-case inflation at small significance thresholds. It controls the strong-sense familywise error rate through a multilevel test uniformly more powerful than Bonferroni. Simulations show that the LCT behaves like Simes' test in some respects, with power intermediate between the HMP and Bonferroni. The LCT represents an interesting and attractive addition to combined testing methods based on heavy-tailed distributions.

Keywords

Cite

@article{arxiv.2105.01501,
  title  = {The L\'evy combination test},
  author = {Daniel J. Wilson},
  journal= {arXiv preprint arXiv:2105.01501},
  year   = {2021}
}
R2 v1 2026-06-24T01:46:08.631Z