English

Smoothed Nested Testing on Directed Acyclic Graphs

Methodology 2021-03-17 v2

Abstract

We consider the problem of multiple hypothesis testing when there is a logical nested structure to the hypotheses. When one hypothesis is nested inside another, the outer hypothesis must be false if the inner hypothesis is false. We model the nested structure as a directed acyclic graph, including chain and tree graphs as special cases. Each node in the graph is a hypothesis and rejecting a node requires also rejecting all of its ancestors. We propose a general framework for adjusting node-level test statistics using the known logical constraints. Within this framework, we study a smoothing procedure that combines each node with all of its descendants to form a more powerful statistic. We prove a broad class of smoothing strategies can be used with existing selection procedures to control the familywise error rate, false discovery exceedance rate, or false discovery rate, so long as the original test statistics are independent under the null. When the null statistics are not independent but are derived from positively-correlated normal observations, we prove control for all three error rates when the smoothing method is arithmetic averaging of the observations. Simulations and an application to a real biology dataset demonstrate that smoothing leads to substantial power gains.

Keywords

Cite

@article{arxiv.1911.09200,
  title  = {Smoothed Nested Testing on Directed Acyclic Graphs},
  author = {Jackson H. Loper and Lihua Lei and William Fithian and Wesley Tansey},
  journal= {arXiv preprint arXiv:1911.09200},
  year   = {2021}
}

Comments

Revised with genetic interaction maps application and new theory of PRDS

R2 v1 2026-06-23T12:22:50.767Z