FALSE DISCOVERY RATE CONTROL WITH UNKNOWN NULL DISTRIBUTION: IS IT POSSIBLE TO MIMIC THE ORACLE?

Article

Roquain, Etienne; Verzelen, Nicolas

Universite Paris Cite; Centre National de la Recherche Scientifique (CNRS); Universite Paris Cite; Sorbonne Universite; INRAE; Universite de Montpellier; Institut Agro

ANNALS OF STATISTICS

0090-5364

10.1214/21-AOS2141

2022

1095-1123

Classical multiple testing theory prescribes the null distribution, which is often too stringent an assumption for nowadays large scale experiments. This paper presents theoretical foundations to understand the limitations caused by ignoring the null distribution, and how it can be properly learned from the same data set, when possible. We explore this issue in the setting where the null distributions are Gaussian with unknown rescaling parameters (mean and variance) whereas the alternative distributions are let arbitrary. In that case, an oracle procedure is the Benjamini-Hochberg procedure applied with the true (unknown) null distribution and we aim at building a procedure that asymptotically mimics the performances of the oracle (AMO in short). Our main result establishes a phase transition at the sparsity boundary n / log(n): an AMO procedure exists if and only if the number of false nulls is of order less than n / log(n), where n is the total number of tests. Further sparsity boundaries are derived for general location models where the shape of the null distribution is not necessarily Gaussian. In light of our impossibility results, we also pursue the less stringent aim of building a nonparametric confidence region for the null distribution. From a practical perspective, this provides goodness-of-fit tests for the null distribution and allows to assess the reliability of empirical null procedures via novel diagnostic graphs. Our results are illustrated on numerical experiments and real data sets, as detailed in a companion vignette (Roquain and Verzelen (2021)).