Mean Testing under Truncation beyond Gaussian

Abstract

We characterize the fundamental limits of high-dimensional mean testing under arbitrary truncation, where samples are drawn from the conditional distribution P(· S) for an unknown truncation set S that may hide up to an -fraction of the probability mass. For distributions with p-th directional moments of magnitude at most P,p, truncation induces a bias of order O(P,p1-1/p). This bias creates a sharp information-theoretic detectability floor: when the signal α falls below this threshold, the null and alternative hypotheses are indistinguishable even with infinite data. Above this floor, we prove that a simple second-order test achieving near-optimal sample complexity n = O\!(\|P\|(α-4P,p1-1/p)2d). We further identify a structural escape from this finite-moment bias barrier. Under a directional median regularity assumption, truncation bias improves to linear order O(). This reveals an intermediate regime in which estimation requires (d) samples for uniform recovery, while testing recovers the classical ( d) rate once truncation bias is eliminated. Together, our results provide a unified framework for mean testing under truncation, connecting finite-moment, sub-Gaussian, and median-regular structural regimes.