Adaptive Confidence Intervals in Efron's Gaussian Two-Groups Model
Abstract
Robust uncertainty quantification is increasingly important in modern data analysis and is often formalized under Huber's model, which allows an -fraction of arbitrary corruptions. In many experimental sciences, however, the measurement protocol is well controlled, and contamination is more plausibly introduced upstream. Motivated by this noise-oblivious nature of adversaries, we study confidence intervals for the null location parameter in Efron's Gaussian two-groups model, where an unknown fraction of observations have arbitrarily shifted means, but all samples share the same law of additive Gaussian measurement noise with variance . We characterize the minimax-optimal length among confidence intervals with a prescribed coverage level uniformly over the unknown contamination proportion and all noise-oblivious adversaries. Although prior work has shown that the minimax point estimation rate of theta does not deteriorate when becomes unknown, our results reveal that, with a given , the minimax-optimal length of confidence intervals that are adaptive to unknown is of order , which is polynomially worse than the optimal length when is known. When the variance is also unknown, we show a further degradation: no adaptive confidence interval can be shorter than . Algorithmically, we introduce a Fourier-based certification procedure built on Carath\'{e}odory's positive-semidefiniteness constraints. By scanning candidate points and accepting those whose residual characteristic function is certifiably consistent with a Gaussian location mixture, our algorithm attains the minimax lower bound in the known-variance setting and is computable in polynomial time.
Cite
@article{arxiv.2604.26992,
title = {Adaptive Confidence Intervals in Efron's Gaussian Two-Groups Model},
author = {Qiaosen Wang and Shuwen Chai and Chao Gao},
journal= {arXiv preprint arXiv:2604.26992},
year = {2026}
}
Comments
corrected several typos; no change to main results