Efficient Robust Constrained Signal Detection via Kolmogorov Width Approximations
Abstract
Robust statistical inference often faces a severe computational-statistical gap when dealing with complex parameter spaces. We investigate minimax signal detection in the Gaussian sequence model under strong -contamination, where the signal belongs to a general prior constraint . Existing optimal tests require computing the exact Kolmogorov -width of , a computationally intractable task for general non-trivial sets. We bridge this gap by proposing a polynomial-time testing framework that universally applies to balanced, type-2, and exactly 2-convex constraints. By leveraging a semidefinite programming relaxation and a modified ellipsoid method equipped with an approximate subgradient oracle, we efficiently approximate the Kolmogorov widths. Remarkably, our unconditional efficient algorithm achieves a robust detection boundary that matches existing upper bounds up to a mere polylogarithmic factor. This establishes a computationally tractable testing solution for a broad class of structured signals without requiring prior knowledge of their exact geometric complexity.
Cite
@article{arxiv.2605.11238,
title = {Efficient Robust Constrained Signal Detection via Kolmogorov Width Approximations},
author = {Yikun Li and Matey Neykov},
journal= {arXiv preprint arXiv:2605.11238},
year = {2026}
}
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46 pages