Safety-Certified CRT Sparse FFT: (k2) Lower Bound and O(N N) Worst-Case

Abstract

Computing Fourier transforms of k-sparse signals, where only k of N frequencies are non-zero, is fundamental in compressed sensing, radar, and medical imaging. While the Fast Fourier Transform (FFT) evaluates all N frequencies in O(N N) time, sufficiently sparse signals should admit sub-linear complexity in N. Existing sparse FFT algorithms using Chinese Remainder Theorem (CRT) reconstruction rely on moduli selection choices whose worst-case implications have not been fully characterized. This paper makes two contributions. First, we establish an (k2) adversarial lower bound on candidate growth for CRT-based sparse FFT when moduli are not pairwise coprime (specifically when m3 m1 m2), implying an O(k2 N) worst-case validation cost that can exceed dense FFT time. This vulnerability is practically relevant, since moduli must often divide N to avoid spectral leakage, in which case non-pairwise-coprime configurations can be unavoidable. Pairwise coprime moduli avoid the proven attack; whether analogous constructions exist for such moduli remains an open question. Second, we present a robustness framework that wraps a 3-view CRT sparse front end with lightweight certificates (bucket occupancy, candidate count) and an adaptive dense FFT fallback. For signals passing the certificates, the sparse path achieves O(N N + k N) complexity; when certificates detect collision risk, the algorithm reverts to O(N N) dense FFT, guaranteeing worst-case performance matching the classical bound.