Deterministic Sparse Fourier Transform with an ellinfty Guarantee

Abstract

In this paper we revisit the deterministic version of the Sparse Fourier Transform problem, which asks to read only a few entries of x ∈ Cn and design a recovery algorithm such that the output of the algorithm approximates x, the Discrete Fourier Transform (DFT) of x. The randomized case has been well-understood, while the main work in the deterministic case is that of Merhi et al.\@ (J Fourier Anal Appl 2018), which obtains O(k2 -1k · 5.5n) samples and a similar runtime with the 2/1 guarantee. We focus on the stronger ∞/1 guarantee and the closely related problem of incoherent matrices. We list our contributions as follows. 1. We find a deterministic collection of O(k2 n) samples for the ∞/1 recovery in time O(nk 2 n), and a deterministic collection of O(k2 2 n) samples for the ∞/1 sparse recovery in time O(k2 3n). 2. We give new deterministic constructions of incoherent matrices that are row-sampled submatrices of the DFT matrix, via a derandomization of Bernstein's inequality and bounds on exponential sums considered in analytic number theory. Our first construction matches a previous randomized construction of Nelson, Nguyen and Woodruff (RANDOM'12), where there was no constraint on the form of the incoherent matrix. Our algorithms are nearly sample-optimal, since a lower bound of (k2 + k n) is known, even for the case where the sensing matrix can be arbitrarily designed. A similar lower bound of (k2 n/ k) is known for incoherent matrices.