A Theory of Super-Resolution from Short-Time Fourier Transform Measurements

TL;DR

This paper develops a super-resolution theory for recovering spike trains from short-time Fourier transform measurements, providing provable guarantees for exact recovery under certain conditions without lattice restrictions.

Contribution

It introduces a novel measure-theoretic super-resolution framework for STFT measurements, extending previous Fourier-based methods to more general spike train settings.

Findings

Recovery succeeds if spike spacing exceeds 1/fc

Method applies to both real line and torus spike trains

No restrictions on cutoff frequency for Gaussian window

Abstract

While spike trains are obviously not band-limited, the theory of super-resolution tells us that perfect recovery of unknown spike locations and weights from low-pass Fourier transform measurements is possible provided that the minimum spacing, $\Delta$, between spikes is not too small. Specifically, for a measurement cutoff frequency of $f_c$, Donoho [2] showed that exact recovery is possible if the spikes (on $\mathbb{R}$) lie on a lattice and $\Delta > 1/f_c$, but does not specify a corresponding recovery method. Cand$\text{\`e}$s and Fernandez-Granda [3, 4] provide a convex programming method for the recovery of periodic spike trains (i.e., spike trains on the torus $\mathbb{T}$), which succeeds provably if $\Delta > 2/f_c$ and $f_c \geq 128$ or if $\Delta > 1.26/f_c$ and $f_c \geq 10^3$, and does not need the spikes within the fundamental period to lie on a lattice. In this paper, we develop a theory of super-resolution from short-time Fourier transform (STFT) measurements. Specifically, we present a recovery method similar in spirit to the one in [3] for pure Fourier measurements. For a STFT Gaussian window function of width $\sigma = 1/(4f_c)$ this method succeeds provably if $\Delta > 1/f_c$, without restrictions on $f_c$. Our theory is based on a measure-theoretic formulation of the recovery problem, which leads to considerable generality in the sense of the results being grid-free and applying to spike trains on both $\mathbb{R}$ and $\mathbb{T}$. The case of spike trains on $\mathbb{R}$ comes with significant technical challenges. For recovery of spike trains on $\mathbb{T}$ we prove that the correct solution can be approximated---in weak-* topology---by solving a sequence of finite-dimensional convex programming problems.