Super-resolution by means of Beurling minimal extrapolation

Abstract

Let M(Td) be the space of complex bounded Radon measures defined on the d-dimensional torus group (R/Z)d=Td, equipped with the total variation norm \|·\|; and let μ denote the Fourier transform of μ∈ M(Td). We address the super-resolution problem: For given spectral (Fourier transform) data defined on a finite set ⊂Zd, determine if there is a unique μ∈ M(Td) of minimal norm for which μ equals this data on . Without additional assumptions on μ and , our main theorem shows that the solutions to the super-resolution problem, which we call minimal extrapolations, depend crucially on the set ⊂, defined in terms of μ and . For example, when =0, the minimal extrapolations are singular measures supported in the zero set of an analytic function, and when ≥ 2, the minimal extrapolations are singular measures supported in the intersection of 2 hyperplanes. By theory and example, we show that the case =1 is different from other cases and is deeply connected with the existence of positive minimal extrapolations. This theorem has implications to the possibility and impossibility of uniquely recovering μ from . We illustrate how to apply our theory to both directions, by computing pertinent analytical examples. These examples are of interest in both super-resolution and deterministic compressed sensing. Our concept of an admissibility range fundamentally connects Beurling's theory of minimal extrapolation with Candes and Fernandez-Granda's work on super-resolution. This connection is exploited to address situations where current algorithms fail to compute a numerical solution to the super-resolution problem.