Phaseless sampling on square-root lattices

Abstract

Due to its appearance in a remarkably wide field of applications, such as audio processing and coherent diffraction imaging, the short-time Fourier transform (STFT) phase retrieval problem has seen a great deal of attention in recent years. A central problem in STFT phase retrieval concerns the question for which window functions g ∈ L2(Rd) and which sampling sets ⊂eq R2d is every f ∈ L2(Rd) uniquely determined (up to a global phase factor) by phaseless samples of the form |Vgf()| = \ |Vgf(λ)| : λ ∈ \, where Vgf denotes the short-time Fourier transform (STFT) of f with respect to g. The investigation of this question constitutes a key step towards making the problem computationally tractable. However, it deviates from ordinary sampling tasks in a fundamental and subtle manner: recent results demonstrate that uniqueness is unachievable if is a lattice, i.e = AZ2d, A ∈ GL(2d,R). Driven by this discretization barrier, the present article centers around the initiation of a novel sampling scheme which allows for unique recovery of any square-integrable function via phaseless STFT-sampling. Specifically, we show that square-root lattices, i.e., sets of the form = A ( Z )2d, \ Z = \ n : n ∈ N0 \, guarantee uniqueness of the STFT phase retrieval problem. The result holds for a large class of window functions, including Gaussians.