Stable Gabor phase retrieval in Gaussian shift-invariant spaces via biorthogonality

Abstract

We study the phase reconstruction of signals f belonging to complex Gaussian shift-invariant spaces V∞() from spectrogram measurements |G f(X)| where G is the Gabor transform and X ⊂eq R2. An explicit reconstruction formula will demonstrate that such signals can be recovered from measurements located on parallel lines in the time-frequency plane by means of a Riesz basis expansion. Moreover, connectedness assumptions on |f| result in stability estimates in the situation where one aims to reconstruct f on compact intervals. Driven by a recent observation that signals in Gaussian shift-invariant spaces are determined by lattice measurements [Grohs, P., Liehr, L., Injectivity of Gabor phase retrieval from lattice measurements, Appl. Comput. Harmon. Anal. 62 (2023), pp. 173-193] we prove a sampling result on the stable approximation from finitely many spectrogram samples. The resulting algorithm provides a provably stable and convergent approximation technique. In addition, it constitutes a method of approximating signals in function spaces beyond V∞(), such as Paley-Wiener spaces.