Recognition: unknown
On a dense set of functions determined by sampled Gabor magnitude
read the original abstract
We study the problem of recovering a function from the magnitude of its Gabor transform sampled on a discrete set. While it is known that uniqueness fails for general square integrable functions, we show that phase retrieval is possible for a dense class of signals: specifically, those whose Bargmann transforms are entire functions of exponential type. Our main result characterises when such functions can be uniquely recovered (up to a global phase) from magnitude only data sampled on uniformly discrete sets of sufficient lower Beurling density. In particular, we prove that every entire function of exponential type is uniquely determined (up to a global phase) among all second order entire functions by its modulus on a sufficiently dense shifted lattice with suitable structure.
This paper has not been read by Pith yet.
Forward citations
Cited by 1 Pith paper
-
Stable phase retrieval from short-time linear canonical transforms of signals in Gaussian shift-invariant spaces
Signals in the complex Gaussian shift-invariant space V_β^∞(ϕ) are uniquely determined up to global unimodular constant by phaseless STLCT measurements on β/2 ℤ × ℝ, with explicit reconstruction, anchor-point stabilit...
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.