Number-phase uncertainty relations in terms of generalized entropies

TL;DR

This paper develops generalized entropy-based uncertainty relations for quantum number and phase measurements, extending existing formulations to include finite phase resolutions and infinite-dimensional limits, with applications to multiphoton states.

Contribution

It introduces a unified entropy framework for number-phase uncertainty relations, incorporating finite phase resolutions and infinite-dimensional limits, and applies it to multiphoton coherent states.

Findings

Derived uncertainty relations using unified entropies for finite and infinite dimensions.

Established inequalities between probability distribution functionals in quantum measurements.

Provided entropic bounds involving probability density integrals.

Abstract

Number-phase uncertainty relations are formulated in terms of unified entropies which form a family of two-parametric extensions of the Shannon entropy. For two generalized measurements, unified-entropy uncertainty relations are given in both the state-dependent and state-independent forms. A few examples are discussed as well. Using the Pegg--Barnett formalism and the Riesz theorem, we obtain a nontrivial inequality between norm-like functionals of generated probability distributions in finite dimensions. The principal point is that we take the infinite-dimensional limit right for this inequality. Hence number-phase uncertainty relations with finite phase resolutions are expressed in terms of the unified entropies. Especially important case of multiphoton coherent states is separately considered. We also give some entropic bounds in which the corresponding integrals of probability density functions are involved.