English

Versatile Gaussian probes for squeezing estimation

Quantum Physics 2017-05-18 v2

Abstract

We consider an instance of black-box quantum metrology in the Gaussian framework, where we aim to estimate the amount of squeezing applied on an input probe, without previous knowledge on the phase of the applied squeezing. By taking the quantum Fisher information (QFI) as the figure of merit, we evaluate its average and variance with respect to this phase in order to identify probe states that yield good precision for many different squeezing directions. We first consider the case of single-mode Gaussian probes with the same energy, and find that pure squeezed states maximize the average quantum Fisher information (AvQFI) at the cost of a performance that oscillates strongly as the squeezing direction is changed. Although the variance can be brought to zero by correlating the probing system with a reference mode, the maximum AvQFI cannot be increased in the same way. A different scenario opens if one takes into account the effects of photon losses: coherent states represent the optimal single-mode choice when losses exceed a certain threshold and, moreover, correlated probes can now yield larger AvQFI values than all single-mode states, on top of having zero variance.

Keywords

Cite

@article{arxiv.1703.05554,
  title  = {Versatile Gaussian probes for squeezing estimation},
  author = {Luca Rigovacca and Alessandro Farace and Leonardo A. M. Souza and Antonella De Pasquale and Vittorio Giovannetti and Gerardo Adesso},
  journal= {arXiv preprint arXiv:1703.05554},
  year   = {2017}
}

Comments

11 + 7 pages, 6 + 3 figures; close to published version

R2 v1 2026-06-22T18:47:31.222Z