Squeezing metrology: a unified framework
Abstract
Quantum metrology theory has up to now focused on the resolution gains obtainable thanks to the entanglement among N probes. Typically, a quadratic gain in resolution is achievable, going from the 1/sqrt(N) of the central limit theorem to the 1/N of the Heisenberg bound. Here we focus instead on quantum squeezing and provide a unified framework for metrology with squeezing, showing that, similarly, one can generally attain a quadratic gain when comparing the resolution achievable by a squeezed probe to the best N-probe classical strategy achievable with the same energy. Namely, here we give a quantification of the Heisenberg squeezing bound for arbitrary estimation strategies that employ squeezing. Our theory recovers known results (e.g.~in quantum optics and spin squeezing), but it uses the general theory of squeezing and holds for arbitrary quantum systems.
Cite
@article{arxiv.1901.07482,
title = {Squeezing metrology: a unified framework},
author = {Lorenzo Maccone and Alberto Riccardi},
journal= {arXiv preprint arXiv:1901.07482},
year = {2020}
}
Comments
Version accepted for publication on "Quantum" (same as previous version v2, but with different license, and doi added for the references)