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States for phase estimation in quantum interferometry

arXiv:quant-ph/0412037 · doi:10.1088/1464-4266/7/1/004

Abstract

Ramsey interferometry allows the estimation of the phase $ϕ$ of rotation of the pseudospin vector of an ensemble of two-state quantum systems. For $ϕ$ small, the noise-to-signal ratio scales as the spin-squeezing parameter $ξ$, with $ξ<1$ possible for an entangled ensemble. However states with minimum $ξ$ are not optimal for single-shot measurements of an arbitrary phase. We define a phase-squeezing parameter, $ζ$, which is an appropriate figure-of-merit for this case. We show that (unlike the states that minimize $ξ$), the states that minimize $ζ$ can be created by evolving an unentangled state (coherent spin state) by the well-known 2-axis counter-twisting Hamiltonian. We analyse these and other states (for example the maximally entangled state, analogous to the optical "NOON" state $|ψ> = (|N,0>+|0,N>)/\sqrt{2}$) using several different properties, including $ξ$, $ζ$, the coefficients in the pseudo angular momentum basis (in the three primary directions) and the angular Wigner function $W(θ,ϕ)$. Finally we discuss the experimental options for creating phase squeezed states and doing single-shot phase estimation.

8 pages and 5 figures