Optical estimation of unitary Gaussian processes without phase reference using Fock states

Changhun Oh,Hyunseok Jeong,Radim Filip,Petr Marek,Kimin Park

doi:10.1088/1367-2630/abd0b8

Abstract

Since a general Gaussian process is phase-sensitive, a stable phase reference is required to take advantage of this feature. When the reference is missing, either due to the volatile nature of the measured sample or the measurement’s technical limitations, the resulting process appears as random in phase. Under this condition, we consider two single-mode Gaussian processes, displacement and squeezing. We show that these two can be efficiently estimated using photon number states and photon number resolving detectors. For separate estimation of displacement and squeezing, the practical estimation errors for hundreds of probes’ ensembles can saturate the Cramér–Rao bound even for arbitrary small values of the estimated parameters and under realistic losses. The estimation of displacement with Fock states always outperforms estimation using Gaussian states with equivalent energy and optimal measurement. For estimation of squeezing, Fock states outperform Gaussian methods, but only when their energy is large enough. Finally, we show that Fock states can also be used to estimate the displacement and the squeezing simultaneously.

Highlights

Quantum metrology with light estimates unknown parameters of quantum processes and reveals the limits of the existing measurements from treating the measuring probes as physical systems in specific optimized quantum states [1,2,3,4]
A specific case of optical interferometry relies on homodyne detection [11], where the reference arm of the interferometer is represented by a classical local oscillator beam [7,8,9], which leaves only the probe to be prepared in a quantum state
We have investigated the possibility of using Fock states and photon number resolving detectors (PNRD) for parameter estimation of single mode Gaussian unitaries in the absence of stable phase reference