Sensitivity of Quantum-Enhanced Interferometers

We review various schemes of quantum-enhanced optical interferometers, both linear (SU(2)) and non-linear (SU(1,1)) ones, as well as hybrid SU(2)/SU(1,1) options, using the unified modular approach based on the Quantum Cramer-Rao bound (QCRB), and taking into account the practical limitations pertinent to all real-world highly-sensitive interferometers. We focus on three important cases defined by the interferometer symmetry: (i) the asymmetric single-arm interferometer; (ii) the symmetric two-arm interferometer with the antisymmetric phase shifts in the arms; and (iii) the symmetric two-arm interferometer with the symmetric phase shifts in the arms. We show that while the optimal regimes for these cases differ significantly, their QCRBs asymptotically correspond to the same squeezing-enhanced shot noise limit (2), which first appeared in the pioneering work by C. Caves in 1981.We show also that in all considered cases the QCRB can be asymptotically saturated by the standard (direct or homodyne) detection schemes.

Automated summary

This paper reviews various schemes of quantum-enhanced optical interferometers, including linear (SU(2)) and non-linear (SU(1,1)) schemes, as well as hybrid SU(2)/SU(1,1) options. It takes into account the practical limitations relevant to real-world interferometers. Three important cases defined by the interferometer symmetry are discussed. It is shown that the Quantum Cramer-Rao bound (QCRB) can be asymptotically saturated by standard detection schemes in all considered cases.