Gaussian quantum metrology for mode-encoded parameters

TL;DR

This paper derives a general formula for quantum Fisher information in multimode Gaussian fields, enabling improved mode-encoded parameter estimation in quantum optics applications like beam displacement and pulse separation.

Contribution

It provides the first analytical expression for quantum Fisher information in multimode Gaussian states for mode-encoded parameters.

Findings

Adding squeezing in specific modes enhances estimation sensitivity.

The formula applies to arbitrary multimode Gaussian fields.

Demonstrated improved precision in beam displacement and pulse separation estimation.

Abstract

Quantum optical metrology aims to identify ultimate sensitivity bounds for the estimation of parameters encoded into quantum states of the electromagnetic field. In many practical applications, including imaging, microscopy, and remote sensing, the parameter of interest is not only encoded in the quantum state of the field, but also in its spatio-temporal distribution, i.e. in its mode structure. In this mode-encoded parameter estimation setting, we derive an analytical expression for the quantum Fisher information valid for arbitrary multimode Gaussian fields. To illustrate the power of our approach, we apply our results to the estimation of the transverse displacement of a beam and to the temporal separation between two pulses. For these examples, we show how the estimation sensitivity can be enhanced by adding squeezing into specific modes.