Squeezing-enhanced communication without a phase reference
Abstract
We study the problem of transmitting classical information using quantum Gaussian states on a family of phase-noise channels with a finite decoherence time, such that the phase-reference is lost after consecutive uses of the transmission line. This problem is relevant for long-distance communication in free space and optical fiber, where phase noise is typically considered as a limiting factor. The Holevo capacity of these channels is always attained with photon-number encodings, challenging with current technology. Hence for coherent-state encodings the optimal rate depends only on the total-energy distribution and we provide upper and lower bounds for all , the latter attainable at low energies with on/off modulation and photodetection. We generalize this lower bound to squeezed-coherent encodings, exhibiting for the first time to our knowledge an unconditional advantage with respect to any coherent encoding for and a considerable advantage with respect to its direct coherent counterpart for . This advantage is robust with respect to moderate attenuation, and persists in a regime where Fock encodings with up to two-photon states are also suboptimal. Finally, we show that the use of part of the energy to establish a reference frame is sub-optimal even at large energies. Our results represent a key departure from the case of phase-covariant Gaussian channels and constitute a proof-of-principle of the advantages of using non-classical, squeezed light in a motivated communication setting.
Cite
@article{arxiv.2006.06522,
title = {Squeezing-enhanced communication without a phase reference},
author = {Marco Fanizza and Matteo Rosati and Michalis Skotiniotis and John Calsamiglia and Vittorio Giovannetti},
journal= {arXiv preprint arXiv:2006.06522},
year = {2021}
}
Comments
v4: final version accepted for publication in Quantum. A very preliminary version was presented at 10.1109/ISIT44484.2020.9174467