TY - JOUR
T1 - Squeezing-enhanced communication without a phase reference
AU - Fanizza, M.
AU - Rosati, M.
AU - Skotiniotis, M.
AU - Calsamiglia, J.
AU - Giovannetti, V.
N1 - Funding Information:
M. F. and V. G. acknowledge support by MIUR via PRIN 2017 (Progetto di Ricerca di Interesse Nazionale): project QUSHIP (2017SRNBRK). M. R., M. S. and J. C. acknowledge support from the Spanish MINECO, project FIS2016-80681-P with the support of AEI/FEDER funds; the Generalitat de Catalunya, project CIRIT 2017-SGR-1127. This project has received funding from the European Union's Horizon 2020 research and innovation programme under the Marie Sk?odowska-Curie grant agreement No 845255. M. S. also acknowledges support from the Baidu-UAB collaborative project ?Learning of Quantum Hidden Markov Models?.
Funding Information:
M. F. and V. G. acknowledge support by MIUR via PRIN 2017 (Progetto di Ricerca di Interesse Nazionale): project QUSHIP (2017SRNBRK). M. R., M. S. and J. C. acknowledge support from the Spanish MINECO, project FIS2016-80681-P with the support of AEI/FEDER funds; the Generalitat de Catalunya, project CIRIT 2017-SGR-1127. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sk lodowska-Curie grant agreement No 845255. M. S. also acknowledges support from the Baidu-UAB collaborative project “Learning of Quantum Hidden Markov Models”.
Publisher Copyright:
© 2021 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All Rights Reserved.
PY - 2021
Y1 - 2021
N2 - 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 m 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 m, 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 m = 1 and a considerable advantage with respect to its direct coherent counterpart for m > 1. 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.
AB - 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 m 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 m, 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 m = 1 and a considerable advantage with respect to its direct coherent counterpart for m > 1. 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.
UR - http://www.scopus.com/inward/record.url?scp=85123012718&partnerID=8YFLogxK
U2 - 10.22331/Q-2021-12-23-608
DO - 10.22331/Q-2021-12-23-608
M3 - Article
AN - SCOPUS:85123012718
SN - 2521-327X
VL - 5
JO - Quantum
JF - Quantum
ER -