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Main Authors: Jin, Anran, Zhang, Xingjian, Jiang, Liang, Penty, Richard V., Zeng, Pei
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2309.03789
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author Jin, Anran
Zhang, Xingjian
Jiang, Liang
Penty, Richard V.
Zeng, Pei
author_facet Jin, Anran
Zhang, Xingjian
Jiang, Liang
Penty, Richard V.
Zeng, Pei
contents Continuous-variable quantum key distribution (CV QKD) using optical coherent detectors is practically favorable due to its low implementation cost, flexibility of wavelength division multiplexing, and compatibility with standard coherent communication technologies. However, the security analysis and parameter estimation of CV QKD are complicated due to the infinite-dimensional latent Hilbert space. Also, the transmission of strong reference pulses undermines the security and complicates the experiments. In this work, we tackle these two problems by presenting a time-bin-encoding CV protocol with a simple phase-error-based security analysis valid under general coherent attacks. With the key encoded into the relative intensity between two optical modes, the need for global references is removed. Furthermore, phase randomization can be introduced to decouple the security analysis of different photon-number components. We can hence tag the photon number for each round, effectively estimate the associated privacy using a carefully designed coherent-detection method, and independently extract encryption keys from each component. Simulations manifest that the protocol using multi-photon components increases the key rate by two orders of magnitude compared to the one using only the single-photon component. Meanwhile, the protocol with four-intensity decoy analysis is sufficient to yield tight parameter estimation with a short-distance key-rate performance comparable to the best Bennett-Brassard-1984 implementation.
format Preprint
id arxiv_https___arxiv_org_abs_2309_03789
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Pilot-reference-free continuous-variable quantum key distribution with efficient decoy-state analysis
Jin, Anran
Zhang, Xingjian
Jiang, Liang
Penty, Richard V.
Zeng, Pei
Quantum Physics
Continuous-variable quantum key distribution (CV QKD) using optical coherent detectors is practically favorable due to its low implementation cost, flexibility of wavelength division multiplexing, and compatibility with standard coherent communication technologies. However, the security analysis and parameter estimation of CV QKD are complicated due to the infinite-dimensional latent Hilbert space. Also, the transmission of strong reference pulses undermines the security and complicates the experiments. In this work, we tackle these two problems by presenting a time-bin-encoding CV protocol with a simple phase-error-based security analysis valid under general coherent attacks. With the key encoded into the relative intensity between two optical modes, the need for global references is removed. Furthermore, phase randomization can be introduced to decouple the security analysis of different photon-number components. We can hence tag the photon number for each round, effectively estimate the associated privacy using a carefully designed coherent-detection method, and independently extract encryption keys from each component. Simulations manifest that the protocol using multi-photon components increases the key rate by two orders of magnitude compared to the one using only the single-photon component. Meanwhile, the protocol with four-intensity decoy analysis is sufficient to yield tight parameter estimation with a short-distance key-rate performance comparable to the best Bennett-Brassard-1984 implementation.
title Pilot-reference-free continuous-variable quantum key distribution with efficient decoy-state analysis
topic Quantum Physics
url https://arxiv.org/abs/2309.03789