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2017

Kiyoshi Tamaki; Hoi-Kwong Lo; Akihiro Mizutani; Go Kato; Charles Ci Wen Lim; Koji Azuma; Marcos Curty

Security of quantum key distribution with iterative sifting (Journal Article)

In: Quantum Science and Technology, vol. 3, no. 1, pp. 014002, 2017.

(Abstract | Links | BibTeX | タグ: )

@article{2058-9565-3-1-014002,

title = {Security of quantum key distribution with iterative sifting},

author = {Kiyoshi Tamaki and Hoi-Kwong Lo and Akihiro Mizutani and Go Kato and Charles Ci Wen Lim and Koji Azuma and Marcos Curty},

url = {http://stacks.iop.org/2058-9565/3/i=1/a=014002},

year  = {2017},

date = {2017-10-01},

journal = {Quantum Science and Technology},

volume = {3},

number = {1},

pages = {014002},

abstract = {Several quantum key distribution (QKD) protocols employ iterative sifting. After each quantum transmission round, Alice and Bob disclose part of their setting information (including their basis choices) for the detected signals. This quantum phase then ends when the basis dependent termination conditions are met, i.e., the numbers of detected signals per basis exceed certain pre-agreed threshold values. Recently, however, Pfister et al (2016 New J. Phys. 18 053001) showed that the basis dependent termination condition makes QKD insecure, especially in the finite key regime, and they suggested to disclose all the setting information after finishing the quantum phase. However, this protocol has two main drawbacks: it requires that Alice possesses a large memory, and she also needs to have some a priori knowledge about the transmission rate of the quantum channel. Here we solve these two problems by introducing a basis-independent termination condition to the iterative sifting in the finite key regime. The use of this condition, in combination with Azuma’s inequality, provides a precise estimation on the amount of privacy amplification that needs to be applied, thus leading to the security of QKD protocols, including the loss-tolerant protocol (Tamaki et al 2014 Phys. Rev. A 90 052314), with iterative sifting. Our analysis indicates that to announce the basis information after each quantum transmission round does not compromise the key generation rate of the loss-tolerant protocol. Our result allows the implementation of wider classes of classical post-processing techniques in QKD with quantified security.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}