Differential Phase Encoding Scheme for Measurement-Device-Independent Quantum Key Distribution

2019 National Conference on Communications (NCC) Pub Date : 2019-02-01 DOI:10.1109/NCC.2019.8732260

S. Ranu, A. Prabhakar, Prabha Mandayam

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Abstract

This paper proposes a measurement-device-independent quantum key distribution (MDI-QKD) scheme based on differential phase encoding. The differential phase shift MDI-QKD (DPS-MDI-QKD) couples the advantages of DPS-QKD with that of MDI-QKD. The proposed scheme offers resistance against photon number splitting attack and phase fluctuations as well as immunity against detector side-channel vulnerabilities. The design proposed in this paper uses weak coherent pulses in a superposition of three orthogonal states, corresponding to one of three distinct paths in a delay-line interferometer. The classical bit information is encoded in the phase difference between pulses traversing successive paths. This 3-pulse superposition offers enhanced security compared to using a train of pulses by decreasing the learning rate of an eavesdropper and unmasking her presence with an increased error rate upon application of intercept and resend attack and beamsplitter attack. The proposed scheme employs phase locking of the sources of the two trusted parties so as to maintain the coherence between their optical signal, and uses a beamsplitter (BS) at the untrusted node (Charlie) to extract the key information from the phase encoded signals.

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测量设备无关量子密钥分配的差分相位编码方案

提出了一种基于差分相位编码的与测量设备无关的量子密钥分发(MDI-QKD)方案。差分相移MDI-QKD (DPS-MDI-QKD)结合了DPS-QKD和MDI-QKD的优点。该方案具有抗光子数分裂攻击和相位波动的能力，并具有抗探测器侧信道漏洞的能力。本文提出的设计使用三个正交状态叠加的弱相干脉冲，对应于延迟线干涉仪中的三个不同路径之一。经典的比特信息被编码在穿越连续路径的脉冲之间的相位差中。与使用脉冲序列相比，这种3脉冲叠加提供了增强的安全性，通过降低窃听者的学习率，并在应用拦截和重发攻击和分束攻击时增加误差率来揭露她的存在。该方案对可信双方的信源进行锁相以保持光信号的相干性，并在非可信节点(Charlie)上使用分束器(BS)从相位编码信号中提取关键信息。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 National Conference on Communications (NCC)

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