Flexible Quantum Network Coding by Using Quantum Multiplexing

IF 4.4 Q1 OPTICS

Advanced quantum technologies Pub Date : 2024-06-04 DOI:10.1002/qute.202400016

Yu-Guang Yang, Bing-Xin Liu, Guang-Bao Xu, Dong-Huan Jiang, Yi-Hua Zhou, Wei-Min Shi, Tao Shang

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Abstract

Quantum network coding (QNC) aims at alleviating quantum communication congestion in quantum networks. Although several QNC protocols have been presented, they cannot meet the practical requirements that part of source nodes intend to transmit their quantum states with same or different qubit numbers via the bottleneck network simultaneously. Here, the study presents a flexible QNC protocol by using quantum multiplexing. First, the entangled pairs are generated between adjacent nodes in a heralded way by using quantum multiplexing. Then the quantum memories of the source nodes and the ones of the corresponding target nodes are entangled when the intermediate nodes execute multiple rounds of entanglement swapping operations on their quantum memories. Finally, the quantum states are transmitted from the source nodes to their corresponding target nodes by means of quantum teleportation. Compared with the existing protocols, the protocol allows an arbitrary part of the source nodes to transmit their quantum states with same or different qubit numbers via the bottleneck network simultaneously, thereby exhibiting its flexibility.

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利用量子复用技术实现灵活的量子网络编码

量子网络编码（QNC）旨在缓解量子网络中的量子通信拥塞问题。虽然已经提出了几种 QNC 协议，但它们无法满足部分源节点打算通过瓶颈网络同时传输其具有相同或不同量子比特数的量子态的实际要求。本研究利用量子复用技术提出了一种灵活的 QNC 协议。首先，利用量子复用技术在相邻节点之间以预示方式产生纠缠对。然后，当中间节点对其量子存储器执行多轮纠缠交换操作时，源节点的量子存储器与相应目标节点的量子存储器发生纠缠。最后，量子态通过量子远传从源节点传输到相应的目标节点。与现有协议相比，该协议允许任意部分源节点通过瓶颈网络同时传输相同或不同量子比特数的量子态，从而体现了其灵活性。

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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来源期刊

Advanced quantum technologies

CiteScore

7.90

自引率

0.00%

发文量