Romtham Sripotchanart , Weisheng Si , Rodrigo N. Calheiros , Qing Cao , Tie Qiu
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引用次数: 0
摘要
得益于量子密钥分发和分布式量子计算等应用,量子网络的部署正获得巨大发展。量子网络的一个重要组成部分是中继器,它对于降低长距离链路中量子比特传输的错误率至关重要。然而,中继器是昂贵的设备,因此,在满足性能要求的同时尽量减少量子网络中的中继器数量成为一个重要问题。现有的解决方案通常通过制定整数线性规划(ILP)来优化解决这一问题。然而,其 ILP 中的变量数为 O(n2),其中 n 是网络中的节点数。当网络规模较大时,这就会产生不可行的运行时间。为了克服这一缺点,本文建议分两步解决中继器放置问题,每一步都使用规模小得多的线性程序,变量为 O(n) 个。虽然这一方案并非最优,但它大大降低了时间复杂度,因此适用于大规模网络。此外,由于它在网络中部署的中继器数量略多,因此它构建的网络比现有解决方案具有更高的节点连通性。我们在合成网络拓扑和真实世界网络拓扑上进行的大量实验验证了我们的说法。
A two-step linear programming approach for repeater placement in large-scale quantum networks
Thanks to the applications such as Quantum Key Distribution and Distributed Quantum Computing, the deployment of quantum networks is gaining great momentum. A major component in quantum networks is repeaters, which are essential for reducing the error rate of qubit transmission for long-distance links. However, repeaters are expensive devices, so minimizing the number of repeaters placed in a quantum network while satisfying performance requirements becomes an important problem. Existing solutions typically solve this problem optimally by formulating an Integer Linear Program (ILP). However, the number of variables in their ILPs is , where is the number of nodes in a network. This incurs infeasible running time when the network scale is large. To overcome this drawback, this paper proposes to solve the repeater placement problem by two steps, with each step using a linear program of a much smaller scale with variables. Although this solution is not optimal, it dramatically reduces the time complexity, making it practical for large-scale networks. Moreover, it constructs networks that have higher node connectivity than those by existing solutions, since it deploys slightly more number of repeaters into networks. Our extensive experiments on both synthetic and real-world network topologies verified our claims.
期刊介绍:
Computer Networks is an international, archival journal providing a publication vehicle for complete coverage of all topics of interest to those involved in the computer communications networking area. The audience includes researchers, managers and operators of networks as well as designers and implementors. The Editorial Board will consider any material for publication that is of interest to those groups.
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