实现可扩展的量子密钥分发:基于机器学习的级联协议方法

Hasan Abbas Al-Mohammed, Saif Al-Kuwari, Hashir Kuniyil, Ahmed Farouk
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引用次数: 0

摘要

量子密钥分发(QKD)是实现安全通信的关键技术,它利用量子力学的力量确保数据得到可靠保护。然而,如何扩展 QKD 以满足高速实际应用的需求仍然是一项重大挑战。传统的密钥评级确定方法依赖于复杂的数学模型,在效率和可扩展性方面往往力不从心。在本文中,我们提出了一种将机器学习(ML)技术与级联纠错协议相结合的方法,以提高 QKD 系统的可扩展性和效率。我们基于 ML 的方法利用自动编码器框架来预测量子比特错误率(QBER)和最终密钥长度,准确率超过 99%。这种方法大大缩短了纠错时间,即使输入数据量很大,如数据传输速率高达 156Mbps,也能保持持续较低的计算时间。相比之下,传统方法的计算时间会随着输入大小的增加而呈指数级增长,这凸显了我们基于 ML 的解决方案优越的可扩展性。通过全面的仿真,我们证明了我们的方法不仅能加快纠错过程,还能优化资源利用率,使其在现实世界的部署中更具成本效益和实用性。Cascade 协议的集成可根据实时 QBER 观察结果动态调整纠错,从而进一步增强系统安全性,为防止潜在窃听提供了强有力的保护。我们的研究为可扩展、高吞吐量 QKD 系统确立了新的基准,证明机器学习可以极大地推动量子密码学领域的发展。这项工作将继续推动真正可扩展量子通信的发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards Scalable Quantum Key Distribution: A Machine Learning-Based Cascade Protocol Approach
Quantum Key Distribution (QKD) is a pivotal technology in the quest for secure communication, harnessing the power of quantum mechanics to ensure robust data protection. However, scaling QKD to meet the demands of high-speed, real-world applications remains a significant challenge. Traditional key rate determination methods, dependent on complex mathematical models, often fall short in efficiency and scalability. In this paper, we propose an approach that involves integrating machine learning (ML) techniques with the Cascade error correction protocol to enhance the scalability and efficiency of QKD systems. Our ML-based approach utilizes an autoencoder framework to predict the Quantum Bit Error Rate (QBER) and final key length with over 99\% accuracy. This method significantly reduces error correction time, maintaining a consistently low computation time even with large input sizes, such as data rates up to 156 Mbps. In contrast, traditional methods exhibit exponentially increasing computation times as input sizes grow, highlighting the superior scalability of our ML-based solution. Through comprehensive simulations, we demonstrate that our method not only accelerates the error correction process but also optimizes resource utilization, making it more cost-effective and practical for real-world deployment. The Cascade protocol's integration further enhances system security by dynamically adjusting error correction based on real-time QBER observations, providing robust protection against potential eavesdropping. Our research establishes a new benchmark for scalable, high-throughput QKD systems, proving that machine learning can significantly advance the field of quantum cryptography. This work continues the evolution towards truly scalable quantum communication.
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