Fully photonics-based random number generators

2017 IEEE/CIC International Conference on Communications in China (ICCC) Pub Date : 2017-10-01 DOI:10.1109/ICCChina.2017.8330364

Pu Li

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Abstract

Real-time and ultrafast random number generators (RNGs) based on physical randomness sources are of paramount importance for cryptography and secure communications, where they are used as cryptographic keys to protect the privacy of data transmission. Since 2008, laser chaos has been viewed as the most promising source of randomness for fast RNGs because of its high bandwidth and large fluctuation. However, most of physical RNGs based on laser chaos did their random number extraction in the electrical domain, and thus their real-time rates suffered from the limitation of electronic bottleneck. Combing the chaotic laser with photonic signal processing techniques, we proposed and developed an innovative real-time methodology for ultrafast physical RNGs. Different with previous reports on RNGs, our fully photonic method do the random number extraction in the optical domain, so it efficiently circumvents the electronic bottleneck and has the potential to reach a real-time rate at the level of Tb/s. In this paper, we review our representative works on this topic of fully photonics based physical RNGs and some possible development orientations in the future are discussed.

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完全基于光子的随机数生成器

基于物理随机源的实时和超快随机数生成器(rng)在密码学和安全通信中具有至关重要的意义，它们被用作保护数据传输隐私的加密密钥。自2008年以来，激光混沌因其高带宽和大波动而被视为快速rng最有希望的随机性来源。然而，基于激光混沌的物理rng大多是在电域进行随机数提取，实时性受到电子瓶颈的限制。将混沌激光与光子信号处理技术相结合，提出并开发了一种创新的超快物理rng实时方法。与以往报道的rng不同，我们的全光子方法在光域中进行随机数提取，因此有效地绕过了电子瓶颈，有可能达到Tb/s水平的实时速率。本文综述了国内外在全光子学物理rng领域的代表性研究成果，并对未来可能的发展方向进行了展望。

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

2017 IEEE/CIC International Conference on Communications in China (ICCC)

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