Operation of an Electrical-Only-Contact Photonic Integrated Chip for Quantum Random Number Generation Using Laser Gain-Switching

3区物理与天体物理 Q1 Materials Science Progress in Optics Pub Date : 2023-10-27 DOI:10.3390/opt4040040

Seán Ó Dúill, Leidy Rodriguez, David Alvarez-Outerelo, Francisco J. Diaz-Otero, Ankit Sharma, Frank Smyth, Liam P. Barry

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Abstract

We present the results of the detected voltage distribution of a quantum random number generator (QRNG) based on a photonic integrated circuit comprising a semiconductor laser, delay interferometer and photodetector. We find that the integrated QRNG system behaves as expected for a QRNG from discrete gain-switched laser sources, especially exhibiting all of the peculiarities of the random voltage distribution and behaving as previously demonstrated for a discrete optical component setup. The biggest advantage of having all of the components integrated into a single chip is that only electrical connections are needed to operate the system, without the need for tricky and expensive optical alignment to external circuitry. We supply results showing that a random bit stream created from the random numbers passes the NIST statistical test suite tests, thus demonstrating the feasibility to generate random numbers via quantum means at gigabit/s rates from a single photonic integrated circuit. All of our results are backed by numerical simulations.

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使用激光增益开关产生量子随机数的纯电接触光子集成芯片的操作

本文介绍了基于半导体激光器、延迟干涉仪和光电探测器组成的光子集成电路的量子随机数发生器(QRNG)的电压分布检测结果。我们发现，集成的QRNG系统的行为与来自离散增益切换激光源的QRNG的预期一致，特别是表现出随机电压分布的所有特性，并表现出先前在离散光学元件设置中所展示的行为。将所有组件集成到一个芯片上的最大优点是只需要电气连接来操作系统，而不需要对外部电路进行棘手且昂贵的光学校准。我们提供的结果表明，由随机数产生的随机比特流通过了NIST统计测试套件测试，从而证明了通过量子手段从单个光子集成电路以千兆位/秒的速率产生随机数的可行性。我们所有的结果都得到了数值模拟的支持。

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来源期刊

Progress in Optics 物理-光学

CiteScore

4.50

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0.00%

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