Quantum random number generation exploits inherent randomness of quantum mechanical processes and measurements. Real-time generation rate of quantum random numbers is usually limited by electronic bandwidth and data processing rates. Here we use a multiplexing scheme to create a fast real-time quantum random number generator based on continuous variable vacuum fluctuations. Multiple sideband frequency modes of a quantum vacuum state within a homodyne detection bandwidth are concurrently extracted as the randomness source. Parallel post-processing of raw data from three sub-entropy sources is realized in one field-programmable gate array (FPGA) based on Toeplitz-hashing extractors. A cumulative generation rate of 8.25 Gbps in real-time is achieved. The system relies on optoelectronic components and circuits that could be integrated in a compact, economical package.
@article{arxiv.1904.12990,
title = {Parallel real-time quantum random number generator},
author = {Xiaomin Guo and Chen Cheng and Mingchuan Wu and Qingzhong Gao and Pu Li and Yanqiang Guo},
journal= {arXiv preprint arXiv:1904.12990},
year = {2020}
}