An Unbiased Quantum Random Number Generator Based on Boson Sampling

It is proven that Boson sampling is a much promising model of optical quantum computation, which is applied to designing quantum computer successfully, such as "Jiuzhang". However, the meaningful randomness of Boson sampling results has not been utilized or exploited. In this research, Boson sampling is applied to design a quantum random number generator (QRNG) by fully exploiting the randomness of Boson sampling results, and its prototype system is constructed with the programmable silicon photonic processor, which can generate unbiased random sequences and overcome the shortcomings of the existing discrete QRNGs such as source-restricted, high demand for the photon number resolution capability of detector and slow self-detection generator speed. Boson sampling is implemented as a random entropy source, and random bit strings with satisfactory randomness and uniformity can be obtained after post-processing the sampling results. It is the first approach for applying the randomness of Boson sampling results to develop a practical prototype system for actual tasks, and the experiment results demonstrate that the designed Boson sampling-based QRNG prototype system passes 15 tests of the NIST SP 800-22 statistical test component, which proves that Boson sampling has great potential for practical applications with desirable performance besides quantum advantage. This work proposes an unbiased quantum random number generator (QRNG) based on Boson sampling. A Boson sampling-based QRNG prototype system is constructed on the programable silicon photonic processor chip, where the experiment results pass 15 tests of the NIST SP 800-22 statistical test component, which proves that Boson sampling has great potential for practical applications with desirable performance besides quantum advantage.image