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A tunable quantum random number generator based on a fiber-optical Sagnac interferometer

Joakim Argillander, Alvaro Alarcón, Guilherme B. Xavier

2022Journal of Optics12 citationsDOIOpen Access PDF

Abstract

Abstract Quantum random number generators (QRNGs) are based on naturally random measurement results performed on individual quantum systems. Here, we demonstrate a branching-path photonic QRNG implemented using a Sagnac interferometer with a tunable splitting ratio. The fine-tuning of the splitting ratio allows us to maximize the entropy of the generated sequence of random numbers and effectively compensate for tolerances in the components. By producing single-photons from attenuated telecom laser pulses, and employing commercially-available components we are able to generate a sequence of more than 2 gigabytes of random numbers with an average entropy of 7.99 bits/byte directly from the raw measured data. Furthermore, our sequence passes randomness tests from both the NIST and Dieharder statistical test suites, thus certifying its randomness. Our scheme shows an alternative design of QRNGs based on the dynamic adjustment of the uniformity of the produced random sequence, which is relevant for the construction of modern generators that rely on independent real-time testing of its performance.

Topics & Concepts

RandomnessRandom number generationNISTInterferometryComputer scienceOpticsPhysicsRandomness testsPhotonicsAlgorithmMathematicsStatisticsNatural language processingChaos-based Image/Signal EncryptionQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
A tunable quantum random number generator based on a fiber-optical Sagnac interferometer | Litcius