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Parametric study of the phase diffusion process in a gain-switched semiconductor laser for randomness assessment in quantum random number generator

Brigitta Septriani, Oliver de Vries, Fabian Steinlechner, Markus Gräfe

2020AIP Advances18 citationsDOIOpen Access PDF

Abstract

The quantum phase noise in a pulsed semiconductor laser is studied thoroughly in the context of its utilization as a quantum entropy source in a quantum random number generator (QRNG) device. We performed a numerical analysis of the phase diffusion process for a semiconductor laser in the continuous-wave operation mode and gain-switched (GS) mode. The result demonstrates the amplification of randomness in the GS mode, which is gauged physically by the variance VarΔϕ. The variance value, which is mathematically related to the temporal distance between the laser pulses used in the experimental setup, also determines the stability of the setup. Furthermore, we show how the QRNG probability distribution is influenced by several experimental factors such as the quality of the interference process and the noise in the detection system.

Topics & Concepts

RandomnessSemiconductor laser theoryParametric statisticsRandom number generationPhase noiseLaserStatistical physicsPhysicsOpticsComputational physicsElectronic engineeringMathematicsStatisticsEngineeringQuantum Mechanics and ApplicationsQuantum Information and CryptographyQuantum optics and atomic interactions
Parametric study of the phase diffusion process in a gain-switched semiconductor laser for randomness assessment in quantum random number generator | Litcius