Abstract
The statistics of the optical phase of the light emitted by a semiconductor laser diode when subject to periodic modulation of the applied bias current are theoretically analyzed. Numerical simulations of the stochastic rate equations describing the previous system are performed to describe the temporal dependence of the phase statistics. These simulations are performed by considering two cases corresponding to random and deterministic initial conditions. In contrast to the Gaussian character of the phase that has been assumed in previous works, we show that the phase is not distributed as a Gaussian during the initial stages of evolution. We characterize the time it takes the phase to become Gaussian by calculating the dynamical evolution of the kurtosis coefficient of the phase. We show that, under the typical gain-switching with square-wave modulation used for quantum random number generation, quantity is in the ns time scale; that corresponds to the time it takes the system to lose the memory of the distribution of the initial conditions. We compare the standard deviation of the phase obtained with random and deterministic initial conditions to show that their differences become more important as the modulation speed is increased.
Highlights
Photonics 2021, 8, 388. https://Experimental and theoretical understanding of the fluctuations of laser light began shortly after the invention of the laser [1,2,3,4,5]
Fixed initial conditions have been considered because they have been used in previous studies of quantum random number generation (QRNG)
They are not the best choice for simulation of these systems because the spontaneous emission noise, that is always present in the system, causes fluctuations in the variables of the system at all times
Summary
Experimental and theoretical understanding of the fluctuations of laser light began shortly after the invention of the laser [1,2,3,4,5]. Statistics of optical phase has been described as Gaussian in numerical simulations [27,33,34] since spontaneous emission noise has Gaussian distribution In these generators the bias current is periodically modulated in such a way that the evolution is mainly in a transient regime, specially when operating at fast bit rates. In this paper we report a theoretical study of the phase diffusion in gain-switched semiconductor lasers This is done by performing numerical simulations of the stochastic rate equations for the complex electrical field and carrier number.
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