Experimental characterization of transitions between locking regimes in a laser system with weak periodic forcing

TL;DR

This study investigates how a semiconductor laser with optical feedback can be controlled using small periodic electric signals, analyzing the conditions for successful entrainment and the transitions between locking and unlocking regimes.

Contribution

It provides a detailed experimental analysis of locking regimes in a laser system under weak periodic forcing, including characterization of transition dynamics.

Findings

Successful entrainment occurs with specific parameter settings.

ROC curves effectively identify locking regimes.

Transitions between locking and unlocking are characterized.

Abstract

The entrainment (or locking) phenomenon, by which an oscillator adapts its natural rhythm to an external periodic signal, is well-known in physics, chemistry, biology, etc.; however, controlling an stochastic nonlinear system with a small-amplitude signal is a challenging task, and systems that allow for low-cost experiments are scarce. Here we use a semiconductor laser with optical feedback, operated in the regime where it randomly emits abrupt spikes. We quantify the quality of the entrainment of the optical spikes to periodic, small-amplitude electric perturbations of the laser pump current. We use the success rate (SR) that counts the number of spikes that occur within a short time window after each perturbation, and the false positive rate (FPR) that counts the additional spikes that occur outside the window. The ROC curves (SR vs. FPR plots) uncover parameter regions where the electric perturbations fully control the laser spikes, entraining them, such that the laser emits, shortly after each perturbation, one and only one spike (i.e., SR=1 and FPR=0). We also characterize the locking-unlocking transitions when the perturbation amplitude and frequency vary.