For decades, semiconductor lasers have provided a fruitful testbed for studies of nonlinear dynamics. A simple method to elicit complex dynamics of a semiconductor laser is to strongly modulate the bias current. Tuning the modulation characteristics, one can induce sub-harmonic pulse trains, which exhibit intermittent dropout events. We show experimentally and numerically that upon completion of a dropout event the P2 and P3 pulse trains may be in-phase or out of phase. To the best of our knowledge, we are the first to report on the determination of the linewidth of the sub-harmonic (P2 and P3) features from the mean time between the phase shifts in both the P2 and P2 regimes. For the P2 case, we show that the phase shift characteristics are described by the statistics of classical random telegraph signals, and we extend this paradigm to the P3 case. We numerically highlight the importance and influence of spontaneous emission noise on the dynamics within these operating regimes.

Gain switching of semiconductor lasers by strong sinusoidal current modulation can generate Period Two (P2) and Period Three (P3) sub-harmonic pulse trains. It is known that these pulse trains can be interrupted by bursting events, for the P2 pulse train predominantly consisting of short segments of relatively weak pulses at the modulation frequency (a P1-like state) before the system returns to the dominant P2 state. Similarly, for systems operating in the P3 state, intermittent switching yields combinations of P1- and P2-like pulses. To better understand these experimental observations, we perform numerical simulations using a standard model coupling the circulating optical field to the carriers of the gain medium and then compare the results with our experimental measurements on a single-mode distributed feedback laser. The simulations show that low optical power events typically precede the interruptions of the dominant sub-harmonic pulse trains. During these events, stochastic sou...