Influence of noise-induced modulations on the timing stability of passively mode-locked semiconductor laser subject to optical feedback

TL;DR

This paper investigates how optical feedback influences the timing stability of passively mode-locked semiconductor lasers, revealing that feedback can cause short-term timing fluctuations and that dual feedback cavities can mitigate these effects.

Contribution

It demonstrates that single feedback cavities induce significant short-term timing fluctuations and that adding a second cavity can effectively suppress these noise-induced modulations.

Findings

Single feedback causes large short-term timing fluctuations.

Dual feedback cavities reduce noise-induced timing jitter.

Improved long-term pulse arrival time stability.

Abstract

We show that passively mode-locked lasers subject to feedback from a single external cavity can exhibit large timing fluctuations on short time scales despite having a relatively small long-term timing jitter, meaning that the commonly used von Linde and K\'{e}f\'{e}lian techniques of experimentally estimating the timing jitter can lead to large errors in the estimation of the arrival time of pulses. We also show that adding a second feedback cavity of the appropriate length can significantly suppress noise-induced modulations that are present in the single feedback system. This reduces the short time scale fluctuations of the interspike interval time and at the same time improves the variance of the fluctuation of the pulse arrival times on long time scales.