Impact of coherent mode coupling on noise performance in elliptical aperture VCSELs for datacom

TL;DR

This paper investigates how mode coupling affects noise in elliptical aperture VCSELs, providing a model for RIN peaks, and offers design insights for improved high-speed data communication devices.

Contribution

It introduces a novel analytical model explaining RIN peaks due to mode interactions in multimode VCSELs with elliptical apertures, and explores design parameters influencing noise performance.

Findings

RIN peaks are caused by mode interactions and spatial hole burning.

Ellipticity influences modal detuning and noise characteristics.

Design guidelines for low RIN VCSELs are proposed.

Abstract

We study the dynamical behavior of medium-size multimode VCSELs with an elliptical oxide aperture, selected for the best trade-off between high output power and modulation speed for datacom applications, with a focus on their relative intensity noise (RIN) performance. Our experimental results, collected for various VCSELs, outline the presence of several peaks in the RIN spectra within the bandwidth of the transmission system, which can limit the eye opening under direct current modulation. Here, we present a rigorous model to explain for the first time the origin of these peaks. In particular, the frequencies of the spectral RIN peaks are analytically described as the result of the non-trivial interaction among transverse modes by addressing the laser dynamics and the related noise features through a time-domain mode expansion approach, accounting for coherent effects in multimode competition, spatial hole burning, and carrier diffusion. The laser modulation performance is addressed through dynamical simulations with PAM2 and PAM4 modulations, which clearly demonstrate the potential for high-bitrate optical interconnects. Finally, we address the effect of the oxide aperture aspect ratio via electromagnetic simulations, demonstrating how the ellipticity affects the modal frequency detuning and the RIN, thus providing design guidelines for VCSELs with low RIN performance and outlining a clear roadmap for a substantially improved bandwidth-power trade-off in these devices.