End-to-end learning has become a popular method for joint transmitter and receiver optimization in optical communication systems. Such approach may require a differentiable channel model, thus hindering the optimization of links based on directly modulated lasers (DMLs). This is due to the DML behavior in the large-signal regime, for which no analytical solution is available. In this paper, this problem is addressed by developing and comparing differentiable machine learning-based surrogate models. The models are quantitatively assessed in terms of root mean square error and training/testing time. Once the models are trained, the surrogates are then tested in a numerical equalization setup, resembling a practical end-to-end scenario. Based on the numerical investigation conducted, the convolutional attention transformer is shown to outperform the other models considered.
@article{arxiv.2309.15747,
title = {Differentiable Machine Learning-Based Modeling for Directly-Modulated Lasers},
author = {Sergio Hernandez and Ognjen Jovanovic and Christophe Peucheret and Francesco Da Ros and Darko Zibar},
journal= {arXiv preprint arXiv:2309.15747},
year = {2024}
}
Comments
final version to Photonics Technology Letters (02/01/2024)