Beyond white- and black-box modeling tools in optical communications and optical computing: physics-informed data-driven modeling
Abstract
Efficient optimization and control of photonic computing and communication systems increasingly rely on accurate surrogate models/digital twins. While data-driven models may achieve faster inference than traditional physics-based methods, they typically suffer from poor training data efficiency and limited generalizability. To address this trade-off, physics-informed data-driven modeling has emerged as a powerful hybrid paradigm. This paper presents a comparative analysis of these three modeling paradigms across three benchmark use cases: optical amplifiers, directly modulated lasers, and interferometer meshes. By evaluating model complexity, data efficiency, generalizability, and modularity, this work provides a detailed analysis of the respective trade-offs and highlights the advantages of combining physical insight with data-driven learning.
Cite
@article{arxiv.2607.07274,
title = {Beyond white- and black-box modeling tools in optical communications and optical computing: physics-informed data-driven modeling},
author = {Isidora Teofilovic and Sergio Hernandez Fernandez and Metodi P. Yankov and Christophe Peucheret and Darko Zibar and Francesco Da Ros},
journal= {arXiv preprint arXiv:2607.07274},
year = {2026}
}
Comments
Submitted to Journal of Lightwave Technology