Multimode optical fibers (MMFs) have gained renewed interest in the past decade, emerging as a way to boost optical communication data rates in the context of an expected saturation of current single-mode fiber-based networks. They are also attractive for endoscopic applications, offering the possibility to achieve a similar information content as multicore fibers, but with a much smaller footprint, thus reducing the invasiveness of endoscopic procedures. However, these advances are hindered by the unavoidable presence of disorder that affects the propagation of light in MMFs and limits their practical applications. We introduce here a general framework to study and avoid the effect of disorder in wave-based systems and demonstrate its application for multimode fibers. We experimentally find an almost complete set of optical channels that are resilient to disorder induced by strong deformations. These deformation principal modes are obtained by only exploiting measurements for weak perturbations harnessing the generalized Wigner-Smith operator. We explain this effect by demonstrating that, even for a high level of disorder, the propagation of light in MMFs can be characterized by just a few key properties. These results are made possible thanks to a precise and fast estimation of the modal transmission matrix of the fiber which relies on a model-based optimization using deep learning frameworks.
Bibliographical noteFunding Information:
The authors kindly thank Arthur Goetschy and Esben R. Andresen for fruitful discussions. M. W. M., J. R., and S. M. P. acknowledge the French Agence Nationale pour la Recherche (Grant No. ANR-16-CE25-0008-01 MOLOTOF and Grant No. ANR-20-CE24-0016 MUPHTA) and the Labex WIFI (ANR-10-LABX-24, ANR-10-IDEX-0001-02 PSL*). Y. B. is supported by the Zuckerman STEM Leadership Program. Y. B. and S. M. P. acknowledge the France-Israel grant (PRC1672) supported by the Israel’s Ministry of Science and Technology and the France’s Centre National de la Recherche Scientifique (CNRS).
© 2021 authors. Published by the American Physical Society.