Learning and Avoiding Disorder in Multimode Fibers

arXiv: Optics Pub Date : 2020-10-28 DOI:10.1103/PhysRevX.11.021060

Maxime W. Matthès, Y. Bromberg, J. de Rosny, S. Popoff

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引用次数: 37

Abstract

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. We experimentally find an almost complete set of optical channels that are resilient to disorder induced by strong deformations. These deformation principle modes are obtained by only exploiting measurements for weak perturbations. 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.

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多模光纤的学习和避免紊乱

在过去的十年中，多模光纤(mmf)重新引起了人们的兴趣，在当前单模光纤网络预期饱和的背景下，多模光纤作为一种提高光通信数据速率的方法而出现。它们在内窥镜应用中也很有吸引力，提供了实现与多芯光纤相似的信息内容的可能性，但占地面积要小得多，从而减少了内窥镜手术的侵入性。然而，这些进步受到不可避免的影响光在MMFs中传播的无序存在的阻碍，并限制了它们的实际应用。我们在这里介绍一个研究和避免无序影响的一般框架。我们通过实验发现了一套几乎完整的光学通道，它们对强变形引起的无序具有弹性。这些变形原理模态仅通过利用弱摄动的测量得到。我们通过证明，即使在高度无序的情况下，光在MMFs中的传播也可以通过几个关键特性来表征，从而解释了这种效应。这些结果之所以成为可能，要归功于光纤模态传输矩阵的精确和快速估计，这依赖于使用深度学习框架的基于模型的优化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Optics

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