Deep Learning-Based Simultaneous Temperature- and Curvature-Sensitive Scatterplot Recognition

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2024 Jul 13

PMID 39001188

Authors

Jianli Liu

Yuxin Ke

Dong Yang

Qiao Deng

Chuang Hei

Hu Han

Daicheng Peng

Fangqing Wen

Ankang Feng

Xueran Zhao

Affiliations

Soon will be listed here.

Abstract

Since light propagation in a multimode fiber (MMF) exhibits visually random and complex scattering patterns due to external interference, this study numerically models temperature and curvature through the finite element method in order to understand the complex interactions between the inputs and outputs of an optical fiber under conditions of temperature and curvature interference. The systematic analysis of the fiber's refractive index and bending loss characteristics determined its critical bending radius to be 15 mm. The temperature speckle atlas is plotted to reflect varying bending radii. An optimal end-to-end residual neural network model capable of automatically extracting highly similar scattering features is proposed and validated for the purpose of identifying temperature and curvature scattering maps of MMFs. The viability of the proposed scheme is tested through numerical simulations and experiments, the results of which demonstrate the effectiveness and robustness of the optimized network model.

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