远距离光纤传感网络中光纤Bragg光栅的设计

IF 0.8 Q3 ENGINEERING, MULTIDISCIPLINARY

Modelling and Simulation in Engineering Pub Date : 2022-10-05 DOI:10.1155/2022/8331485

J. Braunfelds, Elvis Haritonovs, U. Seņkāns, I. Kurbatska, I. Murans, J. Porins, S. Spolitis

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引用次数: 6

摘要

市场上的大多数光学传感器都是光纤布拉格光栅(FBG)传感器，具有低反射率(通常为7-40%)和低旁瓣抑制(SLS)比(通常SLS <15 dB)，这使得这些传感器无法有效地用于远距离远程监控和传感器网络解决方案。本研究的基础是设计光纤光栅传感器的最佳光栅结构，并估计传感器网络和远程监测解决方案所需的最佳化参数。研究了高斯、正弦和凸正弦消光，以达到最大反射率(至少90%)和旁瓣抑制(至少20 dB)，最大窄带宽(FWHM<0.2 nm)和均匀(无消光)的fbg的主要要求。本研究的结果提出了高效的FBG光栅补偿方案，可以进一步物理实现光传感器网络和远距离(至少40公里)监测解决方案。

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Designing of Fiber Bragg Gratings for Long-Distance Optical Fiber Sensing Networks

Most optical sensors on the market are optical fiber Bragg grating (FBG) sensors with low reflectivity (typically 7-40%) and low side-lobe suppression (SLS) ratio (typically SLS <15 dB), which prevents these sensors from being effectively used for long-distance remote monitoring and sensor network solutions. This research is based on designing the optimal grating structure of FBG sensors and estimating their optimal apodization parameters necessary for sensor networks and long-distance monitoring solutions. Gaussian, sine, and raised sine apodizations are studied to achieve the main requirements, which are maximally high reflectivity (at least 90%) and side-lobe suppression (at least 20 dB), as well as maximally narrow bandwidth (FWHM<0.2 nm) and FBGs with uniform (without apodization). Results gathered in this research propose high-efficiency FBG grating apodizations, which can be further physically realized for optical sensor networks and long-distance (at least 40 km) monitoring solutions.

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来源期刊

Modelling and Simulation in Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

2.70

自引率

3.10%

发文量

审稿时长

18 weeks

期刊介绍： Modelling and Simulation in Engineering aims at providing a forum for the discussion of formalisms, methodologies and simulation tools that are intended to support the new, broader interpretation of Engineering. Competitive pressures of Global Economy have had a profound effect on the manufacturing in Europe, Japan and the USA with much of the production being outsourced. In this context the traditional interpretation of engineering profession linked to the actual manufacturing needs to be broadened to include the integration of outsourced components and the consideration of logistic, economical and human factors in the design of engineering products and services.