Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications

Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications

A novel optimized apodization of Fiber Bragg Grating Sensor (FBGS) for quasi-distributed strain sensing applications is developed and introduced in this paper. The main objective of the proposed optimization is to obtain a reflectivity level higher than 90% and a side lobe level around −40 dB, which...

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Main Authors: Fahd Chaoui, Otman Aghzout, Mounia Chakkour, Mounir El Yakhloufi
Format: Article
Language:English
Published: Hindawi Limited 2016-01-01
Series:Active and Passive Electronic Components
Online Access:http://dx.doi.org/10.1155/2016/6523046
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spelling doaj-6c0ea68431a347a9b0fb34a13654387b2020-11-25T00:02:48ZengHindawi LimitedActive and Passive Electronic Components0882-75161563-50312016-01-01201610.1155/2016/65230466523046Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement ApplicationsFahd Chaoui0Otman Aghzout1Mounia Chakkour2Mounir El Yakhloufi3Department of Physics, Faculty of Sciences, UAE, Tetouan, MoroccoElectronics & Microwaves Group, Telecommunication Department, ENSA, UAE, Tetouan, MoroccoDepartment of Physics, Faculty of Sciences, UAE, Tetouan, MoroccoCondensed Matter Physics Group, Faculty of Sciences, UAE, Tetouan, MoroccoA novel optimized apodization of Fiber Bragg Grating Sensor (FBGS) for quasi-distributed strain sensing applications is developed and introduced in this paper. The main objective of the proposed optimization is to obtain a reflectivity level higher than 90% and a side lobe level around −40 dB, which is suitable for use in quasi-distributed strain sensing application. For this purpose, different design parameters as apodization profile, grating length, and refractive index have been investigated to enhance and optimize the FBGS design. The performance of the proposed apodization has then been compared in terms of reflectivity, side lobe level (SLL), and full width at half maximum (FWHM) with apodization profiles proposed by other authors. The optimized sensor is integrated on quasi-distributed sensing system of 8 sensors demonstrating high reliability. Wide strain sensitivity range for each channel has also been achieved in the quasi-distributed system. Results prove the efficiency of the proposed optimization which can be further implemented for any quasi-distributed sensing application.http://dx.doi.org/10.1155/2016/6523046
collection DOAJ
language English
format Article
sources DOAJ
author Fahd Chaoui
Otman Aghzout
Mounia Chakkour
Mounir El Yakhloufi
spellingShingle Fahd Chaoui
Otman Aghzout
Mounia Chakkour
Mounir El Yakhloufi
Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
Active and Passive Electronic Components
author_facet Fahd Chaoui
Otman Aghzout
Mounia Chakkour
Mounir El Yakhloufi
author_sort Fahd Chaoui
title Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
title_short Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
title_full Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
title_fullStr Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
title_full_unstemmed Apodization Optimization of FBG Strain Sensor for Quasi-Distributed Sensing Measurement Applications
title_sort apodization optimization of fbg strain sensor for quasi-distributed sensing measurement applications
publisher Hindawi Limited
series Active and Passive Electronic Components
issn 0882-7516
1563-5031
publishDate 2016-01-01
description A novel optimized apodization of Fiber Bragg Grating Sensor (FBGS) for quasi-distributed strain sensing applications is developed and introduced in this paper. The main objective of the proposed optimization is to obtain a reflectivity level higher than 90% and a side lobe level around −40 dB, which is suitable for use in quasi-distributed strain sensing application. For this purpose, different design parameters as apodization profile, grating length, and refractive index have been investigated to enhance and optimize the FBGS design. The performance of the proposed apodization has then been compared in terms of reflectivity, side lobe level (SLL), and full width at half maximum (FWHM) with apodization profiles proposed by other authors. The optimized sensor is integrated on quasi-distributed sensing system of 8 sensors demonstrating high reliability. Wide strain sensitivity range for each channel has also been achieved in the quasi-distributed system. Results prove the efficiency of the proposed optimization which can be further implemented for any quasi-distributed sensing application.
url http://dx.doi.org/10.1155/2016/6523046
work_keys_str_mv AT fahdchaoui apodizationoptimizationoffbgstrainsensorforquasidistributedsensingmeasurementapplications
AT otmanaghzout apodizationoptimizationoffbgstrainsensorforquasidistributedsensingmeasurementapplications
AT mouniachakkour apodizationoptimizationoffbgstrainsensorforquasidistributedsensingmeasurementapplications
AT mounirelyakhloufi apodizationoptimizationoffbgstrainsensorforquasidistributedsensingmeasurementapplications
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