The Temperature Compensation of FBG Sensor for Monitoring the Stress on Hole-Edge

Feifei Ren; Weifang Zhang; Yingwu Li; Yudong Lan; Yukuan Xie; Wei Dai

doi:10.1109/JPHOT.2018.2858847

The Temperature Compensation of FBG Sensor for Monitoring the Stress on Hole-Edge

Feifei Ren
, Weifang Zhang
, Yingwu Li^*
, Yudong Lan
, Yukuan Xie
, Wei Dai

^*Corresponding author for this work

Beihang University

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

To apply Fiber Bragg Grating (FBG) sensors in the hole structural health monitoring of aircraft, this study investigates a temperature compensation algorithm based on Fourier curve-fitting, combined with an analysis of FBG layout. The results identify that the wavelengths have a linear relationship with stress and temperature and the linear correlation coefficients are all greater than 0.9. In the experiment, the temperature range was 17 °C-100 °C (step is 10 °C) and the tensile force changed from 0 N to 10 KN (step is 1 KN). With the Fourier curve-fitting of the wavelength variation, the temperature compensation can be actualized, and the average error of temperature is 0.17 °C. By integrating the algorithm in the self-developed FBG interrogation system, the real-time monitoring of stress is achieved with the average error of stress is 3.9 μϵ.

Original language	English
Article number	8419234
Journal	IEEE Photonics Journal
Volume	10
Issue number	4
DOIs	https://doi.org/10.1109/JPHOT.2018.2858847
Publication status	Published - Aug 2018
Externally published	Yes

Keywords

FBG sensor
Fourier curve-fitting
aircraft.
hole structure
temperature compensation

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10.1109/JPHOT.2018.2858847

Cite this

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title = "The Temperature Compensation of FBG Sensor for Monitoring the Stress on Hole-Edge",

abstract = "To apply Fiber Bragg Grating (FBG) sensors in the hole structural health monitoring of aircraft, this study investigates a temperature compensation algorithm based on Fourier curve-fitting, combined with an analysis of FBG layout. The results identify that the wavelengths have a linear relationship with stress and temperature and the linear correlation coefficients are all greater than 0.9. In the experiment, the temperature range was 17 °C-100 °C (step is 10 °C) and the tensile force changed from 0 N to 10 KN (step is 1 KN). With the Fourier curve-fitting of the wavelength variation, the temperature compensation can be actualized, and the average error of temperature is 0.17 °C. By integrating the algorithm in the self-developed FBG interrogation system, the real-time monitoring of stress is achieved with the average error of stress is 3.9 μϵ.",

keywords = "FBG sensor, Fourier curve-fitting, aircraft., hole structure, temperature compensation",

author = "Feifei Ren and Weifang Zhang and Yingwu Li and Yudong Lan and Yukuan Xie and Wei Dai",

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AU - Ren, Feifei

AU - Zhang, Weifang

AU - Li, Yingwu

AU - Lan, Yudong

AU - Xie, Yukuan

AU - Dai, Wei

PY - 2018/8

Y1 - 2018/8

N2 - To apply Fiber Bragg Grating (FBG) sensors in the hole structural health monitoring of aircraft, this study investigates a temperature compensation algorithm based on Fourier curve-fitting, combined with an analysis of FBG layout. The results identify that the wavelengths have a linear relationship with stress and temperature and the linear correlation coefficients are all greater than 0.9. In the experiment, the temperature range was 17 °C-100 °C (step is 10 °C) and the tensile force changed from 0 N to 10 KN (step is 1 KN). With the Fourier curve-fitting of the wavelength variation, the temperature compensation can be actualized, and the average error of temperature is 0.17 °C. By integrating the algorithm in the self-developed FBG interrogation system, the real-time monitoring of stress is achieved with the average error of stress is 3.9 μϵ.

AB - To apply Fiber Bragg Grating (FBG) sensors in the hole structural health monitoring of aircraft, this study investigates a temperature compensation algorithm based on Fourier curve-fitting, combined with an analysis of FBG layout. The results identify that the wavelengths have a linear relationship with stress and temperature and the linear correlation coefficients are all greater than 0.9. In the experiment, the temperature range was 17 °C-100 °C (step is 10 °C) and the tensile force changed from 0 N to 10 KN (step is 1 KN). With the Fourier curve-fitting of the wavelength variation, the temperature compensation can be actualized, and the average error of temperature is 0.17 °C. By integrating the algorithm in the self-developed FBG interrogation system, the real-time monitoring of stress is achieved with the average error of stress is 3.9 μϵ.

KW - FBG sensor

KW - Fourier curve-fitting

KW - aircraft.

KW - hole structure

KW - temperature compensation

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The Temperature Compensation of FBG Sensor for Monitoring the Stress on Hole-Edge

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Keywords

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