Abstract
Fiber Bragg Gratings (FBGs) can be used as sensors for strain, temperature and pressure measurements. For this purpose, the ability to determine the Bragg peak wavelength with adequate wavelength resolution and accuracy is essential. However, conventional peak detection techniques, such as the maximum detection algorithm, can yield inaccurate and imprecise results, especially when the Signal to Noise Ratio (SNR) and the wavelength resolution are poor. Other techniques, such as the cross-correlation demodulation algorithm are more precise and accurate but require a considerable higher computational effort. To overcome these problems, we developed a novel fast phase correlation (FPC) peak detection algorithm, which computes the wavelength shift in the reflected spectrum of a FBG sensor. This paper analyzes the performance of the FPC algorithm for different values of the SNR and wavelength resolution. Using simulations and experiments, we compared the FPC with the maximum detection and cross-correlation algorithms. The FPC method demonstrated a detection precision and accuracy comparable with those of cross-correlation demodulation and considerably higher than those obtained with the maximum detection technique. Additionally, FPC showed to be about 50 times faster than the cross-correlation. It is therefore a promising tool for future implementation in real-time systems or in embedded hardware intended for FBG sensor interrogation.
Highlights
Fiber Bragg gratings (FBGs) made their first appearance about 30 years ago [1, 2]
A further problem common to all peak detection techniques is the so called peak locking effect. This phenomenon has been widely studied in the particle-image velocimetry (PIV) community [16, 17] but, to the best of our knowledge, it has never been considered in Fiber Bragg Gratings (FBGs) applications up to now
We proposed a novel peak detection technique based on phase correlation
Summary
Fiber Bragg gratings (FBGs) made their first appearance about 30 years ago [1, 2]. Their common characteristics, such as small size, low weight, insensitivity to electromagnetic interference, chemical inertness, high durability and resistance to corrosion, have made them extremely attractive for the engineering community. Many demodulation schemes for FBG wavelength shift monitoring have been developed, based for example on optical edge filters [7], on tunable fiber laser sources [8], and on Fourier domain mode locking-technology [9] These interrogation techniques have reached a wavelength scanning frequency of several thousands of Hz [9], necessitating high speed acquisition and computation capabilities. A further problem common to all peak detection techniques is the so called peak locking effect This phenomenon has been widely studied in the particle-image velocimetry (PIV) community [16, 17] but, to the best of our knowledge, it has never been considered in FBG applications up to now. We investigated the effects of sample resolution, peak locking and SNR on the precision and accuracy of the FPC algorithm. When M
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