Interrogation of Ultrashort Bragg Grating Sensors Using Shifted Optical Gaussian Filters

Cheng, Rui; Xia, Li; Ran, Yanli; Rohollahnejad, Jalal; Zhou, Jiaao; Wen, Yongqiang

doi:10.1109/lpt.2015.2443812

Cited by 31 publications

(17 citation statements)

References 18 publications

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“…Power arising from the FBG residual sidelobes are the main factor limiting the linear operational range in the conventional measurement method, which involves the differential detection of the overall received power Pi, i.e. the integral of the product R(λ)Fi(λ) [18,19]. Nevertheless, in the proposed method, the grating sidelobes are temporally separated from the main lobe in the detected signal due to the wavelength-to-time mapping, and thus, they do not contribute to the amplitude measurement.…”

Section: Sidelobes Considerationmentioning

confidence: 99%

“…This scheme has been proven to provide ultra-high sensitivity, and it is a promising solution for interrogation of FBGs with a wide spectrum [18]. However, the wavelength range in which the system shows a linear dependence is limited as power reflected from the grating sidelobes become non-negligible [18][19]. In fact, this shortcoming is common to every filtering-based techniques.…”

mentioning

confidence: 99%

“…Consequently, measurement distortions arising from residual power due to the FBG side lobes are avoided, and the linear operational range is considerably extended. Moreover, in contrast to previous works in which the FBG spectral width must be either much narrower [17] or equal [18] to that of the Gaussian filters, we generalize the method for FBG sensors having an arbitrary spectral bandwidth, so the proposed system is further improved in terms of flexibility. Theoretical analysis and experimental results are presented and discussed.…”

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confidence: 99%

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High-speed and high-resolution interrogation of FBG sensors using wavelength-to-time mapping and Gaussian filters

Fernandez¹,

Rossini²,

Cruz³

et al. 2019

Opt. Express

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In this work we report a novel technique for simultaneous high-speed and highresolution interrogation of fiber Bragg grating (FBG) sensors. The method uses the wavelengthto-time mapping effect in a chromatic dispersive medium and a couple of intensity Gaussian filters. The Bragg wavelength is retrieved by means of the amplitude comparison between the two filtered grating spectrums, which are mapped into a time-domain waveform. In this way, measurement distortions arising from residual power due to the grating sidelobes are completely avoided, and the wavelength measurement range is considerably extended with respect to the previously proposed schemes. We present the mathematical background for the interrogation of FBGs with an arbitrary bandwidth. In our proof-of-concept experiments, we achieved sensitivities of ~20 pm with ultra-fast rates up to 264 MHz. IntroductionBragg gratings are among the most popular optical devices and they find applications in a wide variety of fields such as optical signal processing [1,2], optical communications [3,4], microwave photonics [5], and sensoring [6,7]. In this sense, fiber Bragg grating (FBG) sensors are based on wavelength modulation, in which the sensed parameter (e.g. strain or temperature) is linearly related to the grating central wavelength [8].The most extended FBG interrogation techniques use static filters to convert the wavelength shift into an intensity change. Among these methods, the edge filter [11][12], in which the detected light intensity is proportional to the wavelength drift, has attracted more attention due to its simple, low-cost and reliable structure. Interrogation of FBG sensors with speeds up to hundreds of megahertz is desirable in applications such as monitoring of ultra-fast dynamic phenomena, e.g. molecular dynamics sensing and in aerospace diagnostics. To this end, techniques based on the wavelength-to-time mapping using broadband short pulses and dispersive components have been demonstrated [13][14][15][16]. The main drawbacks of these schemes are the fundamental tradeoff between interrogation speed and wavelength resolution, and the need for expensive high-speed photodiodes and sampling electronics.The conventional intensity-based methods require to be operated in the linear range of a filter to ensure a linear detection. Recently, Cheng et al [17] proposed an interrogation system in which the linear dependence is achieved using Gaussian filters. The difference between the intensities at the output of two crossed Gaussian filters ultimately leads to a linear behavior, which is exploited for the Bragg wavelength determination. This scheme has been proven to provide ultra-high sensitivity, and it is a promising solution for interrogation of FBGs with a wide spectrum [18]. However, the wavelength range in which the system shows a linear dependence is limited as power reflected from the grating sidelobes become non-negligible [18][19]. In fact, this shortcoming is common to every filtering-based techniques.

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Section: Sidelobes Considerationmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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High-speed and high-resolution interrogation of FBG sensors using wavelength-to-time mapping and Gaussian filters

Fernandez¹,

Rossini²,

Cruz³

et al. 2019

Opt. Express

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“…The product between two different codewords (or even between shifted versions of the same codeword) is constrained to a lower value, which is the cross-correlation product (XC) [7]. From this concept, we can identify the central position of the encoded sensors by evaluating the auto-correlation product between each codeword and the total measured reflection spectrum (similar to the approaches presented in [9], [10]). Fig.…”

Section: Encoded Fbg Sensorsmentioning

confidence: 99%

Overlap-Proof Fiber Bragg Grating Sensing System Using Spectral Encoding

Triana

Pastor

Varón

2016

IEEE Photon. Technol. Lett.

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“…However, due to their inherent broad spectra which are unfavorable for many spectral interrogation techniques, such USFBGs have rarely been used as sensors. Even so, several important advantages can be envisaged if USFBGs can be used as grating sensors, especially for distributed measurements [5]. Recently, we have introduced USFBGs potentials as weak sensing units and have demonstrated an identical USFBG based distributed microwave-photonic sensing system [6].…”

Section: Introductionmentioning

confidence: 99%

Fast and reliable interrogation of USFBG sensors based on MG-Y laser discrete wavelength channels

Rohollahnejad

Xia

Cheng

et al. 2017

Optics Communications

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In this letter, we propose to use discrete wavelength channels of a single chip MG-Y laser to interrogate an ultra-short fiber Bragg grating with a wide Gaussian spectrum. The broadband Gaussian spectrum of USFBG is sampled by the wavelength channels of MG-Y laser, through which the center of the spectrum. The measurement inherits the important features of a common tunable laser interrogation technique, namely its high flexibility, natural insensitivity to intensity variations relative to common intensity-based approaches. While for traditional tunable laser methods, it requires to sweep the whole spectrum to obtain the center wavelength of the spectrum, for the proposed scheme, just a few discrete wavelength channels of laser are needed to be acquired, which leads to significant improvements of the efficiency and measurement speed. This reliable and low cost concept could offer the good foundation for USFBGs future applications in large scale distributed measurements, especially in time domain multiplexing scheme.

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Interrogation of Ultrashort Bragg Grating Sensors Using Shifted Optical Gaussian Filters

Cited by 31 publications

References 18 publications

High-speed and high-resolution interrogation of FBG sensors using wavelength-to-time mapping and Gaussian filters

High-speed and high-resolution interrogation of FBG sensors using wavelength-to-time mapping and Gaussian filters

Overlap-Proof Fiber Bragg Grating Sensing System Using Spectral Encoding

Fast and reliable interrogation of USFBG sensors based on MG-Y laser discrete wavelength channels

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