A Review of Distributed Optical Fiber Sensors for Civil Engineering Applications

Barrias, António; Casas, Joan R.; Villalba, Sergi

doi:10.3390/s16050748

Cited by 660 publications

(348 citation statements)

References 125 publications

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“…Distributed optical fiber sensing using Rayleigh-based phase sensitive optical time-domain reflectometry (φOTDR) is gaining a great deal of interest in areas such as structure health monitoring, aerospace or material processing [1,2]. φOTDR-based sensors are routinely employed for the monitoring of mechanical variations (e.g., vibrations, displacements, etc.)…”

mentioning

confidence: 99%

Phase-sensitive OTDR probe pulse shapes robust against modulation-instability fading

Fernández‐Ruiz

Martins²,

Pastor-Graells

et al. 2016

Opt. Lett.

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Typicalphase-sensitive optical-time domain reflectometry (φOTDR) schemes rely on the use of coherent rectangular-shaped probe pulses. In these systems, there is a trade-off between the signal-to-noise ratio (SNR), spatial resolution and operating range of the φOTDR system. To increase any of these parameters, an increase in the pulse peak power is usually indispensable. However, as it is well-known, there is a limit in the allowable increase in probe power due to the onset of undesired nonlinear effects such as modulation instability. In this Letter, we perform an analysis of the effect of the probe pulse shape on the visibility fading due to modulation instability. In particular, four different temporal profiles are chosen, namely, rectangular, Gaussian, triangular and super-Gaussian (order 2). Our numerical and experimental analyses reveal that the use of triangular or Gaussian-like pulses can significantly inhibit the visibility fading issues. As such, an increase in the range up to two-fold for the same pulse energy (i.e., SNR) and nominal spatial resolution can be achieved, as compared with the results obtained when using rectangular pulses. This is due to a more robust behavior of the Gaussian and triangular pulses against the FermiPasta-Ulam (FPU) recurrence occurring in modulation instability.

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mentioning

confidence: 99%

Phase-sensitive OTDR probe pulse shapes robust against modulation-instability fading

Fernández‐Ruiz

Martins²,

Pastor-Graells

et al. 2016

Opt. Lett.

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“…The strain precisions are OFDR (1 με), BOTDR (40 με), BOTDA (20 με), BOFDA (2 με), BOCDA (10 με), FBG (1 με). The OFDR is a type of DOFS technologies which has shorter measuring time, higher sensitivity, and higher spatial resolution than other frequently-used DOFS technologies like BOTDR, BOTDA, BOFDA, BOCDA, and so on [10][11][12][13][14][15][16][17][18][19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Experiment and Numerical Study on Deformation Measurement of Cast-in-Place Concrete Large-Diameter Pipe Pile Using Optical Frequency Domain Reflectometer Technology

et al. 2018

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Abstract:The Cast-in-place concrete large-diameter pipe (PCC) pile has been used as the foundation reinforcement and embankment in China due to its low cost and high bearing capacity. The deformation of PCC pile under different vertical loads is very important for the application of engineering. In order to study the deformation characteristics of PCC pile, a small-scale model test was carried out. The new distributed measuring technology, named Optical Frequency Domain Reflectometer (OFDR), was applied to measure the strain on the PCC pile. A single mode fiber (SMF) was used, and the methods of layout, packaging and protection of optical fiber are introduced in detail. The obtained data was dealt with by wavelet transform, and the strain curves were analyzed based on the experiments. The finite element (FE) analysis model was established by COMSOL Multiphysics, and the numerical results compared with the experiment results. It showed that the optical fiber sensor can measure the strain of PCC pile, and that the deformation of PCC pile can be successfully obtained by OFDR technology. The strain of the pile decreases with depth and increases with loading. The measured result agrees well with numerical simulation result. The potential application of OFDR technology to PCC pile in situ and PCC energy pile is discussed.

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“…The principle is to transform photon energy into electric field and current by means of semiconductor with specific structure, and its quantum efficiency is 80~90%. Barrias, A. et al [6] found that the singular area of internal temperature in buildings would not be detected inevitably because of a large layout spacing of thermistor thermometers and other reasons. Fiber optic sensing is developed with the development of optical communication and the development of IT industry.…”

Section: State Of the Artmentioning

confidence: 99%

“…After fitting the sensing data of 2 sliding optical fibers, we can draw a conclusion that the coefficient & 1 and & 2 are close to each other. We can get the data fitting of & 1 and & 2 in pairs using formula (6) in several groups of experiments, and get the values of multiple groups of & 1 and & 2 respectively, and then we can get the average value. By calculating these values produced thereof , we can have the correlation between light loss A and sliding distance !…”

Section: Fiber Loss Monitoring and Statistics Analysismentioning

confidence: 99%

Distributed Fiber Optical Technology for Damage Identification of Engineering Structure

Dong¹,

Zhou²

2018

Int. J. Onl. Eng.

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Abstract-To conduct optical fiber monitoring rock slide model test and optical fiber monitoring of steel concrete interface slip model test, the large triaxial shear test of geotechnical engineering was used. First, the data of sliding distance and optical loss and their dynamic range were obtained. Second, the slide distance and fiber loss relation curve and the fitting equation were worked out. Finally, the typical applications of optical fiber sensing technology in Rock Engineering (high slope engineering, rock foundation of Dam Engineering) slope stability and geological disaster monitoring were put forward. The results showed that optical fiber sensing was very sensitive, and the loss value was 30 to 50dB. The dynamic range of rock slide monitoring fiber was 3 to 3.5mm, and the dynamic range of the interface slip monitoring fiber was 1.6mm. Thus, the sensing system can detect the sliding process of the interface between the concrete and the steel plate. It provides some reference for the sliding monitoring of the composite materials.

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A Review of Distributed Optical Fiber Sensors for Civil Engineering Applications

Cited by 660 publications

References 125 publications

Phase-sensitive OTDR probe pulse shapes robust against modulation-instability fading

Phase-sensitive OTDR probe pulse shapes robust against modulation-instability fading

Experiment and Numerical Study on Deformation Measurement of Cast-in-Place Concrete Large-Diameter Pipe Pile Using Optical Frequency Domain Reflectometer Technology

Distributed Fiber Optical Technology for Damage Identification of Engineering Structure

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