Using a validated transmission model for the optimization of bundled fiber optic displacement sensors

Moro, Erik A.; Todd, Michael D.; Puckett, Anthony D.

doi:10.1364/ao.50.006526

Cited by 10 publications

(12 citation statements)

References 14 publications

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“…This sensor can measure linear displacement between the fibers and the reflective surface, relating it to the optical intensity reflected by the surface and coupled into the receiving fiber. Different configurations can be found in the literature with the emitting and receiving fibers positioned parallel to each other or in angle; instead of using only two fibers, a bundle of emitting fibers and/or a bundle of receiving fibers can be used to increase the sensitivity [11][12][13][14][15][16][17][18][19][20][21][22][23]. A drawback of this approach is the inability to distinguish linear displacement from angular displacement, decreasing the accuracy of the sensor [24].…”

Section: Introductionmentioning

confidence: 99%

High sensitivity fiber optic angular displacement sensor and its application for detection of ultrasound

Sakamoto¹,

Kitano

Pacheco

et al. 2012

Appl. Opt.

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In this paper, we report on the development of an intensity-modulated fiber-optic sensor for angular displacement measurement. This sensor was designed to present high sensitivity, linear response, and wide bandwidth and, furthermore, to be simple and low cost. The sensor comprises two optical fibers, a positive lens, a reflective surface, an optical source, and a photodetector. A mathematical model was developed to determine and simulate the static characteristic curve of the sensor and to compare different sensor configurations regarding the core radii of the optical fibers. The simulation results showed that the sensor configurations tested are highly sensitive to small angle variation (in the range of microradians) with nonlinearity less than or equal to 1%. The normalized sensitivity ranges from 0.25 × V max to 2.40 × V max mV ∕ μrad (where V max is the peak voltage of the static characteristic curve), and the linear range is from 194 to 1840 μrad. The unnormalized sensitivity for a reflective surface with reflectivity of 100% was measured as 7.7 mV ∕ μrad. The simulations were compared with experimental results to validate the mathematical model and to define the most suitable configuration for ultrasonic detection. The sensor was tested on the characterization of a piezoelectric transducer and as part of a laser ultrasonics setup. The velocities of the longitudinal, shear, and surface waves were measured on aluminum samples as 6.43, 3.17, and 2.96 mm ∕ μs, respectively, with an error smaller than 1.3%. The sensor, an alternative to piezoelectric or interferometric detectors, proved to be suitable for detection of ultrasonic waves and to perform time-of-flight measurements and nondestructive inspection.

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Section: Introductionmentioning

confidence: 99%

High sensitivity fiber optic angular displacement sensor and its application for detection of ultrasound

Sakamoto¹,

Kitano

Pacheco

et al. 2012

Appl. Opt.

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“…(2)-(4)] produce an interferogram whose frequency (f R ) is calculated using Eq. (7). The dominant tone in Table 1, therefore, oscillates at a frequency calculated as the sum: f R f b , where f R constitutes an unbiased positiondependent component and f b is a velocity-dependent bias.…”

Section: B Measured Interferogrammentioning

confidence: 99%

“…In some applications, this combination of absolute measurement and robust operation is highly desirable, since experimental uncertainty can be costly to eliminate. Further, in comparison to high-sensitivity, robust intensity-modulated sensing methodologies [5][6][7], both the absolute measurement capability and the ease with which robust operation is achieved make the white light EFPI architecture potentially well suited for deployment.…”

Section: Introductionmentioning

confidence: 99%

Understanding the effects of Doppler phenomena in white light Fabry–Perot interferometers for simultaneous position and velocity measurement

2012

Self Cite

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In static tests, low-power (<5 mW) white light extrinsic Fabry-Perot interferometric position sensors offer high-accuracy (μm) absolute measurements of a target's position over large (cm) axial-position ranges, and since position is demodulated directly from phase in the interferogram, these sensors are robust to fluctuations in measured power levels. However, target surface dynamics distort the interferogram via Doppler shifting, introducing a bias in the demodulation process. With typical commercial off-the-shelf hardware, a broadband source centered near 1550 nm, and an otherwise typical setup, the bias may be as large as 50-100 μm for target surface velocities as low as 0.1 mm/s. In this paper, the authors derive a model for this Doppler-induced position bias, relating its magnitude to three swept-filter tuning parameters. Target velocity (magnitude and direction) is calculated using this relationship in conjunction with a phase-diversity approach, and knowledge of the target's velocity is then used to compensate exactly for the position bias. The phase-diversity approach exploits side-by-side measurement signals, transmitted through separate swept filters with distinct tuning parameters, and permits simultaneous measurement of target velocity and target position, thereby mitigating the most fundamental performance limitation that exists on dynamic white light interferometric position sensors.

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“…Both linear variable displacement transformers [ 8 ] and linear encoders can supply nanoscale resolution with a large measurement range [ 9 , 10 ], however, they are unreliable in electromagnetic interference environments. Fiber optic sensors (FOS) have attracted much attention of researchers over the past few decades due to some innovative characteristics, such as high bandwidth, low loss, and can work under harsh environmental conditions compared to traditional sensors [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

An Optical Fiber Lateral Displacement Measurement Method and Experiments Based on Reflective Grating Panel

Guan

et al. 2016

Sensors

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An optical fiber sensing method based on a reflective grating panel is demonstrated for lateral displacement measurement. The reflective panel is a homemade grating with a periodic variation of its refractive index, which is used to modulate the reflected light intensity. The system structure and operation principle are illustrated in detail. The intensity calculation and simulation of the optical path are carried out to theoretically analyze the measurement performance. A distinctive fiber optic grating ruler with a special fiber optic measuring probe and reflective grating panel is set up. Experiments with different grating pitches are conducted, and long-distance measurements are executed to accomplish the functions of counting optical signals, subdivision, and discerning direction. Experimental results show that the proposed measurement method can be used to detect lateral displacement, especially for applications in working environments with high temperatures.

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Using a validated transmission model for the optimization of bundled fiber optic displacement sensors

Cited by 10 publications

References 14 publications

High sensitivity fiber optic angular displacement sensor and its application for detection of ultrasound

High sensitivity fiber optic angular displacement sensor and its application for detection of ultrasound

Understanding the effects of Doppler phenomena in white light Fabry–Perot interferometers for simultaneous position and velocity measurement

An Optical Fiber Lateral Displacement Measurement Method and Experiments Based on Reflective Grating Panel

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