Probing micron-scale distributed contortions via a twisted multicore optical fiber

Ahmad, Raja; Westbrook, Paul S.; Ko, Wing; Feder, K.

doi:10.1063/1.5098959

Cited by 14 publications

(3 citation statements)

References 53 publications

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“…Lengths in excess of 1 km are readily fabricated into cables and can provide information about temperature, strain, and acoustics without the requirement for electrical connections, and with the possibility of resistance to harsh environmental conditions in various structures. Examples of sensing systems include distributed temperature (Gifford et al, 2005;Sancho et al, 2013), strain (Froggatt and Moore, 1998) and acoustic sensing (Daley et al, 2013;Kirkendall et al, 2007;Diamandi et al, 2019), as well as sensing of bend and shape (Gander et al, 2000;Duncan et al, 2007;Ahmad et al, 2019). A critical aspect of such systems is that they rely on backscattering of light propagating in the core of an optical fiber, usually in single-mode operation.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Optical Fiber for Distributed Acoustic Sensing beyond the Limits of Rayleigh Backscattering

Westbrook¹,

Feder²,

Kremp³

et al. 2020

iScience

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Section: Introductionmentioning

confidence: 99%

Enhanced Optical Fiber for Distributed Acoustic Sensing beyond the Limits of Rayleigh Backscattering

Westbrook¹,

Feder²,

Kremp³

et al. 2020

iScience

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“…In addition to MMF fiber imaging applications, many fiber-based sensors of bend, position, twist and displacement have been demonstrated. In the most general case, it has been shown that the entire three-dimensional shape of a fiber can be reconstructed using twisted multicore fibers and optical frequency domain reflectometry E-mail: tkremp@ofsoptics.com (OFDR) [13][14][15] . Such fiber shape reconstruction can be used in sensors and encoders for three-dimensional motion control applications in fields ranging from robotics to medical procedures.…”

Section: Introductionmentioning

confidence: 99%

Neural-network-based multimode fiber imaging and position sensing under thermal perturbations

Kremp¹,

Bagley

Lamb³

et al. 2023

Adaptive Optics and Wavefront Control for Biological Systems IX

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Multimode fibers (MMFs) have a very large number of propagating modes per unit area and therefore allow for imaging with a very large number of pixels relative to their diameter. This makes MMFs perfect candidates for ultrathin endoscopes in applications such as deep brain imaging. However, the accuracy of the input-output relation that is needed, e.g., for distal spot scanning without moving parts, requires a new calibration after the fiber position or temperature has been significantly altered.While neural networks have been used before to attempt to solve these challenges, we present an MMF-based imaging method that tolerates and classifies different fiber positions, using two single-layer fully-connected neural networks that only require the optical intensity without measuring the optical phase. One network learns the nonlinear relation between the input and output intensities and allows for image reconstruction in the presence of position changes, while the other network classifies that position change for different images. We show that our method is superior to memory-effect-based position sensing, both for small position changes where the relation between position change and output specklegram rotation angle is linear, as well as for larger position changes where this linearity and uniqueness break down. We also show that the position classification results are robust to temperature and polarization perturbations, and that our position classifier is able to effectively generalize. Likewise, we show that our imaging network also is robust to 30°C perturbations in temperature and 10°in polarization.

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“…The interference between two supermodes excited in the MCF has been used to obtain an interferometric strain sensor. Multi-parameter sensors for rotation and bending are reported in the literature as well [ 9 , 10 , 11 , 12 , 13 , 14 , 15 ].…”

Section: Introductionmentioning

confidence: 99%

Bend-Direction and Rotation Plastic Optical Fiber Sensor

Sartiano

Geernaert

Roca

et al. 2020

Sensors

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A plastic filament of poly (methyl methacrylate) (PMMA) was fabricated by extrusion. The mode confinement was simulated using numerical software. The idea is to study how the light intensity changes inside the plastic optical fiber (POF) when a bending in multiple directions is applied. The results obtained from the simulation were compared to the experimental observations. The non-circular shape of the POF allows sensing a rotation applied as well. The angle of rotation was obtained processing two images of the end facet of the fiber (one with the fiber in a reference position and one with the rotated fiber), using an intensity-based automatic image registration. The accuracy in the rotation calculation was of 0.01°.

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Probing micron-scale distributed contortions via a twisted multicore optical fiber

Cited by 14 publications

References 53 publications

Enhanced Optical Fiber for Distributed Acoustic Sensing beyond the Limits of Rayleigh Backscattering

Enhanced Optical Fiber for Distributed Acoustic Sensing beyond the Limits of Rayleigh Backscattering

Neural-network-based multimode fiber imaging and position sensing under thermal perturbations

Bend-Direction and Rotation Plastic Optical Fiber Sensor

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