Enhancement of acoustic sensitivity of hollow-core photonic bandgap fibers

Yang, Fan; Jin, Wei; Ho, S. L.; Wang, Fuyin; Li, Wen; Ma, Lei; Hu, Yongming

doi:10.1364/oe.21.015514

Cited by 22 publications

(11 citation statements)

References 22 publications

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“…The microstructured regions of the PCFs are modeled as anisotropic materials while the silica outer cladding and the acrylate regions are modeled as isotropic materials [11]. The effect of the coating material and thickness on NR was proposed by many researchers and recently in [12]. To avoid inaccurate comparison between the three investigated fibers because of different coating materials and thickness, the same coating material and thickness for all fibers are used.…”

Section: Simulation Results and Analysismentioning

confidence: 99%

“…Some of these advantages are; (1) design and manufacturing flexibility of HC-PBFs can reduce the effective Young's modulus of the fiber and enhances the NR of the HC-PBF [3,11], (2) the undesirable negative index effect introduced in SMF is expected to be greatly reduced in a HC-PBF in which most of the mode energy is confined in air, so the NR of the HC-PBF is expected to have higher sensitivity, (3) holes of the HC-PBF can be filled with a material with opposite thermal expansion to make the material completely temperature insensitive [9], (4) In the HC-PBF sensing coil, because the light travels through air, it has much smaller Kerr, Faraday, and thermal constants than silica cores, this reduces the dependencies on power, magnetic field, and temperature fluctuations [9], (5) HC-PBFs are almost entirely bend-insensitive and can be bent down to very small diameters (<1cm) with minimal loss, this makes it suitable for small-size hydrophone applications [5,12], and (6) HC-PBFs have very low back-reflection at the fiber end faces because of the close match of the mode index with the ambient air and this helps to reduce the back-reflected light level which is beneficial for many applications [10]. However, using PCFs as acoustic sensors needs further investigation to be feasible as an alternative to its counterpart of SMF interferometers.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Phase Sensitivity to Acoustic Pressure of Microstrustured Optical Fibers: A Comparison Study

Abdallah¹,

Zhang²,

Zhong³

2015

IJSIP

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Section: Simulation Results and Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Phase Sensitivity to Acoustic Pressure of Microstrustured Optical Fibers: A Comparison Study

Abdallah¹,

Zhang²,

Zhong³

2015

IJSIP

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“…Acoustic pressures with different amplitudes and frequencies that act on the investigated optical fiber are applied by the ASI. Once the induced stress distribution in the optical fiber is calculated, the anisotropic refractive index elements are calculated using (8), and the EMW module is used for mode analysis. Mode analysis study allows us to calculate eff , eff , MFD, and NA.…”

Section: Mathematical Modelmentioning

confidence: 99%

“…Some of these advantages are as follows. (1) The design and manufacturing flexibility of HC-PBFs reduces the effective Young's modulus of the fiber and enhances the NR of the HC-PBF to acoustic pressure [2], (2) matching between the mode indexes of the HC-PBF with the ambient air helps to reduce the back-reflected light at the fiber end faces which is useful for many applications [7], (3) holes of the HC-PBF can be filled with a substance with opposite thermal expansion to make the material insensitive to temperature [5], (4) in the HC-PBF, because the optical mode propagates in air, it has smaller Faraday, Kerr, and thermal constants than solid-silica cores, and this reduces the dependencies on temperature, magnetic field, and power fluctuations [5], and (5) HC-PBFs are almost entirely bend-insensitive and can be bent to very small diameters (<1 cm) with minimal loss, and this makes it suitable for small-size hydrophone systems [6,8]. However, using HC-PBFs as underwater acoustic sensors needs further investigation to be feasible alternatives to their 2 International Journal of Optics counterparts of SMFs.…”

Section: Introductionmentioning

confidence: 99%

Investigation on the Effect of Underwater Acoustic Pressure on the Fundamental Mode of Hollow-Core Photonic Bandgap Fibers

Abdallah

Zhang

Zhong

2015

International Journal of Optics

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Recently, microstructured optical fibers have become the subject of extensive research as they can be employed in many civilian and military applications. One of the recent areas of research is to enhance the normalized responsivity (NR) to acoustic pressure of the optical fiber hydrophones by replacing the conventional single mode fibers (SMFs) with hollow-core photonic bandgap fibers (HC-PBFs). However, this needs further investigation. In order to fully understand the feasibility of using HC-PBFs as acoustic pressure sensors and in underwater communication systems, it is important to study their modal properties in this environment. In this paper, the finite element solver (FES) COMSOL Multiphysics is used to study the effect of underwater acoustic pressure on the effective refractive index ( eff ) of the fundamental mode and discuss its contribution to NR. Besides, we investigate, for the first time to our knowledge, the effect of underwater acoustic pressure on the effective area ( eff ) and the numerical aperture (NA) of the HC-PBF.

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“…Yan et al reported the enhancement of the acoustic sensitivity with hollow-core photonic bandgap fibers (HC-PBFs) by using air-included polymer coatings [43]. The first investigations in this field were performed by Cole et al, where it was demonstrated that this type of coated fiber has similar normalized responsivity (NR) to the mandrel based hydrophones [44,45].…”

Section: Enhancement Of Acoustic Sensitivity Of Hollow-core Photonic mentioning

confidence: 99%

Advanced fiber-optic acoustic sensors

et al. 2014

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Acoustic sensing is nowadays a very demanding field which plays an important role in modern society, with applications spanning from structural health monitoring to medical imaging. Fiber-optics can bring many advantages to this field, and fiber-optic acoustic sensors show already performance levels capable of competing with the standard sensors based on piezoelectric transducers. This review presents the recent advances in the field of fiber-optic dynamic strain sensing, particularly for acoustic detection. Three dominant technologies are identified -fiber Bragg gratings, interferometric Mach-Zehnder, and Fabry-Pérot configurations -and their recent developments are summarized.

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Enhancement of acoustic sensitivity of hollow-core photonic bandgap fibers

Cited by 22 publications

References 22 publications

Phase Sensitivity to Acoustic Pressure of Microstrustured Optical Fibers: A Comparison Study

Phase Sensitivity to Acoustic Pressure of Microstrustured Optical Fibers: A Comparison Study

Investigation on the Effect of Underwater Acoustic Pressure on the Fundamental Mode of Hollow-Core Photonic Bandgap Fibers

Advanced fiber-optic acoustic sensors

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