Extrinsic Fabry-Pérot Underwater Acoustic Sensor Based on Micromachined Center-Embossed Diaphragm

Most research works emphasized on the acoustic sensor miniaturization are not optimized for applications under high surrounding pressure. For underwater acoustic sensing, measuring the small acoustic pressure from the huge hydrostatic pressure makes the design of the sensor challenging. In this pape...

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Bibliographic Details
Published inJournal of lightwave technology Vol. 32; no. 23; pp. 4628 - 4636
Main Authors Fuyin Wang, Zhengzheng Shao, Jiehui Xie, Zhengliang Hu, Hong Luo, Yongming Hu
Format Journal Article
LanguageEnglish
Published IEEE 01.12.2014
Subjects
acoustic sensing
Adaptive optics
Cavity resonators
diaphragm
extrinsic Fabry-Perot interferometer
membrane
micromachining
Optical device fabrication
Optical fiber sensors
Optical interferometry
Optical sensors
Sensitivity
micromachining
diaphragm
Acoustic sensing
membrane
extrinsic Fabry–Pérot interferometer
optical fiber sensors
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Summary:Most research works emphasized on the acoustic sensor miniaturization are not optimized for applications under high surrounding pressure. For underwater acoustic sensing, measuring the small acoustic pressure from the huge hydrostatic pressure makes the design of the sensor challenging. In this paper, we attempt to solve the problem by adopting a center-embossed diaphragm as the sensitive structure. The deformation angular error is defined to evaluate the optical performance degradation and the optical sensitivity reduction under hydrostatic pressure. Simulations indicate that the central embossment is beneficial to maintain optics-related properties, although the structural sensitivity is reduced. Then, the diaphragm design guideline for underwater acoustic sensing is regulated. An optical fiber extrinsic Fabry-Perot interferometer probe based on the diaphragm, which was micromachined by double-side etching of the silicon on insulator, was designed and assembled. Experimental results show that the interferometric fringe preserves similar shapes at any tested depth from 0 (in air) to 50 cm. The recovered signal detected by the sensor coincides well with the corresponding transmitted signal. The pressure sensitivity response is flat in frequency range from 10 to 2 kHz, of which value is about -154.6 dB re. 1/μPa. It agrees well with the theoretical predication. These results demonstrated that the designed sensor according to the guideline can be used as an underwater acoustic sensor. Moreover, the sensor has potential applications in smart unmanned platforms and swiftly deployable arrays.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2014.2362494