The optimal design of a 3D column type fiber-optic vector hydrophone

2016 IEEE/OES China Ocean Acoustics (COA) Pub Date : 1900-01-01 DOI:10.1109/COA.2016.7535714

Jin Mengqun, Ge Huiliang, Z. Zili

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引用次数: 1

Abstract

A 3-dimentional fiber-optic vector hydrophone, with many advantages including high sensitivity, large dynamic range, intrinsic immunity to electromagnetic interference and light weight, is becoming a hotspot of new-style vector sensors. For array applications, this review has discussed the finite element methods and experimental results of the hydrophone. A fiber-optic flexural disk vector hydrophone has been developed and related metrology aspects of measurement have been demonstrated. To figure out the issue of fiber-optic vector hydrophone, we optimize the hydrophone with an optical scheme, mechanism construction and sensing properties. In the optical scheme aspect, we replace the traditional optical devices with low reflectivity a fiber Bragg grating to simplify the optical scheme and minimize the sensor size. In the sensing properties aspect, we optimize the sensing parameter of the fiber-optic acceleration component with finite element analysis. The influence factor of the acoustic performance is discussed. In the mechanism construction aspect, a 3-dimetional isolated acceleration sensing structure is presented with a fiber-optic pressure component outside. A column type fiber optic vector hydrophone sample is then introduced. The size of the hydrophone is φ60mm×125mm. The acceleration sensitivity of the acceleration component is 22.5dB ref.1rad/g; and, with fluctuation of ±1.5dB ref.1rad/g at the range from 100Hz to 1000Hz. The equivalent pressure phase sensitivity in water of each axis is -183.5dB ref. 1rad/uPa@100Hz ~ -159dB ref. 1rad/uPa@1000Hz; and, with fluctuation of ±1.5dB at the range from 100 to 1000Hz. The cross talk of each axis is below -20dB. The pressure sensitivity of the pressure component is -131.8 ref. 1rad/uPa; and, with fluctuation of ±1dB. We also test the directionality of the 3 acceleration component and pressure component. It has a good directionality performance and the maximum value non uniformity of the acceleration component is below 1dB.

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三维柱型光纤矢量水听器的优化设计

三维光纤矢量水听器具有灵敏度高、动态范围大、抗电磁干扰、重量轻等优点，正成为新型矢量传感器的研究热点。在阵列应用方面，本文讨论了水听器的有限元方法和实验结果。一种光纤弯曲圆盘矢量水听器已经开发和相关的计量方面的测量已经证明。为了解决光纤矢量水听器的问题，从光学方案、机构结构和传感性能三个方面对光纤矢量水听器进行了优化。在光学方案方面，我们用光纤布拉格光栅代替传统的低反射率光学器件，简化了光学方案，减小了传感器的尺寸。在传感性能方面，采用有限元方法对光纤加速度元件的传感参数进行了优化。讨论了影响声性能的因素。在机构结构方面，提出了一种外置光纤压力元件的三维隔离加速度传感结构。然后介绍了一种柱式光纤矢量水听器样品。水听器的尺寸为φ60mm×125mm。加速度元件的加速度灵敏度为22.5dB ref.1rad/g;在100Hz至1000Hz范围内，波动为±1.5dB ref.1rad/g。各轴在水中的等效压力相灵敏度为-183.5dB ref. 1rad/uPa@100Hz ~ -159dB ref. 1rad/uPa@1000Hz;在100 ~ 1000Hz范围内波动为±1.5dB。各轴串扰低于-20dB。压力元件的压力灵敏度为-131.8 ref. 1rad/uPa;，波动为±1dB。我们还测试了3个加速度分量和压力分量的方向性。它具有良好的方向性，加速度分量的最大不均匀性在1dB以下。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 IEEE/OES China Ocean Acoustics (COA)

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