A three-dimentional vector hydrophone based on fiber-optic flexural disk accelerometer

被引：0

作者：

Hangzhou Applied Acoustic Research Institute, Hangzhou ^{[1
]}

Zhejiang

310023, China

机构：

[1] Hangzhou Applied Acoustic Research Institute, Hangzhou, 310023, Zhejiang

来源：

Zhongguo Jiguang | / 3卷

关键词：

Fiber optic vector hydrophone; Fiber optics; Fiber-layer division method; Fiber-layer equivalent method; Finite element analysis; Pressure phase sensitivity;

D O I：

10.3788/CJL201542.0305004

中图分类号：

学科分类号：

摘要：

Fiber-optic vector hydrophone (FOVH), 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, finite element methods and experimental results of the fiberoptical flexural disk vector hydrophone are discussed (FOVH). Two finite element analysis methods are presented to forecast the performance, fiber-layer equivalent method (FLEM) and fiber-layer division method (FLDM), then a fiber-optic flexural disk vector hydrophone is developed and related metrology aspects of measurement is demonstrated. The experimental results are presented that pressure phase sensitivity of the hydrophone is -182 dB@100 Hz~-158.5 dB@1000 Hz (ref.1 rad/μPa) at the range from 100 Hz to 1000 Hz. The cross-sensitivity is less than -30 dB. It possesses a good directional performance. ©, 2015, Science Press. All right reserved.

引用

页数：7

共 13 条

[1] Nash P., Strudley A., Crickmore R., Et al., High efficiency TDM-WDM architectures for seismic reservoir monitoring, 7503, (2009)
[2] Freitas J., Recent developments in seismic seabed oil reservoir monitoring applications using fibre-optic sensing networks, Meas Sci Technol, 22, 5, pp. 1-26, (2011)
[3] Xiong S., Study of Fiber Optic Vector Hydrophone, (2003)
[4] Zeng N., Shi C., Zhang M., Et al., A 3-component fiber-optic accelerometer for well logging, Opt Commun, 234, pp. 153-162, (2004)
[5] Rao W., Zhang N., Niu S., Et al., Seafloor exploration using a 4-element towed fiber optic hydrophone array, ICEOE, 2, pp. 359-361, (2011)
[6] Wu Y., Study on Key Technology of Fiber Optic Vector Hydrophone in Towed Line Array, (2011)
[7] Wu Y., Luo H., Hu Z., Et al., Adaptive cancellation of background noise of fiber optic vector sensor system, Chinese J Lasers, 38, 3, (2011)
[8] Im J.-I., Roh Y.-R., A finite element analysis of an interferometric optical fiber hydrophone, J Acoust Soc Am, 103, 5, pp. 2425-2431, (1998)
[9] Im J.-I., Roh Y.-R., A finite element analysis of an interferometric optical fiber hydrophone with a concentric composite mandrel including a foaming layer, J Acoust Soc Am, 106, 3, pp. 1363-1368, (1999)
[10] Zhang H., Wang L., Shi Q., Et al., A new demodulation method for time division multiplexing system of fiber-optic hydrophone using a 3×3 coupler, Chinese J Lasers, 38, 5, (2011)

← 1 2 →