[1] HE T. Design and test of cylindrical high hydrostatic pressure hydrophone[J]. Journal of Applied Acoustics, 38, 1033-1036(2019).

     何涛. 圆柱形超高静水压水听器设计与测试[J]. 应用声学, 38, 1033-1036(2019).

[2] DANDRIDGE A, COGDELL G B. Fiber optic sensors for navy applications[J]. IEEE Lcs, 2, 81-89(1991).

[3] DAI S, ZHANG H, WEI C et al. Preliminary application of single-receiver fiber-optic hydrophone array in marine gas hydrate seismic exploration[J]. Equipment for Geophysical Prospecting, 28, 145-151(2018).

[4] CAO C Y. Study on Key Techniques of High Performance Fiber-Optics Hydrophone Array Based on Ultra-Remotely Optical Transmission and Cascaded Amplifiers[D](2013).

     曹春燕. 光纤水听器阵列超远程光传输低噪声光放大链关键技术研究[D](2013).

[5] BOUFFARON R, LAUNAY F X, MOLIN S et al. All-optical Acoustic Array for Underwater Surveillance[C](2013).

[6] LU Q Z, HUANG J B et al. Design of resistant static pressure probe for DFB fiber laser hydrophone[J]. Journal of Applied Optics, 41, 428-434(2020).

[7] WANG J, CHEN K, TANG J et al. Development of deep-sea detector of the mandrel interferometric optical fiber hydrophone[J]. Optical Fiber & Electric Cable and Their Applications, 04, 14-17(2019).

[8] MENG Z, CHEN W, WANG J F et al. Research progress of fiber optic hydrophone technology[J]. Laser & Optoelectronics Progress, 58, 1306009(2021).

     孟洲, 陈伟, 王建飞. 光纤水听器技术的研究进展[J]. 激光与光电子学进展, 58, 1306009(2021).

[9] SHI J H, GUANG D, LI S L et al. Phase-shifted demodulation technique with additional modulation based on a 3×3 coupler and EFA for the interrogation of fiber-optic interferometric sensors[J]. Optics Letters, 46, 2900-2903(2021).

[10] 杨悦. 超低频光纤水听器的研制[D](2022).

     YANG Y. Research and Development of Ultra-Low-Frequency Fiber Optic hydrophone[D](2022).

[11] WANG F Y. Study on A Novel Combined Fiber Optic Vector Hydrophone[D](2011).

     王付印. 新型组合式光纤矢量水听器研究[D](2011).

[12] YANG Y, CHANG T Y, YU M et al. Physics-based performance optimization of fiber-optic interferometric hydrophone with push–pull mandrel structure[J]. IEEE Sensors Journal, 22, 19346-19356(2022).

[13] GUANG D, SUN X Y, SHI J H et al. Sensitivity improvement of fiber optic interferometric hydrophone based on composite structure[J]. Optics Express, 32, 47721-47734(2024).

[14] 冯玉祥, 刘志凯, 黄闽南. 单光路拉曼分布式光纤测温系统[J]. 光学 精密工程, 32, 2645-2653(2024).

     FENG Y X, LIU Z K, HUANG M N et al. Single optical channel based Raman distributed optical fiber temperature measurement system[J]. Opt. Precision Eng., 32, 2645-2653(2024).

[15] LIU F, LIANG Y Z, CAO J J et al. Radio-frequency heterodyne detection of fiber-optic ultrasonic sensor[J]. Opt. Precision Eng., 32, 2708-2717(2024).

     刘付武兴, 梁贻智, 曹君杰. 光纤超声传感器的射频域自相干解调技术[J]. 光学 精密工程, 32, 2708-2717(2024).

[16] LI S Y[M]. Pressure vessel Design Engineer Training Tutorial(2019).

     李世玉[M]. 压力容器设计工程师培训教程(2019).

[17] [standard](2011).

     [standard](2011).

[18] [standard].

     [standard].

[19] YANG Y, LUO Z C, WANG Z M et al. High-performance fiber optic interferometric hydrophone based on push-pull structure[J]. IEEE Transactions on Instrumentation and Measurement, 70, 9511313(2021).