EI / SCOPUS / CSCD 收录

中文核心期刊

SHI Shengguo, YANG Desen, HONG Lianjin. Research on sound wave receiving theory of co-oscillating sphere type vector hydrophone[J]. ACTA ACUSTICA, 2009, 34(1): 30-38. DOI: 10.15949/j.cnki.0371-0025.2009.01.004
Citation: SHI Shengguo, YANG Desen, HONG Lianjin. Research on sound wave receiving theory of co-oscillating sphere type vector hydrophone[J]. ACTA ACUSTICA, 2009, 34(1): 30-38. DOI: 10.15949/j.cnki.0371-0025.2009.01.004

Research on sound wave receiving theory of co-oscillating sphere type vector hydrophone

More Information
  • PACS: 
      43.30
  • Received Date: November 22, 2007
  • Revised Date: July 21, 2008
  • Available Online: July 05, 2022
  • Sound pressure wave and particle velocity wave receiving theory of co-oscillating sphere type vector hy- drophone has been studied in this paper.Based on measurement principle of particle co-oscillating sphere type velocity hydrophone,the expressions of sound wave receiving response of both unconstrained rigid sphere and unconstrained elastic sphere in an acoustic plane-wave field are derived,and the relationship between the frequency response curves of velocity hydrophone and its geometrical dimension and density.In addition,according to sound wave receiving theory of spherical receiving transducer,the expression of sound pressure receiving response of the vector hydrophone is derived, and the laws of the pressure distribution on the surface of particle velocity hydrophone and relationships between the pressure receiving coefficient of the vector hydrophone and the parameters,such as the dimensions of the receiving sur- face,the radius of the particle velocity hydrophone,the layout position and radius of sound pressure hydrophone,are analyzed and calculated.The analysis method of sound wave receiving theory of vector hydrophone is established,which lay the theoretical foundation for design and development of the vector hydrophone.
  • Related Articles

    [1]CHEN Yi, LIU Fei, TONG Haoyang, LI Wenjing, JIN Xiaofeng, XU Ping. A three-dimensional optical fiber vector hydrophone based on optical fiber accelerometers with integrated structural design[J]. ACTA ACUSTICA, 2025, 50(1): 157-164. DOI: 10.12395/0371-0025.2023161
    [2]LI Xionghui, LIANG Guolong, SHEN Tongsheng, LUO Zailei. Improved sparse Bayesian learning direction estimation algorithm for single vector hydrophones[J]. ACTA ACUSTICA, 2025, 50(1): 77-85. DOI: 10.12395/0371-0025.2023121
    [3]ZHU Xiaochun, ZHU Zhongrui, ZHANG Xu, SHI Shengguo. Direction-of-arrival estimation based on phase modal space for a circular acoustic vector-sensor array on the cylindrical baffle[J]. ACTA ACUSTICA, 2024, 49(2): 274-285. DOI: 10.12395/0371-0025.2022141
    [4]WANG Yujie, LI Zigao, CHI Cheng, JU Donghao, ZHANG Chunhua. Single vector hydrophone time-domain deconvolution bearing estimation method based on combined second-order statistics[J]. ACTA ACUSTICA, 2023, 48(4): 656-667. DOI: 10.15949/j.cnki.0371-0025.2023.04.003
    [5]ZHANG Hu, CHEN Hongjuan, ZHANG Honggang, WANG Peng. Sensitivity correction of co-vibrating vector hydrophone in standing wave tube by numerical calculation[J]. ACTA ACUSTICA, 2023, 48(3): 532-540. DOI: 10.15949/j.cnki.0371-0025.2023.03.003
    [6]FAN Qingqing, LI Junhong, ZHAI Yuguang, MA Jun. A novel MEMS piezoelectric vector hydrophone[J]. ACTA ACUSTICA, 2023, 48(1): 102-111. DOI: 10.15949/j.cnki.0371-0025.2023.01.011
    [7]WANG Chao, DA Lianglong, HAN Mei, SUN Qindong, WANG Wenlong. Single vector hydrophone sparse asymptotic minimum variance bearing estimation algorithm[J]. ACTA ACUSTICA, 2021, 46(6): 1050-1058. DOI: 10.15949/j.cnki.0371-0025.2021.06.024
    [8]TU Xinyu, LI Junbao, LIU Xiaodi. Low-frequency and high-sensitivity laminated beam-based acceleration sensors for vector hydrophones[J]. ACTA ACUSTICA, 2021, 46(4): 623-632. DOI: 10.15949/j.cnki.0371-0025.2021.04.014
    [9]WANG Xiaolin, LIU Bilong, YANG Jun, LIU Jingwei, WANG Ran. Utilizing vector hydrophones to achieve an active anechoic terminal in an acoustic tube[J]. ACTA ACUSTICA, 2019, 44(2): 258-264. DOI: 10.15949/j.cnki.0371-0025.2019.02.013
    [10]YIN Yilong, LI Junbao, XING Jianxin, LÜ Kejia. Research on the relaxor ferroelectric single crystal flexural beam vector hydrophone[J]. ACTA ACUSTICA, 2014, 39(2): 243-250. DOI: 10.15949/j.cnki.0371-0025.2014.02.011

Catalog

    Article Metrics

    Article views (67) PDF downloads (15) Cited by()
    Related

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return