Geoacoustic Inversion for Bottom Parameters in the Deep-Water Area of the South China Sea 被引量：13

Geoacoustic Inversion for Bottom Parameters in the Deep-Water Area of the South China Sea

下载PDF

导出

摘要 Bottom acoustic parameters play an important role in sound field prediction. Acoustic parameters in deep water are not well understood. Bottom acoustic parameters are sensitive to the transmission-loss （TL） data in the shadow zone of deep water. We propose a multiple-step fill inversion method to invert sound speed, density and attenuation in deep water. Based on a uniform liquid hMf-space bottom model, sound speed of the bottom is inverted by using the long range TL at low frequency obtained in an acoustic propagation experiment conducted in the South China Sea （SCS） in summer 2014. Meanwhile, bottom density is estimated combining with the Hamilton sediment empirical relationship. Attenuation coefficients at different frequencies are then estimated from the TL data in the shadow zones by using the known sound speed and density as a constraint condition. The nonlinear relationship between attenuation coefficient and frequency is given in the end. Tile inverted bottom parameters can be used to forecast the transmission loss in the deep water area of SCS very we//. Bottom acoustic parameters play an important role in sound field prediction. Acoustic parameters in deep water are not well understood. Bottom acoustic parameters are sensitive to the transmission-loss （TL） data in the shadow zone of deep water. We propose a multiple-step fill inversion method to invert sound speed, density and attenuation in deep water. Based on a uniform liquid hMf-space bottom model, sound speed of the bottom is inverted by using the long range TL at low frequency obtained in an acoustic propagation experiment conducted in the South China Sea （SCS） in summer 2014. Meanwhile, bottom density is estimated combining with the Hamilton sediment empirical relationship. Attenuation coefficients at different frequencies are then estimated from the TL data in the shadow zones by using the known sound speed and density as a constraint condition. The nonlinear relationship between attenuation coefficient and frequency is given in the end. Tile inverted bottom parameters can be used to forecast the transmission loss in the deep water area of SCS very we//.

作者吴双林李整林秦继兴

机构地区 State Key Laboratory of Acoustics Fiaikou Laboratory of Acoustics University of Chinese Academy of Sciences

出处《Chinese Physics Letters》 SCIE CAS CSCD 2015年第12期70-73,共4页 中国物理快报（英文版）

基金 Supported by the National Natural Science Foundation of China under Grant Nos 11434012,41561144006,11174312 and 11404366

关键词 Geoacoustic Inversion for Bottom Parameters in the Deep-Water Area of the South China Sea TL SCS

分类号 O427 [理学—声学]

引文网络
相关文献

参考文献14

1Zhang X L, Li Z L and Huang X D 2010 Chin. J. Acoust. 29 162.
2D'Spain G L, Murray J J and Hodgkiss W S 1999 J. Acoust. Soc. Am. 105 3245.
3Zhou J X 1985 J. Acoust. Soc. Am. 78 1003.
4Li Z L and Zhang R H 2007 Chin. Phys. Lett. 24 471.
5Li Z L and Zhang R H 2004 IEEE J. Oceanic Eng. 29 973.
6Li Z L and Zhang R H 2004 Chin. Phys. Lett. 21 1100.
7Li Z L, Li F H, Liu J J et al 2006 Chin. Phys. Lett. 23 2483.
8Li F H and Zhang R H 2000 Chin. J. Acoust. 25 297.
9Li Q Q, Li Z L and Zhang R H 2011 Chin. Phys. Lett. 28 034303.
10Jensen F B, Kuperman W A and Porter M B 2011 Comput. Ocean Acoust. 2nd edn (New York: Springer).

同被引文献89

1LI Zhenglin ZHANG Renhe PENG Zhaohui LI Xilu.Anomalous sound propagation due to the horizontal variation of seabed acoustic properties[J].Science China(Physics,Mechanics & Astronomy),2004,47(5):571-580. 被引量：5
2LIZheng-Lin ZHANGRen-He.A Broadband Geoacoustic Inversion Scheme[J].Chinese Physics Letters,2004,21(6):1100-1103. 被引量：17
3YAN Jin,ZHANG Renhe,ZHOU Shihong,SHA Liewei (National Laboratory of Acoustics, Chinese Academy of Sciences Beijing 100080).Characteristics of the internal waves and their effects on the sound transmission in the Midst of the Yellow Sea[J].Chinese Journal of Acoustics,1999,18(1):47-55. 被引量：6
4陈守虎,吴立新,张仁和,李整林,James F.Lynch,Timothy F.Duda,Arthur E.Newhall.南中国海内波特征及其引起的声场起伏[J].自然科学进展,2004,14(10):1163-1170. 被引量：14
5李秀林,李整林,李风华,彭朝晖.浅海水平纵向相关与海底参数反演[J].自然科学进展,2005,15(1):38-45. 被引量：5
6HUANGXiaodi LIZhenglin ZHANGRenhe.Effects of the internal waves on the time correlation of the acoustic fields in the East China Sea[J].Progress in Natural Science:Materials International,2004,14(11):945-949. 被引量：8
7李秀林,倪明,李整林,李风华,张仁和.基于光纤水听器的声场水平相关性研究[J].应用声学,2005,24(1):11-14. 被引量：9
8张仁和,何怡,刘红.水平不变海洋声道中的WKBZ简正波方法[J].声学学报,1994,19(1):1-12. 被引量：45
9陈庚,籍顺心.菲律宾海声传播信道时空相关性变化实验[J].声学学报,1994,19(4):266-277. 被引量：7
10彭朝晖,张仁和.三维耦合简正波-抛物方程理论及算法研究[J].声学学报,2005,30(2):97-102. 被引量：24

引证文献13

1李梦竹,李整林,李倩倩.南海北部负跃层环境下海底参数声学反演[J].声学学报,2019,44(3):321-328. 被引量：10
2王梦圆,李整林,秦继兴,吴双林.深海直达声区水下声源距离深度联合估计[J].信号处理,2019,35(9):1535-1543. 被引量：10
3WANG Mengyuan,LI Zhenglin,WU Shuanglin,QIN Jixing,YU Yanxin.The characteristic of sound propagation in deep water and underwater source localization in the direct zone[J].Chinese Journal of Acoustics,2019,38(4):433-444. 被引量：1
4LI Mengzhu,LI Zhenglin,Li Qianqian.Geoacoustic inversion for bottom parameters in a thermocline environment in the northern area of the South China Sea[J].Chinese Journal of Acoustics,2020,39(1):39-52.
5ZHANG Qingqing,LI Zhenglin,QIN Jixing,LI Wen,WU Shuanglin.The convergence of sound field in a South China Sea canyon[J].Chinese Journal of Acoustics,2020,39(2):164-175.
6张青青,李整林,秦继兴,李文,吴双林.南海海域跨海沟环境的声场会聚特性[J].声学学报,2020,45(4):458-465. 被引量：5
7刘炎堃,郭永刚,李整林,李风华,张波.基于路径选择的深海水下运动目标被动深度估计[J].应用声学,2020,39(5):647-655. 被引量：4
8张青青,李整林,秦继兴.南中国海海域存在孤立子内波条件下的声场统计特性[J].应用声学,2020,39(6):821-830. 被引量：3
9王梦圆,李整林,秦继兴,吴双林,王光旭.深海直达声区中大深度声场水平纵向相关特性[J].兵工学报,2021,42(4):817-826. 被引量：1
10薛城,宫在晓,顾怡鸣,王域,林鹏,李整林.结合卷积神经网络的浅海有源探测信道匹配[J].声学学报,2021,46(6):800-812. 被引量：1

二级引证文献39

1张培珍,莫秉戈,王斌.拓展的衍射CT技术反演多孔性海底声学参数[J].吉林大学学报（地球科学版）,2019,49(6):1788-1794.
2刘炎堃,郭永刚,李整林,李风华,张波.基于路径选择的深海水下运动目标被动深度估计[J].应用声学,2020,39(5):647-655. 被引量：4
3张旭,李智生.大范围海域多站纯方位定位精度分布特性估计[J].信号处理,2020,36(12):2052-2060. 被引量：2
4李国富,张爽,齐占峰,魏永星,周莹,于金花,常哲,秦玉峰.拖曳声源深度起伏对深海会聚区声传播损失测量的影响[J].海洋技术学报,2020,39(5):58-63. 被引量：1
5谢亮,王鲁军,林旺生.深海脉冲信号簇到达结构特征及其在水下声源定位中的应用[J].声学学报,2021,46(2):171-181. 被引量：10
6姚琦海,汪勇,黎佳艺,杨益新.基于广义回归神经网络的强干扰下垂直阵目标距离估计方法[J].应用声学,2021,40(5):723-730. 被引量：7
7胡平,彭朝晖,李整林.浅海内波环境下声场时间相关特性[J].应用声学,2021,40(5):731-737.
8朱方伟,郑广赢,刘福臣.基于深海海底反射区匹配到达结构的声源深度估计方法[J].哈尔滨工程大学学报,2021,42(10):1510-1517. 被引量：2
9薛城,宫在晓,顾怡鸣,王域,林鹏,李整林.结合卷积神经网络的浅海有源探测信道匹配[J].声学学报,2021,46(6):800-812. 被引量：1
10李悦,马晓川,刘宇,王磊,李璇,魏润宇.非等声速信道下的循环神经网络机动目标跟踪模型[J].声学学报,2021,46(6):1013-1027. 被引量：1

1樊飞,李达,王维玉,李仕良.光纤传感器在深基坑监测中的应用[J].华北地震科学,2015,33(A01):48-51. 被引量：3
2李新平,ZHAO Hang,WANG Bin,XIAO Taoli.Mechanical Properties of Deep-buried Marble Material Under Loading and Unloading Tests[J].Journal of Wuhan University of Technology(Materials Science),2013,28(3):514-520. 被引量：2
3黄吉.剧院魔方[J].数码设计（surface）,2010(4):62-63.
4郭晓乐,杨坤德,马远良,杨秋龙.Geoacoustic Inversion Based on Modal Dispersion Curve for Range-Dependent Environment[J].Chinese Physics Letters,2015,32(12):74-77.
5Common Declaration on the Protection of Cultural Heritage in the Maritime Silk Road of South China Sea Released[J].China & The World Cultural Exchange,2014,80(7):5-6.
6徐结海.关于小型宾馆程控交换通信系统的设计分析[J].科技创新与应用,2013,3(36):76-76. 被引量：2
7冯亦博.浅谈建筑供配电节能[J].科技视界,2015(12):237-238.
8霍坤炳.光纤熔接技术[J].有线电视技术,2008,15(11):85-86. 被引量：3
9李希武.光纤接续损耗监控和测量方法分析及对比[J].今日科苑,2008(14):73-74.
10Nor Antonina Abdullah,Noor Azhar Mohd Shazili,Rosnan Yaacob,Kamaruzzaman Yunus.Grain Size and Metallic Trace Element Contents in Sediments of Kemaman Coast, Terengganu, Malaysia, South China Sea[J].Journal of Earth Science and Engineering,2014,4(2):80-87.

Chinese Physics Letters

2015年第12期

浏览历史

内容加载中请稍等...

Geoacoustic Inversion for Bottom Parameters in the Deep-Water Area of the South China Sea 被引量：13

参考文献14

同被引文献89

引证文献13

二级引证文献39

相关作者

相关机构

相关主题

浏览历史