浅海环境水声传播数据实测与仿真分析
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摘要
搭建了一套水下录音记录系统,在复杂浅海环境进行了水声数据采集实验;对于水声采集数据进行了距离、频率谱分析,利用MIT开发的声学计算程序OASES针对声场进行了仿真分析。通过模拟结果和实测结果的比较,优化调整仿真程序的环境参数,分析发现影响声场分布的主要因素为沉积层压缩波声速与声源深度。通过这种方式,优化了仿真软件的环境参数,初步建立了比较准确的浅海水声环境仿真模型,取得了预期实验效果。
In this paper,an underwater acoustic data acquisition test is conducted in complex shallow water environment by building an underwater recording system.Distance and frequency spectrum analysis of underwater acoustic data acquisition is carried out,and simulation analysis of sound field is carried out by using the acoustic calculation program OASES developed by MIT.By comparing the simulation results with the measured results,the environmental parameters of the simulation program are adjusted continuously.It is found that the main factors affecting the distribution of sound field are sound velocity of compressed wave in sedimentary layer and the depth of sound source.In this way,the environmental parameters of the simulation software are optimized,and a relatively accurate shallow water acoustic environment simulation model is preliminarily established,and the test results are achieved.
In this paper,an underwater acoustic data acquisition test is conducted in complex shallow water environment by building an underwater recording system.Distance and frequency spectrum analysis of underwater acoustic data acquisition is carried out,and simulation analysis of sound field is carried out by using the acoustic calculation program OASES developed by MIT.By comparing the simulation results with the measured results,the environmental parameters of the simulation program are adjusted continuously.It is found that the main factors affecting the distribution of sound field are sound velocity of compressed wave in sedimentary layer and the depth of sound source.In this way,the environmental parameters of the simulation software are optimized,and a relatively accurate shallow water acoustic environment simulation model is preliminarily established,and the test results are achieved.
引文
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[3] 田坦,刘国枝,孙大军.声呐技术[M].哈尔滨:哈尔滨工程大学出版社,2004.
[4] 潘长明,高飞,孙磊,等.浅海温跃层对水声传播损失场的影响[J].哈尔滨工程大学学报,2014,35(4):312-318.
[5] 高飞,潘长明,孙磊,等.浅海环境不确定性对声场扰动的影响[J].声学技术.2017,36(4):309-314.
[6] 屈科,胡长青,赵梅.浅海海底单参数快速反演模型研究[J].声学技术,2011,31(2):152-155.
[7] 程广利,胡金华,张明敏.浅海声场对不确定环境参数的灵敏度分析方法[J].兵工学报.2014,35(4):567-571.
[8] 笪良龙.海洋水声环境效应建模与应用[M].北京:科学出报社,2012.
[9] 赵梅,胡长青.浅海负跃层海底单参数模型研究[J].声学技术.2015,34(2):103-108.
[10] 赵航芳,李建龙,宫先仪.不确实海洋中最小方差匹配场波束形成对环境参量失配的灵敏性分析[J].哈尔滨工程大学学报,2011,32(2):200-208.
[11] 杨坤德,马远良.利用海底反射信号进行地声参数反演的方法[J].物理学报.2009,58(3):1798-1805.
[12] 何呈,赵安邦,王谋业.浅海声传播及多途信号分解[J].系统工程与电子技术.2016,38(8):1922-1928.
[2] Tang Dajun.Inverting for sandy sediment sound speed in very shallow water using boat noise[J].The Journal of the Acoustical Society of America,2005,117(4):2503-2523.
[3] 田坦,刘国枝,孙大军.声呐技术[M].哈尔滨:哈尔滨工程大学出版社,2004.
[4] 潘长明,高飞,孙磊,等.浅海温跃层对水声传播损失场的影响[J].哈尔滨工程大学学报,2014,35(4):312-318.
[5] 高飞,潘长明,孙磊,等.浅海环境不确定性对声场扰动的影响[J].声学技术.2017,36(4):309-314.
[6] 屈科,胡长青,赵梅.浅海海底单参数快速反演模型研究[J].声学技术,2011,31(2):152-155.
[7] 程广利,胡金华,张明敏.浅海声场对不确定环境参数的灵敏度分析方法[J].兵工学报.2014,35(4):567-571.
[8] 笪良龙.海洋水声环境效应建模与应用[M].北京:科学出报社,2012.
[9] 赵梅,胡长青.浅海负跃层海底单参数模型研究[J].声学技术.2015,34(2):103-108.
[10] 赵航芳,李建龙,宫先仪.不确实海洋中最小方差匹配场波束形成对环境参量失配的灵敏性分析[J].哈尔滨工程大学学报,2011,32(2):200-208.
[11] 杨坤德,马远良.利用海底反射信号进行地声参数反演的方法[J].物理学报.2009,58(3):1798-1805.
[12] 何呈,赵安邦,王谋业.浅海声传播及多途信号分解[J].系统工程与电子技术.2016,38(8):1922-1928.
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