Random matrix theory for description of sound scattering on background internal waves in a shallow sea

Q3 Earth and Planetary Sciences
D. V. Makarov, E. V. Sosedko
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引用次数: 0

Abstract

The problem of propagation of low-frequency sound in a shallow waveguide with random hydrological inhomogeneity caused by background internal waves is considered. A new approach to statistical modeling of acoustic fields, based on the application of the random matrix theory and previously successfully used for deep-water acoustic waveguides, is used to the case of shallow-water waveguides. In this approach, sound scattering on random inhomogeneity is described using an ensemble of random propagator matrices which describe the transformation of the acoustic field in the space of normal waveguide modes. A study of the effect of sound “escaping” from a waveguide was carried out. The term “escaping” here means energy transfer to modes with stronger attenuation due to scattering on internal waves. A model of an underwater sound channel with an axis at a depth of about 45 meters is considered. It is shown that the first few modes propagating inside the water column are very little subject to losses due to the “escaping”. The strongest impact of the leakage scattering is experienced by the middle group of modes capable of reaching the sea surface. It is revealed as significant increasing of losses as compared to a horizontally homogeneous waveguide. On the other hand, the existence of linear mode combinations for which loss enhancement is practically absent has been revealed. These linear combinations correspond to the eigenfunctions of an inhomogeneous waveguide. Statistical analysis of propagator eigenfunctions indicates on qualitative differences of mechanisms of scattering for frequencies of 100 and 500 Hz.
浅海背景内波声散射的随机矩阵理论描述
研究了由背景内波引起的随机水文非均匀性的浅波导中低频声的传播问题。将随机矩阵理论应用于深水声波导的一种新的声场统计建模方法应用于浅水声波导。在这种方法中,声音在随机非均匀性上的散射是用随机传播矩阵的集合来描述的,这些矩阵描述了声场在正常波导模式空间中的变换。对声音从波导中“逃逸”的影响进行了研究。术语“逃逸”在这里是指能量转移到具有更强的衰减模式,由于散射在内波。考虑了一个轴深约为45米的水声通道模型。结果表明,在水柱内部传播的前几个模态由于“逸出”而受到的损失很小。泄漏散射的影响最大的是能够到达海面的中间模态组。结果表明,与水平均匀波导相比,其损耗显著增加。另一方面,揭示了几乎不存在损耗增强的线性模态组合的存在。这些线性组合对应于非均匀波导的本征函数。对传播子特征函数的统计分析表明,在100 Hz和500 Hz频率下,散射机制存在质的差异。
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来源期刊
Fundamentalnaya i Prikladnaya Gidrofizika
Fundamentalnaya i Prikladnaya Gidrofizika Earth and Planetary Sciences-Geophysics
CiteScore
1.20
自引率
0.00%
发文量
0
期刊介绍: Emphasis of the journal includes the following areas:‎ ‎- fundamental and applied hydrophysics;‎ ‎- dynamics and hydrodynamics of marine objects;‎ ‎- physical fields of ocean, atmosphere, marine objects and their interaction;‎ ‎- methods and means for registration hydrophysical fields of ocean and marine objects;‎ ‎- application of information technology for solving problems in the field of hydrophysics, design ‎‎and operation of the offshore facilities system;‎ ‎- hydrosphere ecology;‎ ‎- hydrobionics;‎ As well as the most interesting scientific conferences’ reports, materials of science debates, book ‎‎reviews. From the scientists, engineers (and designers) of marine equipment, students, graduate ‎‎students and professors who specialize in the field of fundamental and applied hydrophysics.‎
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