Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water

Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water

This work is concerned with the characteristics of very low frequency sound propagation (VLF, ≤100 Hz) in the shallow marine environment. Under these conditions, the classical hypothesis of considering the sea bottom as a fluid environment is no longer appropriate, and the sound propagation characte...

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Main Authors: Nansong Li, Hanhao Zhu, Xiaohan Wang, Rui Xiao, Yangyang Xue, Guangxue Zheng
Format: Article
Language:English
Published: MDPI AG 2021-12-01
Series:Sensors
Subjects:
very low frequency (VLF)
sound propagation characteristic
full waveguides
finite element method (FEM)
fluid/elastic interaction
Online Access:https://www.mdpi.com/1424-8220/21/1/192
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spelling doaj-5498da25616a49538296c572a8f7f5a72020-12-31T00:02:46ZengMDPI AGSensors1424-82202021-12-012119219210.3390/s21010192Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow WaterNansong Li0Hanhao Zhu1Xiaohan Wang2Rui Xiao3Yangyang Xue4Guangxue Zheng5Acoustic Science and Technology Laboratory, Harbin Engineering University, Harbin 150001, ChinaInstitute of Marine Science and Technology, Zhejiang Ocean University, Zhoushan 316022, ChinaAcoustic Science and Technology Laboratory, Harbin Engineering University, Harbin 150001, ChinaInstitute of Naval Architecture and Mechanical-Electrical Engineering, Zhejiang Ocean University, Zhoushan 316022, ChinaInstitute of Naval Architecture and Mechanical-Electrical Engineering, Zhejiang Ocean University, Zhoushan 316022, ChinaAcoustic Science and Technology Laboratory, Harbin Engineering University, Harbin 150001, ChinaThis work is concerned with the characteristics of very low frequency sound propagation (VLF, ≤100 Hz) in the shallow marine environment. Under these conditions, the classical hypothesis of considering the sea bottom as a fluid environment is no longer appropriate, and the sound propagation characteristics at the sea bottom should be also considered. Hence, based on the finite element method (FEM), and setting the sea bottom as an elastic medium, a proposed model which unifies the sea water and sea bottom is established, and the propagation characteristics in full waveguides of shallow water can be synchronously discussed. Using this model, the effects of the sea bottom topography and the various geoacoustic parameters on VLF sound propagation and its corresponding mechanisms are investigated through numerical examples and acoustic theory. The simulation results demonstrate the adaptability of the proposed model to complex shallow water waveguides and the accuracy of the calculated acoustic field. For the sea bottom topography, the greater the inclination angle of an up-sloping sea bottom, the stronger the leak of acoustic energy to the sea bottom, and the more rapid the attenuation of the acoustic energy in sea water. The effect of a down-sloping sea bottom on acoustic energy is the opposite. Moreover, the greater the pressure wave (P-wave) speed in the sea bottom, the more acoustic energy remains in the water rather than leaking into the bottom; the influence laws of the density and the shear wave (S-wave) speed in the sea bottom are opposite.https://www.mdpi.com/1424-8220/21/1/192very low frequency (VLF)sound propagation characteristicfull waveguidesfinite element method (FEM)fluid/elastic interaction
collection DOAJ
language English
format Article
sources DOAJ
author Nansong Li
Hanhao Zhu
Xiaohan Wang
Rui Xiao
Yangyang Xue
Guangxue Zheng
spellingShingle Nansong Li
Hanhao Zhu
Xiaohan Wang
Rui Xiao
Yangyang Xue
Guangxue Zheng
Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
Sensors
very low frequency (VLF)
sound propagation characteristic
full waveguides
finite element method (FEM)
fluid/elastic interaction
author_facet Nansong Li
Hanhao Zhu
Xiaohan Wang
Rui Xiao
Yangyang Xue
Guangxue Zheng
author_sort Nansong Li
title Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
title_short Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
title_full Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
title_fullStr Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
title_full_unstemmed Characteristics of Very Low Frequency Sound Propagation in Full Waveguides of Shallow Water
title_sort characteristics of very low frequency sound propagation in full waveguides of shallow water
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2021-12-01
description This work is concerned with the characteristics of very low frequency sound propagation (VLF, ≤100 Hz) in the shallow marine environment. Under these conditions, the classical hypothesis of considering the sea bottom as a fluid environment is no longer appropriate, and the sound propagation characteristics at the sea bottom should be also considered. Hence, based on the finite element method (FEM), and setting the sea bottom as an elastic medium, a proposed model which unifies the sea water and sea bottom is established, and the propagation characteristics in full waveguides of shallow water can be synchronously discussed. Using this model, the effects of the sea bottom topography and the various geoacoustic parameters on VLF sound propagation and its corresponding mechanisms are investigated through numerical examples and acoustic theory. The simulation results demonstrate the adaptability of the proposed model to complex shallow water waveguides and the accuracy of the calculated acoustic field. For the sea bottom topography, the greater the inclination angle of an up-sloping sea bottom, the stronger the leak of acoustic energy to the sea bottom, and the more rapid the attenuation of the acoustic energy in sea water. The effect of a down-sloping sea bottom on acoustic energy is the opposite. Moreover, the greater the pressure wave (P-wave) speed in the sea bottom, the more acoustic energy remains in the water rather than leaking into the bottom; the influence laws of the density and the shear wave (S-wave) speed in the sea bottom are opposite.
topic very low frequency (VLF)
sound propagation characteristic
full waveguides
finite element method (FEM)
fluid/elastic interaction
url https://www.mdpi.com/1424-8220/21/1/192
work_keys_str_mv AT nansongli characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
AT hanhaozhu characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
AT xiaohanwang characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
AT ruixiao characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
AT yangyangxue characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
AT guangxuezheng characteristicsofverylowfrequencysoundpropagationinfullwaveguidesofshallowwater
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