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http://dx.doi.org/10.1016/j.ijnaoe.2020.07.008

A hybrid algorithm of underwater structure vibration and acoustic radiation-propagation in ocean acoustic channel  

Duan, Jia-xi (Naval Submarine Academy)
Zhang, Lin (Naval Submarine Academy)
Da, Liang-long (Naval Submarine Academy)
Sun, Xue-hai (Naval Submarine Academy)
Chen, Wen-jing (National Laboratory of Marine Science and Technology)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.12, no.1, 2020 , pp. 680-690 More about this Journal
Abstract
In ocean environment, the sound speed gradient of seawater has an important influence on far field sound propagation. The FEM/BEM is used to decouple the vibroacoustic radiation of the spherical shell, and the Green function of the virtual source chain is adopted for decoupling. For far field radiated Sound Pressure Level (SPL), the Beam Displacement Ray normal Mode (BDRM) is employed. The vibration and near-/far-field radiated SPL of spherical shell is analyzed in shallow sea uniform layer, negative/positive gradient, negative thermocline environment, and deep-sea sound channel. Results show that the vibroacoustic radiation of spherical shell acted at 300Hz can be analogous to dipole. When the radiated field of the spherical shell is dominated by large-grazing-angle waves, it can be analogous to vertically distributed dipole, and the far field radiated SPL is lower; while similar to horizontally distributed dipole if dominated by small-grazing-angle waves, and the far field SPL is high.
Keywords
Sound speed gradient; Elastic structure; Vibration; Acoustic radiation; Sound propagation;
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