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G Bal (2005)
10.1016/j.wavemoti.2005.08.002Wave Motion, 43
A K Dolzhikov (1984)
Hydroacoustical Methods of Study and Mastering of Ocean
A Ishimaru (1978)
Wave Propagation and Scattering in Random Media
I P Yarovenko I V Prokhorov (2006)
10.1134/S0030400X0611018XOpt. Spectr., 101
I P Yarovenko I V Prokhorov (2008)
10.1088/0266-5611/24/2/025019Inverse Problems, 24
(2009)
Pribory, No. 12
C S Clay (1977)
Fundamentals of Acoustical Oceanography
(1999)
A Thesis for the Degree Master of Science in Electrical Engineering
L. V. Kiselev M. D. Ageev (2005)
[in Russian]
A S Kolchedantsev (1982)
Hydroacoustical Stations
A N Ivakin (2012)
10.1134/S1063771012020066Acoust. Phys., 58
I P Yarovenko I V Prokhorov (2010)
10.1070/QE2010v040n01ABEH014089Quantum Electronics, 40
(2006)
Gidroakust. Zh., No. 3
Abstract The theoretical aspects of constructing hydrolocation images in a fluctuating ocean are considered. Using radiative transfer theory, an inverse problem of determining the bottom scattering coefficient is investigated. The explicit solution to the inverse problem is derived in the single-scattering approximation. The results of theoretical and numerical analyses of the impact of volume scattering on the quality of hydrolocation images are presented.
Acoustical Physics – Springer Journals
Published: May 1, 2015
Keywords: Acoustics
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