%0 Journal Article %1 1457032 %A Flatte, S.M. %D 1983 %J Proceedings of the IEEE %K acoustic_wave oscillations random_environment random_media %N 11 %P 1267-1294 %R 10.1109/PROC.1983.12764 %T Wave propagation through random media: Contributions from ocean acoustics %V 71 %X Recent theoretical and experimental progress in understanding sound transmission through a random field of internal waves is reviewed. Some attempt is made to place this work in historical relation to similar efforts in radio-wave propagation through the ionosphere and light propagation through the atmosphere. It is emphasized that internal waves as a random medium possess several new features unfamiliar to those dealing with homogeneous isotropic turbulence. The effect of a background deterministic wave-speed variation (the ocean sound channel) is central to the theoretical treatment, which is based on a path-integral solution of the parabolic wave equation. A distinction is made between two sections of the saturated region and some emphasis is placed on the region of partial saturation. Comparison with experiment is discussed with examples from the two-point mutual coherence function of time, frequency, and vertical separation; the intensity correlation in time, frequency, and vertical separation; the spectra of phase and log intensity, pulse propagation, and the higher moments of intensity.

@article{1457032, abstract = {Recent theoretical and experimental progress in understanding sound transmission through a random field of internal waves is reviewed. Some attempt is made to place this work in historical relation to similar efforts in radio-wave propagation through the ionosphere and light propagation through the atmosphere. It is emphasized that internal waves as a random medium possess several new features unfamiliar to those dealing with homogeneous isotropic turbulence. The effect of a background deterministic wave-speed variation (the ocean sound channel) is central to the theoretical treatment, which is based on a path-integral solution of the parabolic wave equation. A distinction is made between two sections of the saturated region and some emphasis is placed on the region of partial saturation. Comparison with experiment is discussed with examples from the two-point mutual coherence function of time, frequency, and vertical separation; the intensity correlation in time, frequency, and vertical separation; the spectra of phase and log intensity, pulse propagation, and the higher moments of intensity.}, added-at = {2014-05-13T16:23:15.000+0200}, author = {Flatte, S.M.}, biburl = {https://www.bibsonomy.org/bibtex/2dbb403464f7b73f712cea8693e6e12c9/peter.ralph}, description = {In this field, the Green function is composed of ratios of "ray tube functions".}, doi = {10.1109/PROC.1983.12764}, interhash = {dfe97237239bfe32f457b9c0d16201f8}, intrahash = {dbb403464f7b73f712cea8693e6e12c9}, issn = {0018-9219}, journal = {Proceedings of the IEEE}, keywords = {acoustic_wave oscillations random_environment random_media}, month = nov, number = 11, pages = {1267-1294}, timestamp = {2014-05-13T16:23:15.000+0200}, title = {Wave propagation through random media: Contributions from ocean acoustics}, volume = 71, year = 1983 }