Sound Propagation Through Directional Internal Wave Fields
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| Author | : J. A. Neubert |
| Publisher | : |
| Total Pages | : 25 |
| Release | : 1984 |
| Genre | : |
| ISBN | : |
Acoustic propagation can be used to discern directional internal waves in ambient ocean internal wave fields. The Rytov method gives the mean square sound-level fluctuations and the mean square phase fluctuations as a function for the fluctuating component of the refractive index. These relations are valid throughout the unsaturated regime of sound fluctuations. The propagating vertical displacement of the directional internal wave field is formed, and from its correlation lengths the necessary correlation lengths the necessary correlation function can be obtained. Thence, for the directional internal wave field are found. Next and for expected horizontally isotropic ambient internal wave field are determined by manipulation of the Garrett and Munk spectrum. This technique can be applied to the detection of a directional internal wave in a background field of horizontally isotropic ambient internal waves as shown in the example. Keywords include: underwater acoustics, Acoustic propagation, Rytov method.
| Author | : Mark Lewis Grabb |
| Publisher | : |
| Total Pages | : 354 |
| Release | : 1996 |
| Genre | : |
| ISBN | : |
| Author | : |
| Publisher | : |
| Total Pages | : 728 |
| Release | : 1994 |
| Genre | : Aeronautics |
| ISBN | : |
| Author | : Igor Chunchuzov |
| Publisher | : Cambridge Scholars Publishing |
| Total Pages | : 355 |
| Release | : 2020-02-28 |
| Genre | : Science |
| ISBN | : 1527547760 |
This book presents the theory and results of experimental studies of the propagation of infrasound waves in a real atmosphere with its inherent fine-scale layered structure of wind speed and temperature. It is motivated by the fact that the statistical characteristics of anisotropic (or layered) fluctuations of meteorological fields, the horizontal scales of which significantly exceed their vertical scales, have been very poorly studied compared to those of locally isotropic turbulence in the inertial range of scales. This book addresses this lacuna by developing a theory of the formation of anisotropic inhomogeneities of the atmosphere in a random field of internal gravity waves and vortex structures. Using theory, it explains numerous experimental data depicting the influence of the fine structure of the atmosphere on the propagation of infrasound waves from pulsed sources. The text will appeal to specialists in the fields of acoustics and optics of the atmosphere, remote sensing of the atmosphere, the dynamics of internal waves, nonlinear acoustics, and infrasound monitoring of explosions and natural hazards.
| Author | : |
| Publisher | : |
| Total Pages | : 11 |
| Release | : 2005 |
| Genre | : |
| ISBN | : |
A stably stratified atmosphere supports propagation of internal gravity waves (IGW). These waves result in highly anisotropic fluctuations in temperature and wind velocity that are stretched in a horizontal direction. As a result, (IGW) can significantly affect propagation of sound waves in nighttime boundary layers and infrasound waves in the stratosphere. In this paper, a theory of sound propagation through, and scattering by, (IGW) is developed. First, 3D spectra of temperature and wind velocity fluctuations due to (IGW), which were recently derived in the literature for the case of large wave numbers, are generalized to account for small wave numbers. The generalized 3D spectra are then used to calculate the sound scattering cross section in an atmosphere with (IGW). The dependencies of the obtained scattering cross section on the sound frequency, scattering angle, and other parameters of the problem are qualitatively different from those for the case of sound scattering by isotropic turbulence with the von K rm n spectra of temperature and wind velocity fluctuations. Furthermore, the generalized 3D spectra are used to calculate the mean sound field and the transverse coherence function of a plane sound wave propagating through (IGW). The results obtained also significantly differ from those for the case of sound propagation through isotropic turbulence.
| Author | : Alexey Alexandrovich Shmelev |
| Publisher | : |
| Total Pages | : 193 |
| Release | : 2011 |
| Genre | : Acoustic models |
| ISBN | : |
This thesis describes the physics of fully three-dimensional low frequency acoustic interaction with internal waves, bottom sediment waves and surface swell waves that are often observed in shallow waters and on continental slopes. A simple idealized model of the ocean waveguide is used to analytically study the properties of acoustic normal modes and their perturbations due to waves of each type. The combined approach of a semi-quantitative study based on the geometrical acoustics approximation and on fully three-dimensional coupled mode numerical modeling is used to examine the azimuthal dependence of sound wave horizontal reflection from, transmission through and ducting between straight parallel waves of each type. The impact of the natural crossings of nonlinear internal waves on horizontally ducted sound energy is studied theoretically and modeled numerically using a three-dimensional parabolic equation acoustic propagation code. A realistic sea surface elevation is synthesized from the directional spectrum of long swells and used for three-dimensional numerical modeling of acoustic propagation. As a result, considerable normal mode amplitude scintillations were observed and shown to be strongly dependent on horizontal azimuth, range and mode number. Full field numerical modeling of low frequency sound propagation through large sand waves located on a sloped bottom was performed using the high resolution bathymetry of the mouth of San Francisco Bay. Very strong acoustic ducting is shown to steer acoustic energy beams along the sand wave's curved crests.
| Author | : John A. Colosi |
| Publisher | : Cambridge University Press |
| Total Pages | : 443 |
| Release | : 2016-06-20 |
| Genre | : Mathematics |
| ISBN | : 1107072344 |
In this book, key discoveries in the field of statistical ocean acoustics over the last 35 years are addressed with illustrations from ocean observations.
| Author | : Denis Makarov |
| Publisher | : World Scientific |
| Total Pages | : 412 |
| Release | : 2010 |
| Genre | : Science |
| ISBN | : 9814273171 |
A systematic study of chaotic ray dynamics in underwater acoustic waveguides began in the mid-1990s when it was realized that this factor plays a crucial role in long-range sound propagation in the ocean. The phenomenon of ray chaos and its manifestation at a finite wavelength ? wave chaos ? have been investigated by combining methods from the theory of wave propagation and the theory of dynamical and quantum chaos. This book is the first monograph summarizing results obtained in this field. Emphasis is made on the exploration of ray and modal structures of the wave field in an idealized environmental model with periodic range dependence and in a more realistic model with sound speed fluctuations induced by random internal waves. The book is intended for acousticians investigating the long-range sound transmission through the fluctuating ocean and also for researchers studying waveguide propagation in other media. It will be of major interest to scientists working in the field of dynamical and quantum chaos.
| Author | : Stanley M. Flatté |
| Publisher | : |
| Total Pages | : 73 |
| Release | : 1975 |
| Genre | : Internal waves |
| ISBN | : |
The signal received by a hydrophone in the ocean many kilometers from a steady sound source fluctuates dramatically due to variations of the speed of sound in sea-water. A computer code that simulates the passage of acoustic CW signals through an ocean with internal waves is written. The code generates a sound-speed field from an internal-wave spectrum that has been derived from oceanographic measurements. The acoustic propagation is achieved through the use of the parabolic-equation approximation. The code is limited fundamentally to acoustic frequencies above approximately 10 Hz, and by practical computer-time constraints to frequencies below approximately 400 Hz. The code allows the calculation of the amplitude and phase of the full acoustic field as a function of depth and range at any desired time. (Author).
| Author | : Boris Katsnelson |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 549 |
| Release | : 2012-02-22 |
| Genre | : Science |
| ISBN | : 1441997768 |
Shallow water acoustics (SWA), the study of how low and medium frequency sound propagates and scatters on the continental shelves of the worlds oceans, has both technical interest and a large number of practical applications. Technically, shallow water poses an interesting medium for the study of acoustic scattering, inverse theory, and propagation physics in a complicated oceanic waveguide. Practically, shallow water acoustics has interest for geophysical exploration, marine mammal studies, and naval applications. Additionally, one notes the very interdisciplinary nature of shallow water acoustics, including acoustical physics, physical oceanography, marine geology, and marine biology. In this specialized volume the authors, all of whom have extensive at-sea experience in US and Russian research efforts, have tried to summarize the main experimental, theoretical, and computational results in shallow water acoustics, with an emphasis on providing physical insight into the topics presented.
