Dynamics and Stability of Acoustic Wavefronts in the Ocean

Abstract

To develop a method of modeling sound propagation in an environment with multi-scale inhomogeneities, which preserves the efficiency and intuitive qualities of the ray theory but is free from spurious environmental sensitivity and strong perturbations associated with ray trajectories. To investigate and quantify effects on underwater acoustic wavefronts of internal gravity waves, sea swell, spice, and other small-scale processes in the water column. 1. To assess significance of time dependence of the sound speed and flow velocity perturbations on predictability of acoustic wavefronts and timefronts. 2. To quantify horizontal refraction of sound by random meso-scale inhomogeneities at O(1)Mm propagation ranges. 3. To find the variance and bias of random ray travel times in the regime, where the ray displacement may be comparable to the vertical extent of the underwater waveguide but the clustering has not developed yet. 4. To determine, using a perturbation theory and numerical simulations, typical propagation ranges where clustering of chaotic rays replaces the anisotropy of ray scattering as the main physical mechanism responsible for acoustic wavefront stability. 5. To develop an efficient technique for modeling acoustic wavefronts and their perturbations in range-dependent and horizontally inhomogeneous oceans. 6. To model perturbations of acoustic wavefronts and timefronts by internal gravity waves, internal tides, sea swell, and spice in the ocean. 7. To determine, using a perturbation theory and full-wave numerical simulations, the range of acoustic frequencies where diffusion along the wavefront overtakes the anisotropy of ray scattering as the main physical mechanism responsible for acoustic wavefront stability. 8. To investigate implications of wavefront stability on the downward extension of acoustic timefronts and deepening of lower turning points of steep rays due to small- and meso-scale physical processes in the upper ocean.

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Document Details

Document Type
Technical Report
Publication Date
Sep 01, 2011
Accession Number
ADA571641

Entities

People

  • Oleg A. Godin

Organizations

  • University of Colorado Boulder

Tags

Communities of Interest

  • Air Platforms

DTIC Thesaurus Topics

  • Acoustic Frequencies
  • Acoustic Propagation
  • Acoustic Waves
  • Acoustics
  • Differential Equations
  • Diffraction
  • Equations
  • Gravity Waves
  • Perturbation Theory
  • Physics
  • Scattering
  • Simulations
  • Three Dimensional
  • Travel Time
  • Two Dimensional
  • Wave Equations
  • Wavefronts

Fields of Study

  • Physics

Readers

  • Atmospheric Science / Meteorology, specifically Wind Wave Turbulence.
  • Wave Propagation and Nonlinear Chaotic Dynamics.