Title :
Secular behavior and breakdown of chaotic ray solutions
Author :
Collins, Michael D. ; Lingevitch, Joseph F.
Author_Institution :
Naval Res. Lab., Washington, DC, USA
fDate :
4/1/1999 12:00:00 AM
Abstract :
Solutions of the eikonal equation and the first two transport equations are derived for problems involving ray chaos. The solution of the eikonal equation approximates the phase. The solutions of the transport equations approximate the amplitude as an asymptotic series in ω-1. Examples are presented to illustrate that the second term in the series grows relative to the first term along some rags. This secular behavior is associated with the exponential decay of amplitude, which occurs along chaotic rays. The results suggest that chaotic ray solutions (including ray paths, phases, and amplitudes) break down rapidly with range. Although the analysis is limited to a special case that is free of caustics, the results bring into question the use of chaotic ray solutions for long-range propagation
Keywords :
Helmholtz equations; acoustic intensity; acoustic tomography; chaos; geometrical acoustics; inhomogeneous media; nonlinear acoustics; underwater acoustic propagation; Helmholtz equation; acoustic pressure; asymptotic series; breakdown; caustics; chaotic ray solutions; eikonal equation; exponential decay of amplitude; long-range propagation; ocean acoustic tomography; ray amplitudes; ray chaos; ray paths; ray phases; secular behavior; transport equations; Acoustic propagation; Chaos; Electric breakdown; Equations; Frequency; Helium; Oceans; Optimization methods; Tomography;
Journal_Title :
Oceanic Engineering, IEEE Journal of
