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Wave and extra-wide-angle parabolic equations for sound propagation in a moving atmosphere

Vladimir E. Ostashev, D. Keith Wilson, Michael B. Muhlestein

2020The Journal of the Acoustical Society of America34 citationsDOI

Abstract

The narrow-angle parabolic equation (NAPE) with the effective sound speed approximation (ESSA) is widely used for sound and infrasound propagation in a moving medium such as the atmosphere. However, it is valid only for angles less than 20° with respect to the nominal propagation direction. In this paper, the wave equation and extra-wide-angle parabolic equation (EWAPE) for high-frequency (short-wavelength) sound waves in a moving medium with arbitrary Mach numbers are derived without the ESSA. For relatively smooth variations in the medium velocity, the EWAPE is valid for propagation angles up to 90°. Using the Padé (n,n) series expansion and narrow-angle approximation, the EWAPE is reduced to the wide-angle parabolic equation (WAPE) and NAPE. Versions of these equations are then formulated for low Mach numbers, which is the case that is usually considered in the literature. The phase errors pertinent to the equations considered are studied. It is shown that the equations for low Mach numbers and the WAPE with the ESSA are applicable only under rather restrictive conditions on the medium velocity. An effective numerical implementation of the WAPE for arbitrary Mach numbers in the Padé (1,1) approximation is developed and applied to sound propagation in the atmosphere.

Topics & Concepts

Mach numberMach waveMathematical analysisSpeed of soundWave propagationPhysicsParabolic partial differential equationWave equationWavenumberPhase velocityMathematicsMechanicsAcousticsOpticsPartial differential equationUnderwater Acoustics ResearchSeismic Waves and AnalysisAcoustic Wave Phenomena Research
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