Validity of the sonar equation and Babinet’s principle for scattering in a stratified medium

Ratilal, Purnima; Lai, Yisan; Makris, Nicholas C.

doi:10.1121/1.1499136

Cited by 23 publications

(18 citation statements)

References 11 publications

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“…Frequency should also be low enough for the received acoustic field scattered from any given fish to be expressible as the product of the 3 factors 'transmission to the given fish', 'scattering from the fish', and 'transmission from the fish' (Appendix C). At CFFS wavelengths, this factorization is typically not possible because propagation and scattering effects are convolved together in an ocean waveguide (Ratilal et al 2002). Frequencies should be chosen so that acoustic attenuation from propagation through the fish is negligible even over long ranges.…”

Section: Potential Ecosystem Explorationmentioning

confidence: 99%

Ocean Acoustic Waveguide Remote Sensing (OAWRS) of marine ecosystems

Jagannathan¹,

Bertsatos²,

Symonds³

et al. 2009

Mar. Ecol. Prog. Ser.

106

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Ocean Acoustic Waveguide Remote Sensing (OAWRS) has recently been shown to be capable of instantaneously imaging and continuously monitoring fish populations over continental shelf-scale areas, covering thousands of km 2 . We show how OAWRS can be used in a variety of oceanic ecosystems to remotely assess populations and study the behavior of fish and other marine organisms, such as Antarctic krill, to help the study of marine ecology and the ecosystem-based approach to fisheries management.

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Section: Potential Ecosystem Explorationmentioning

confidence: 99%

Ocean Acoustic Waveguide Remote Sensing (OAWRS) of marine ecosystems

Jagannathan¹,

Bertsatos²,

Symonds³

et al. 2009

Mar. Ecol. Prog. Ser.

106

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“…Each incoming mode is composed of one down-going component with amplitude A n (r 0 ) and incident elevation angle α n , and one up-going component with amplitude B n (r 0 ) and incident elevation angle -α n , respectively. Each scattered mode is also composed of a pair of plane waves, the down-going plane wave with amplitude B m (r) and elevation angle α m , the up-going plane wave with amplitude A m (r) and elevation angle -α m [12]. Each of the four terms in eq.…”

Section: Modeling Forward Scattering With Normal Mode Modelmentioning

confidence: 99%

“…The normal mode model [11,12] is employed to simulate the forward scattering field with an object crossing the source-receiver line and a physical interpretation is given. Furthermore, we designed and conducted lake experiments at range-to-depth ratios up to about 190, much farther than reported experiments.…”

mentioning

confidence: 99%

Forward acoustic scattering by moving objects: Theory and experiment

Lei

Yang

et al. 2012

Chin. Sci. Bull.

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The normal mode model for scattering in shallow water is employed to investigate the forward scattering with a target crossing the source-receiver axial line. An experiment was conducted in a littoral environment to analyze forward scattering by a slowly moving object. The theoretical and experimental results show that the sound field aberration takes minimum values if the object is located mid-point along the source-receiver line, whereas it attains its maximum if the object is close to the source or receiver. The total field is either enhanced or suppressed if the object crosses different Fresnel zones. In addition, the duration of shadow-induced aberration is dependent on the width of the first Fresnel zone, which is longest at the mid-point of the source-receiver line.forward scattering, moving object, Fresnel zone, shadow effect, sound field aberration Citation:Lei B, Yang K D, Ma Y L, et al. Forward acoustic scattering by moving objects: Theory and experiment.

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“…Equation ͑2͒ is applicable when the source and receiver ranges are sufficiently far from the target that the plane wave scatter function description is valid. 5,52,54 For a single shell, the incident field has modal plane wave amplitudes given by, 1,5,51…”

Section: Scattered Field Contribution To the Direct Wave From A Smentioning

confidence: 99%

Mean and covariance of the forward field propagated through a stratified ocean waveguide with three-dimensional random inhomogeneities

Ratilal

Makris

2005

The Journal of the Acoustical Society of America

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Compact analytic expressions are derived for the mean, mutual intensity, and spatial covariance of the acoustic field forward propagated though a stratified ocean waveguide containing three-dimensional random surface and volume inhomogeneities. The inhomogeneities need not obey a stationary random process in space, can be of arbitrary composition and size relative to the wavelength, or can have large surface roughness and slope. The form of the mean forward field after multiple scattering through the random waveguide is similar to that of the incident field, except for a complex change in the horizontal wave number of each mode. This change describes attenuation and dispersion induced by the medium's inhomogeneities, including potential mode coupling along the propagation path. The spatial covariance of the forward field between two receivers includes the accumulated effects of both coherent and incoherent multiple forward scattering through the random waveguide. It is expressed as a sum of modal covariance terms. Each term depends on the medium's expected modal extinction densities as well as the covariance of its scattering properties, which potentially couple each mode to every other mode. Three-dimensional scattering effects can become important at ranges where the Fresnel width exceeds the cross-range coherence scale of the medium's inhomogeneities.

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Validity of the sonar equation and Babinet’s principle for scattering in a stratified medium

Cited by 23 publications

References 11 publications

Ocean Acoustic Waveguide Remote Sensing (OAWRS) of marine ecosystems

Ocean Acoustic Waveguide Remote Sensing (OAWRS) of marine ecosystems

Forward acoustic scattering by moving objects: Theory and experiment

Mean and covariance of the forward field propagated through a stratified ocean waveguide with three-dimensional random inhomogeneities

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