Modeling Acoustical Pressure and Particle Acceleration Close to Marine Seismic Airguns and Airgun Arrays

Comparisons are made of sound pressure and particle acceleration predicted by two methods in the vicinity of two arrays of marine-seismic airguns. Data describing the array properties and the environmental conditions are taken from test cases designed to facilitate intermodel comparison. The two pro...

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Veröffentlicht in:IEEE journal of oceanic engineering 2019-07, Vol.44 (3), p.611-620
Hauptverfasser: Prior, Mark K., Duncan, Alexander J., Ozkan Sertlek, H., Ainslie, Michael A.
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creator Prior, Mark K.
Duncan, Alexander J.
Ozkan Sertlek, H.
Ainslie, Michael A.
description Comparisons are made of sound pressure and particle acceleration predicted by two methods in the vicinity of two arrays of marine-seismic airguns. Data describing the array properties and the environmental conditions are taken from test cases designed to facilitate intermodel comparison. The two propagation approaches, one based on method of images and the other on wave number integration, are shown to be capable of giving line-on-line agreement when the latter method implements the full form of the Hankel transform; when the more approximate Fourier transform is used, predictions are shown to differ at ranges of a few meters from the source.
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subjects Acceleration
Acoustic propagation
airgun
Arrays
Atmospheric modeling
Data models
Environmental conditions
Fourier transforms
Linear particle accelerator
marine-seismic
Measuring instruments
Method of images
Particle acceleration
Predictions
Predictive models
pressure waveform
Receivers
Sound pressure
Surface waves
Wave number
title Modeling Acoustical Pressure and Particle Acceleration Close to Marine Seismic Airguns and Airgun Arrays
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