Recursive Bayesian synthetic aperture geoacoustic inversion in the presence of motion dynamics

TitleRecursive Bayesian synthetic aperture geoacoustic inversion in the presence of motion dynamics
Publication TypeJournal Article
Year of Publication2014
AuthorsTan B.A, Gerstoft P, Yardim C, Hodgkiss WS
JournalJournal of the Acoustical Society of America
Date Published2014/09
Type of ArticleArticle
ISBN Number0001-4966
Accession NumberWOS:000342205700031
Keywordsenvironment; field; impulse-response; oceanic wave-guide; parameter-estimation; shallow-water; single hydrophone; source localization; uncertainty; underwater acoustics inversion

A low signal to noise ratio (SNR), single source/receiver, broadband, frequency-coherent matched-field inversion procedure recently has been proposed. It exploits coherently repeated transmissions to improve estimation of the geoacoustic parameters. The long observation time improves the SNR and creates a synthetic aperture due to relative source-receiver motion. To model constant velocity source/receiver horizontal motion, waveguide Doppler theory for normal modes is necessary. However, the inversion performance degrades when source/receiver acceleration exists. Furthermore processing a train of pulses all at once does not take advantage of the natural incremental acquisition of data along with the ability to assess the temporal evolution of parameter uncertainty. Here a recursive Bayesian estimation approach is developed that coherently processes the data pulse by pulse and incrementally updates estimates of parameter uncertainty. It also approximates source/receiver acceleration by assuming piecewise constant but linearly changing source/receiver velocities. When the source/receiver acceleration exists, it is shown that modeling acceleration can reduce further the parameter estimation biases and uncertainties. The method is demonstrated in simulation and in the analysis of low SNR, 100-900 Hz linear frequency modulated (LFM) pulses from the Shallow Water 2006 experiment. (C) 2014 Acoustical Society of America.

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