Title :
Self-initiating MUSIC-based direction finding in underwater acoustic particle velocity-field beamspace
Author :
Wong, Kainam T. ; Zoltowski, Michael D.
Author_Institution :
Dept. of Electron. Eng., Chinese Univ. of Hong Kong, Shatin, Hong Kong
fDate :
4/1/2000 12:00:00 AM
Abstract :
This paper introduces a novel blind MUSIC-based (MUltiple SIgnal Classification) source localization algorithm applicable to an arbitrarily spaced three-dimensional array of vector hydrophones, each of which comprises two or more co-located and orthogonally oriented velocity hydrophones plus an optional pressure hydrophone. This proposed algorithm: (1) exploits the incident sources´ angular diversity in the underwater acoustic particle velocity field; (2) adaptively forms velocity-field beams at each vector-hydrophone; (3) uses ESPRIT to self-generate coarse estimates of the sources´ arrival angles to start off its MUSIC-based iterative search with no a priori source information; and (4) automatically pairs the x-axis direction-cosine estimates with the y-axis direction-cosine estimates. Simulation results verify the efficacy of this proposed scheme.
Keywords :
acoustic wave interferometry; array signal processing; direction-of-arrival estimation; eigenstructure assignment; hydrophones; iterative methods; signal classification; sonar arrays; sonar signal processing; acoustic interferometry; angular diversity; arbitrarily spaced 3D array; blind MUSIC-based source localization; coarse estimates; colocated hydrophones; data model; eigenstructure method; iterative search; orthogonally oriented hydrophones; pressure hydrophone; self-initiating MUSIC-based direction finding; signal classification; sonar arrays; source localization algorithm; underwater acoustic particle velocity field; vector hydrophones; velocity-field beamforming; x-axis direction-cosine estimates; y-axis direction-cosine estimates; Acoustic arrays; Acoustic beams; Direction of arrival estimation; Iterative algorithms; Multiple signal classification; Parameter estimation; Sensor arrays; Signal processing algorithms; Sonar equipment; Underwater acoustics;
Journal_Title :
Oceanic Engineering, IEEE Journal of
