Title :
Passive acoustic monitoring using random matrix theory
Author :
Menon, Ravi ; Gerstoft, Peter ; Hodgkiss, William S.
Author_Institution :
Marine Phys. Lab., Univ. of California San Diego, La Jolla, CA, USA
Abstract :
Cross-correlating ocean noise is a potential alternative to using active sources to monitor and study ocean environments. However, directional sources in the medium (usually ships) often introduce a bias in the cross-correlations, making the travel time estimates unreliable. Here, we use recent results in random matrix theory for the eigenvalue density of isotropic noise sample covariance matrices to separate the directional noise from the diffuse noise field. The eigenvalues obtained from ocean data agree well with the theoretical results. Beamforming on the diffuse noise components reveals a fairly spatially isotropic nature for the noise field, which fits the assumption. The cross-correlations using the diffuse noise field alone converge to the expected travel times (i.e., unbiased estimates) and are stable temporally.
Keywords :
acoustic signal processing; array signal processing; eigenvalues and eigenfunctions; beamforming; cross-correlating ocean noise; cross-correlations; directional sources; eigenvalues; noise components; noise field; ocean environments; passive acoustic monitoring; random matrix theory; spatially isotropic nature; Correlation; Covariance matrix; Eigenvalues and eigenfunctions; Noise; Oceans; Sensors; System-on-a-chip; Passive acoustics; eigenvalue density; environment monitoring; isotropic noise; sample covariance matrix;
Conference_Titel :
Statistical Signal Processing Workshop (SSP), 2012 IEEE
Conference_Location :
Ann Arbor, MI
Print_ISBN :
978-1-4673-0182-4
Electronic_ISBN :
pending
DOI :
10.1109/SSP.2012.6319827
