Title :
ML estimation of seafloor topography using multi-frequency synthetic aperture sonar
Author :
Barclay, P.J. ; Hayes, M.P. ; Gough, P.T.
Author_Institution :
Dept. of Electr. & Comput. Eng., Canterbury Univ., Christchurch, New Zealand
Abstract :
In this paper we investigate synthetic aperture sonar (SAS) broadband interferometric height estimation using multiple frequency bands. The height estimate is generated using a maximum likelihood (ML) estimate combining the data from the hydrophones. To decrease the effect of the large variance of the phase difference estimates the broadband signal is divided into smaller subbands and combined to give a height estimate with much improved accuracy, albeit at a reduced resolution due to the reduction in system bandwidth. Results are shown for a two element sonar, and the improvement obtained using multiple frequency bands subbanded to give a lower variance in the height estimate. Multiple pings are also combined as multiple looks, further reducing the height variance.
Keywords :
acoustic wave interferometry; bathymetry; hydrophones; maximum likelihood estimation; synthetic aperture sonar; underwater sound; ML estimation; SAS; broadband interferometric height estimation; broadband signal; height variance; hydrophone data; maximum likelihood estimate; multifrequency synthetic aperture sonar; multiple frequency bands; multiple pings; phase difference estimate; seafloor topography; subbands; system bandwidth reduction; Covariance matrix; Delay effects; Delay estimation; Frequency estimation; Maximum likelihood estimation; Phase estimation; Sea floor; Sonar equipment; Surfaces; Synthetic aperture sonar;
Conference_Titel :
Oceans 2005 - Europe
Conference_Location :
Brest, France
Print_ISBN :
0-7803-9103-9
DOI :
10.1109/OCEANSE.2005.1511779
