Title :
Estimating ocean surface velocity and coherence time using multichannel ATI-SAR systems
Author :
Besson, O. ; Gini, F. ; Griffiths, H.D. ; Lombardini, F.
Author_Institution :
Dept. of Avionics & Syst., ENSICA, Toulouse, France
fDate :
12/1/2000 12:00:00 AM
Abstract :
Conventional along-track interferometric synthetic aperture radars (ATI-SARs) derive the ocean surface velocity from an estimate of the phase difference between the SAR echoes received from two displaced phase centres with a single time-lag. The authors propose an efficient asymptotic maximum likelihood (ML) algorithm for jointly estimating the ocean surface velocity and ocean coherence time by using multichannel SAR data collected from an array of phase centres with multiple time-lags. The method combines a covariance matching algorithm with the use of the extended invariance principle (EXIP). Simulated results show that the proposed technique provides better estimation accuracy than the conventional two-channel system. Moreover, it provides unambiguous velocity retrieval and flexibility to varying ocean coherence time
Keywords :
array signal processing; covariance analysis; maximum likelihood estimation; oceanographic techniques; radar applications; radar signal processing; radiowave interferometry; remote sensing by radar; synthetic aperture radar; ML algorithm; Monte Carlo simulation; SAR echoes; along-track interferometric synthetic aperture radar; covariance matching algorithm; displaced phase centres; efficient asymptotic maximum likelihood algorithm; estimation accuracy; extended invariance principle; multichannel ATI-SAR systems; multichannel SAR data; multiple time-lags; ocean coherence time estimation; ocean surface velocity estimation; phase centres array; phase difference estimation; remote sensing; simulated results; single time-lag; two-channel system; unambiguous velocity retrieval;
Journal_Title :
Radar, Sonar and Navigation, IEE Proceedings -
DOI :
10.1049/ip-rsn:20000773
