TY - GEN
T1 - The robust InSAR optimization framework with application to monitoring cities on volcanoes
AU - Wang, Yuanyuan
AU - Zhu, Xiao Xiang
N1 - Publisher Copyright:
© 2015 IEEE.
PY - 2015/6/9
Y1 - 2015/6/9
N2 - This paper introduces the Robust InSAR Optimization (RIO) framework to the multi-pass InSAR techniques, such as PSI, SqueeSAR and TomoSAR whose current optimal estimators were derived based on the assumption of Gaussian distributed stationary data, with seldom attention towards their robustness. The RIO framework effectively tackles two common problems in the multi-pass InSAR techniques: 1. treatment of images with bad quality, especially those with large uncompensated phase error, and 2. the covariance matrix estimation of non-Gaussian and non-stationary distributed scatterer (DS). The former problem is dealt with using a robust M-estimator which effectively down-weight the images that heavily violate the phase model, and the latter is addresses with a new method: the Rank M-Estimator (RME) by which the covariance is estimated using the rank of the DS. RME requires no flattening/estimation of the interferometric phase, thanks to the property of mean invariance of rank. The robustness of RME is achieved by using an M-estimator, i.e. amplitude-based weighing function in covariance estimation. The RIO framework can be easily extended to most of the multi-pass InSAR techniques.
AB - This paper introduces the Robust InSAR Optimization (RIO) framework to the multi-pass InSAR techniques, such as PSI, SqueeSAR and TomoSAR whose current optimal estimators were derived based on the assumption of Gaussian distributed stationary data, with seldom attention towards their robustness. The RIO framework effectively tackles two common problems in the multi-pass InSAR techniques: 1. treatment of images with bad quality, especially those with large uncompensated phase error, and 2. the covariance matrix estimation of non-Gaussian and non-stationary distributed scatterer (DS). The former problem is dealt with using a robust M-estimator which effectively down-weight the images that heavily violate the phase model, and the latter is addresses with a new method: the Rank M-Estimator (RME) by which the covariance is estimated using the rank of the DS. RME requires no flattening/estimation of the interferometric phase, thanks to the property of mean invariance of rank. The robustness of RME is achieved by using an M-estimator, i.e. amplitude-based weighing function in covariance estimation. The RIO framework can be easily extended to most of the multi-pass InSAR techniques.
KW - D-InSAR
KW - InSAR
KW - M-estimator
KW - rank covariance matrix
KW - robust estimation
UR - http://www.scopus.com/inward/record.url?scp=84938854680&partnerID=8YFLogxK
U2 - 10.1109/JURSE.2015.7120466
DO - 10.1109/JURSE.2015.7120466
M3 - Conference contribution
AN - SCOPUS:84938854680
T3 - 2015 Joint Urban Remote Sensing Event, JURSE 2015
BT - 2015 Joint Urban Remote Sensing Event, JURSE 2015
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2015 Joint Urban Remote Sensing Event, JURSE 2015
Y2 - 30 March 2015 through 1 April 2015
ER -