Title :
Sparse reconstruction techniques in tomographic SAR inversion
Author :
Xiao Xiang Zhu ; Bamler, Richard
Author_Institution :
Remote Sensing Technol. Inst. (IMF), German Aerosp. Center (DLR), Wessling, Germany
Abstract :
Tomographic SAR inversion is essentially a spectral analysis problem. The resolution in the elevation direction depends on the spread of orbit tracks. Since the orbits of modern meter-resolution space-borne SAR systems, such as TerraSAR-X, are tightly controlled, the tomographic elevation resolution is at least an order of magnitude lower than in range and azimuth. Hence, super-resolution reconstruction algorithms are desired. Considering the sparsity of the signal in elevation, here the theory of compressive sensing comes into play. In this paper, recent developments on compressive sensing applied to tomographic SAR inversion are presented: A compressive sensing based algorithm “SL1MMER” was proposed; The ultimate bounds of the technique on localization accuracy and super-resolution power were investigated; the super-resolution capability of SL1MMER is demonstrated using TerraSAR-X real data examples.
Keywords :
compressed sensing; radar resolution; signal reconstruction; spaceborne radar; spectral analysis; synthetic aperture radar; tomography; SL1MMER compressive sensing based algorithm; TerraSAR-X; compressive sensing theory; elevation direction; meter-resolution space-borne SAR systems; orbit tracks; sparse reconstruction techniques; spectral analysis problem; super-resolution reconstruction algorithms; tomographic SAR inversion; tomographic elevation resolution; Abstracts; Atmospheric modeling; Image coding; Image resolution; Indexes; Remote sensing; Synthetic aperture radar; SL1MMER algorithm; compressive sensing; sparsity; tomographic SAR inversion;
Conference_Titel :
Signal Processing Conference (EUSIPCO), 2013 Proceedings of the 21st European
Conference_Location :
Marrakech
