Abstract
The filtering of multi-pass synthetic aperture radar interferometry (InSAR) stack data is a necessary preprocessing step utilized to improve the accuracy of the object-based three-dimensional information inversion in urban area. InSAR stack data is composed of multi-temporal homogeneous data, which is regarded as a third-order tensor. The InSAR tensor can be filtered by data fusion, i.e., tensor decomposition, and these filters keep balance in the noise elimination and the fringe details preservation, especially with abrupt fringe change, e.g., the edge of urban structures. However, tensor decomposition based on batch processing cannot deal with few newly acquired interferograms filtering directly. The filtering of dynamic InSAR tensor is the inevitable challenge when processing InSAR stack data, where dynamic InSAR tensor denotes the size of InSAR tensor increases continuously due to the acquisition of new interferograms. Therefore, based on the online CANDECAMP/PARAFAC (CP) decomposition, we propose an online filter to fuse data and process the dynamic InSAR tensor, named OLCP-InSAR, which performs well especially for the urban area. In this method, CP rank is utilized to measure the tensor sparsity, which can maintain the structural features of the InSAR tensor. Additionally, CP rank estimation is applied as an important step to improve the robustness of Online CP decomposition - InSAR(OLCP-InSAR). Importing CP rank and outlier’s position as prior information, the filter fuses the noisy interferograms and decomposes the InSAR tensor to acquire the low rank information, i.e., filtered result. Moreover, this method can not only operate on tensor model, but also efficiently filter the new acquired interferogram as matrix model with the assistance of chosen low rank information. Compared with other tensor-based filters, e.g., high order robust principal component analysis (HoRPCA) and Kronecker-basis-representation multi-pass SAR interferometry (KBR-InSAR), and the widespread traditional filters operating on a single interferometric pair, e.g., Goldstein, non-local synthetic aperture radar (NL-SAR), non-local InSAR (NL-InSAR), and InSAR nonlocal block-matching 3-D (InSAR-BM3D), the effectiveness and robustness of OLCP-InSAR are proved in simulated and real InSAR stack data. Especially, OLCP-InSAR can maintain the fringe details at the regular building top with high noise intensity and high outlier ratio.
Highlights
The interferometric synthetic aperture radar (InSAR) is an effective remote sensing technique to obtain the multi-baseline interferograms and monitor the surface deformation via repeated observation [1]
In online CP (OLCP)-InSAR, it is required to preset an appropriate value of CP rank, it is a NP-hard problem for calculating CP rank directly [38,39] and it influences the performance of the filtering method by initializing with a random CP rank
The experiments were conducted with simulated data and real InSAR tensor generated from TerraSAR-X images, which proves the effectiveness and robustness of OLCP-InSAR when dealing with the InSAR data of urban areas
Summary
The interferometric synthetic aperture radar (InSAR) is an effective remote sensing technique to obtain the multi-baseline interferograms and monitor the surface deformation via repeated observation [1]. KBR is a combination of the zero norm of the core tensor acquired by higher order singular value decomposition (HoSVD) [27] and the relaxation of the Tucker rank [28] These filters have achieved a good performance in filtering InSAR tensor because of multi-pass data fusion, especially at the region of phase jump. The low rank information of the accumulated InSAR tensor provides an effective reference for filtering the new acquired interferograms. The filter fuses the multi-pass interferograms and learns the low rank information of InSAR tensoronline, which can provide assistance to process new acquired interferograms To this end, the contributions of this paper are threefold:. The framework can effectively filter the dynamic InSAR tensor and improve the accuracy of object-based interferometric phase estimation, especially at the regular building top with the high noise intensity and high outlier ratio.
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