2016
DOI: 10.3390/rs8100830
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A Sparsity-Based InSAR Phase Denoising Algorithm Using Nonlocal Wavelet Shrinkage

Abstract: An interferometric synthetic aperture radar (InSAR) phase denoising algorithm using the local sparsity of wavelet coefficients and nonlocal similarity of grouped blocks was developed. From the Bayesian perspective, the double-l 1 norm regularization model that enforces the local and nonlocal sparsity constraints was used. Taking advantages of coefficients of the nonlocal similarity between group blocks for the wavelet shrinkage, the proposed algorithm effectively filtered the phase noise. Applying the method t… Show more

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Cited by 8 publications
(4 citation statements)
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“…The quantitative indexes are the number of residues (NOR) [1] remaining after filtering, the MSE between the filtered phase and the corresponding ideal phase, the mean structural similarity index (MSSIM) [26] between the filtered phase and the corresponding ideal phase, and running time (T). Lacking the ideal interferometric phase, the no-reference metric Q [26,27] was used in the experiments on real data. The metric Q can provide a quantitative measure of the phase detail information.…”
Section: Performance Evaluationmentioning
confidence: 99%
“…The quantitative indexes are the number of residues (NOR) [1] remaining after filtering, the MSE between the filtered phase and the corresponding ideal phase, the mean structural similarity index (MSSIM) [26] between the filtered phase and the corresponding ideal phase, and running time (T). Lacking the ideal interferometric phase, the no-reference metric Q [26,27] was used in the experiments on real data. The metric Q can provide a quantitative measure of the phase detail information.…”
Section: Performance Evaluationmentioning
confidence: 99%
“…For real InSAR data, the no-reference metric Q is adopted, because the clean/reference interferometric phase is usually unknown. The index can comprehensively reflect the capacities of noise suppression and detail preservation of the filtering method [16,49], so it is suitable for our evaluation. According to [49], the local dominant orientation is calculated by the singular value decomposition of local interferometric phase image gradient matrix G…”
Section: Nmentioning
confidence: 99%
“…Besides, the first wavelet domain method for interferometric phase filtering is proposed in [14], which reduces noise in the complex wavelet plane. This work has important implications for subsequent research [15,16]. Generally speaking, wavelet domain filters have a better capacity to preserve spatial resolution when compared with spatial domain methods.…”
Section: Introductionmentioning
confidence: 99%
“…10,11 WTs decompose the input signal into a series of distinctive frequencies that represent different characteristics of the signal and have the capability to reflect the nonstationarity of the signal. With the benefits of multiscale and multiresolution operation, WTs have been widely applied in many studies, including for hyperspectral image denoising, 12,13 compression, 14 classification, 15 and image fusion or enhancement. 16,17 Guo et al 18 employed a WT filter to the harmonic detection systems.…”
Section: Introductionmentioning
confidence: 99%