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PIER PIER B PIER C PIER M PIER Letters
2016-06-03
Bias Compensation in h /a/α Polarimetric SAR Decomposition and Its Implication for the Classification
By
Mohamed Yahia,

    Mr. Mohamed Yahia

    Ecole Nationale d'Ingenieurs de Gabes

    Tunisia

    Homepage

Faten Khalfa,

    Dr. Faten Khalfa

    Labo. SYSCOM

    Tunisia

    Homepage

Marwa Chabir,

    Dr. Marwa Chabir

    Labo. SYSCOM

    Tunisia

    Homepage

Taoufik Aguili

    Dr. Taoufik Aguili

    Syscom Laboratory

    Engineers' National School of Tunis

    Tunisia

    Homepage

Progress In Electromagnetics Research B, Vol. 68, 105-121, 2016
doi:10.2528/PIERB16033005
Abstract
Classification of land cover types is one important application of polarimetric synthetic aperture radar (PolSAR) remote sensing. There are numerous features that can be extracted from PolSAR images. Among them, eigenvalues λi, entropy H, alpha angle α, and anisotropy A are effective and popular tools for the analysis and quantitative estimation of the physical parameters. Nevertheless, the speckle noise appearing in PolSAR images reduces the accuracy of image classification. Consequently, it should be filtered correctly. Generally, filtering PolSAR data generate biased estimates of λi/H/A/α parameters. In this paper, we studied the effects of bias compensation on supervised and unsupervised PolSAR image classification. We applied the asymptotic quasi maximum likelihood estimator AQ-MLE and Yahia/Aguili's bias compensation methods. To improve the classification accuracies, we demonstrated that bias compensation must be associated with speckle reduction. The combination of the span with biased parameters reduced the effects of bias but did not eliminate it totally. Simulated and real data were used for validation.
Citation
Mohamed Yahia, Faten Khalfa, Marwa Chabir, and Taoufik Aguili, "Bias Compensation in h /a/α Polarimetric SAR Decomposition and Its Implication for the Classification," Progress In Electromagnetics Research B, Vol. 68, 105-121, 2016.
doi:10.2528/PIERB16033005
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