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2011-04-29

Land Cover Classification of Palsar Images by Knowledge Based Decision Tree Classifier and Supervised Classifiers Based on SAR Observables

By Pooja Mishra, Dharmendra Singh, and Yoshio Yamaguchi
Progress In Electromagnetics Research B, Vol. 30, 47-70, 2011
doi:10.2528/PIERB11011405

Abstract

The intent of this paper is to explore the application of information obtained from fully polarimetric data for land cover classification. Various land cover classification techniques are available in the literature, but still uncertainty exists in labeling various clusters to its own class without using any a priori information. Therefore, the present work is focused on analyzing useful intrinsic information extracted from SAR observables obtained by various decomposition techniques. The eigenvalue decomposition and Pauli decomposition have been carried out to separate classes on the basis of their scattering mechanisms. The various supervised classification techniques were applied in order to see possible differences among SAR observables in terms of information that they contain and their usefulness in classifying particular land cover type. Another important issue is labeling the clusters, and this work is carried out by decision tree classification that uses knowledge based approach. This classifier is implemented by scrupulous knowledge of data obtained by empirical evidence and their experimental validation. It has been demonstrated quantitatively that standard polarimetric parameters such as polarized backscatter coefficients (linear, circular and linear 45°), co and cross-pol ratios for both linear and circular polarizations can be used as information bearing features for making decision boundaries. This forms the basis of discrimination between various classes in sequential format. The classification approach has been evaluated for fully polarimetric ALOS PALSAR L-band level 1.1 data. The classifier uses these data to classify individual pixel into one of the five categories: water, tall vegetation, short vegetation, urban and bare soil surface. The quantitative results shown by this classifier gives classification accuracy of about 88%, which is better than other classification techniques (supervised classification techniques based on SAR observables).

Citation


Pooja Mishra, Dharmendra Singh, and Yoshio Yamaguchi, "Land Cover Classification of Palsar Images by Knowledge Based Decision Tree Classifier and Supervised Classifiers Based on SAR Observables," Progress In Electromagnetics Research B, Vol. 30, 47-70, 2011.
doi:10.2528/PIERB11011405
http://www.jpier.org/PIERB/pier.php?paper=11011405

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