Random Similarity-Based Entropy/Alpha Classification of PolSAR Data

A fast and competent alternative to the widely used Cloude-Pottier entropy/alpha (H/alpha) classification is developed for the rapid response application of polarimetric synthetic aperture radar (PolSAR) data. Random similarity which measures both the scattering similarity and randomness of polarimetric scatterers is used to enable an H/alpha-like classification in terms of two key parameters, i.e., the similarity-based angle alpha(s) and entropy H-s, alpha(s) the alternatives to the Cloude-Pottier angle a and entropy H, respectively. Parameters alpha(s) and H-s maintain the same physical information alpha(s) parameters a and H, so the existing knowledge regarding a and H can be naturally extended to them. Angle alpha(s) measures scattering mechanism and is ranged within the same interval [0 degrees, 90 degrees] alpha(s) a while entropy H-s measures scattering randomness which is also a logarithm within the interval [ 0, 1] similar to H. The pixelwise eigendecomposition in the calculation of a and H is avoided for alpha(s) and H-s, and the resulted efficiency improvement is, thus, considerable. By rigorously modeling the alpha(s)-alpha and the H-s-H relationship to illustrate the competence of the H-s-alpha(s) combination in discrimination of target and to identify the searching ranges for the boundary determination, an H-s/alpha(s) classification is then devised with the boundaries of the eight effective classes being determined by an optimization to minimize the misclassification and further integrated on different PolSAR images to remove the possible bias from dataset for general applicability. Comparative experiment on both space-borne and airborne PolSAR datasets with H/a indicates that H-s/alpha(s) can achieve very consistent roll-invariant target discrimination alpha(s) H/alpha (overall accuracy >= 95%, kappa coefficient >= 0.95) but with averagely 150 times higher efficiency although the LAPACK-based eigenanalysis tool has been used to accelerate the eigendecomposition for H/alpha. Preliminary result from the adaptive model-based classification reveals that the H-s-involved boundaries in H-s/alpha(s) are independent of a particular PolSAR dataset.