International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B3, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
TEXTURE ANALYSIS FOR CLASSIFICATION OF RISAT-II IMAGES 
D. Chakraborty?', S Thakur®, A Jeyaram®, YVN Krishna Murthy^, VK Dadhwal* 
" Regional Remote Sensing Centre — East, NRSC, ISRO, Kolkata, India (deba.isro@gmail.com) 
? Sikkim Manipal Institute of Technology, Sikkim, India 
"NRSC, ISRO, Hyderabad, India 
Commission III, Working Group ICWG III/VII 
KEYWORDS: Image, Texture, Method, Interpretation, Analysis, Development and Classification 
ABSTRACT 
RISAT-II or Radar Imaging satellite - II is a microwave-imaging satellite lunched by ISRO to take images of the earth during day 
and night as well as all weather condition. This satellite enhances the ISRO's capability for disaster management application together 
with forestry, agricultural, urban and oceanographic applications. The conventional pixel based classification technique cannot 
classify these type of images since it do not take into account the texture information of the image. This paper presents a method to 
classify the high-resolution RISAT-II microwave images based on texture analysis. It suppress the speckle noise from the microwave 
image before analysis the texture of the image since speckle is essentially a form of noise, which degrades the quality of an image; 
make interpretation (visual or digital) more difficult. A local adaptive median filter is developed that uses local statistics to detect the 
speckle noise of microwave image and to replace it with a local median value. Local Binary Pattern (LBP) operator is proposed to 
measure the texture around each pixel of the speckle suppressed microwave image. It considers a series of circles (2D) centered on 
the pixel with incremental radius values and the intersected pixels on the perimeter of the circles of radius r (where r = 1, 3 and 5) are 
used for measuring the LBP of the center pixel. The significance of LBP is that it measure the texture around each pixel of the image 
and computationally simple. ISODATA method is used to cluster the transformed LBP image. The proposed method adequately 
classifies RISAT-II X band microwave images without human intervention. 
1.0 INTRODUCTION 
Optical remote sensing technology is used for mapping the 
earth surface. But it cannot map the earth surface in all weather 
conditions since optical bands cannot penetrate clouds, smog 
and haze. Microwave remote sensing technology is used as an 
alternative technology for mapping the earth surface features 
especially when optical data is not available (Oliver et al., 
1998). But interpretation of microwave images is very difficult 
due to the presence of texture in these images. Classical 
methods namely K-Means (Hartigan et al. 1979), Fuzzy C 
Means (Bezdek et al. 1984) and methods of Minimum Distance 
(Richards, 1995) are not adapted because they fail to take into 
account the fact that a texture can be represented as a mix of 
smooth regions and very sharp transitions. The issue of texture 
based image classification is an old and difficult problem, 
which is still a field of a lot of research. 
Relevant studies on Texture Classification: GLCM (Gray Level 
Co-occurrence matrix) algorithm (Tsai et al. 2006; Clausi et al. 
2004; Tsai et al. 2005; Haralick et al. 1973) quantifies the 
texture by measuring the spatial frequency of co-occurrence of 
pixel gray levels in a user defined moving kernel (window). 
Since the size of a GLCM matrix depends on the data range of 
pixel gray values, images of large numbers of data bits may 
result in large matrix sizes during GLCM operation and require 
a large amount of memory and CPU cycles to handle the 
computation. The reductions of GLCM matrix sizes by 
rescaling the image gray levels to a lower data bit number 
  
reduce the classification accuracy. Another important factor 
that may cause substantial impact to GLCM processing is the 
kernel size. Moreover, the method is not able to properly 
identify the boundary region between the textures. 
Markov random field (MRF) model (Szira yi et al. 2000; Clausi 
et al. 2004; Chellappa et al. 1985; Solberg et al. 1996; Chen et 
al. 1998) assumes that the intensity at each pixel in the image 
depends on the intensities of the neighboring pixels. The 
method segment the image based on the local calculations of 
probability and potential functions. The draw back of the 
method is that, it cannot properly handle the data from classes 
not present in the training set, erodes the quality of the 
segmentation in the boundary region and needs huge amount of 
computing power. 
Some more techniques like the gamma, Weibull, and K 
distributions have been used to classify microwave images 
(Bernad et al. 2009; Dong et al. 2001; Tison et al. 2004; Petrou 
et al. 2002). These mathematical models have done well in 
characterizing low-resolution microwave images. But most of 
them failed to classify high-resolution microwave images due 
to presence of complex structure of textures in such type of 
images. RISAT II is capable of high-resolution microwave 
imaging of Im, 3m, 1.8m and 8m. Therefore classification of 
this type of high-resolution microwave images without much 
human intervention is required to be developed. 
   
  
   
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