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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2t 
In the experiment, No.38th research institute. designed and 
constructed a high resolution X-band SAR system. 
In the following, an outline of the system design is given: the 
SAR system is configured as one antenna radar with a ground 
resolution up to 0.5m X 0.5m. Figure | shows the AIRSAR 
flight segment. 
Due to its compact design, the SAR system can be installed on 
rather small aircrafts. During the projects mentioned, the system 
was installed in Y 12. 
3. TEXTURE ANANLYSIS 
3.1 High Resolution AIRSAR Images 
High resolution sensor technique has made great process since 
1990's. High resolution image can show the object information 
such as structure, texture and detail clearly. Texture feature is 
the direct embodiment of the object structure and space 
arrangement in the image. Recently, resolution of remote 
sensing image data has been higher, and the tendency has been 
seen not only for visible sensor images but also for Synthetic 
Aperture Radar (SAR) images. Textural analysis has also been 
carried out for SAR. However, it is scarcely discussed that 
textural features of high resolution AIRSAR images such as 
river, road and residential area are extracted by texture analysis. 
In this study, the influences carried by the shadows of 
residential area, trees and mountain areas that have been 
considered in high resolution AIRSAR. However, unusual 
surface patterns are formed clearly due to the fine shadow 
included the analysis areas using higher resolution images. 
3.2 Texture Analysis 
Image texture in general is considered the change and repeat of 
image grey in space, or local pattern (texture cell) in image and 
its arrange rules. Texture is the important information in remote 
sensing and significant base of interpretation by manual work 
and computer. In extracting remote sensing image thematic 
information, it improves the correction and precise through 
adding texture information to original image spectral 
information. Image texture, defined as a function of the spatial 
variation in pixel intensities (grey values), is useful in a variety 
of applications and has been a subject of intense study by many 
researchers. One immediate application of image texture is the 
recognition of image regions using texture properties. 
Applied texture method is to carry out texture analysis. Texture 
analysis refers to acquire texture character through some image 
processing technology, then obtains quantitative or qualitative 
description of texture. It includes two aspects: inspecting basic 
cells of texture and acquiring the information on basic cells 
arrange distribution of texture. Statistics-based | method, 
structure-based method and spectrum-based method are put 
forward (Jiang et al, 2003). Statistic method refers to carrying 
out texture analysis in the condition of unknown the basic cell 
of texture, and it mainly describes the basic cell of texture or 
random and spatial statistic character in local pattern, such as 
GLCM (Grey Level Co-occurrence Matrices), wave transforms, 
fractal representation, *visual" properties random field models 
and other representation. Structural texture analysis focuses 
primarily on identifying periodicity in texture or on identifying 
their placement rules. 
161 
Texture analysis has been extensively used to classify remote: 
sensed images. Filtering features and co-occurrence have been 
compared in several studies, which concluded that co- 
occurrence features give the best performance. Co-occurrence 
technique use spatial grey level difference based statistics to 
extract texture from remote-sensed images. 
Rignot and Kwok (Rignot et al, 1990) have analyzed SAR 
images using texture features computed from gray level co- 
occurrence matrices. However, they supplement these features 
with knowledge about the properties of SAR images. Du (Du, 
1990) used texture features derived from Gabor filters to 
segment SAR images. He successfully segmented the 
SAR images into categories of water, new forming ice, 
older ice, and multi-year ice. Lee and Philpot (Lee et al, 
1990) also used spectral texture features to segment SAR 
images. 
3.3 Grey-level Co-occurrence Matrix 
Co-occurrence matrix representation: 
I. Method of extracting properties of an image by 
comparing grey-tone spatial dependencies between 
pixels; 
Matrices of the frequencies (probabilities) of going 
from one gray level to another at a predefined 
distance and different orientations is derived; 
3. 14 Statistical measures of texture can be extracted 
from the matrix into a feature vector, E.g. Inverse 
Difference Moment, Energy (Angular Second 
Moment), Contrast, Correlation, Entropy; 
t2 
Grey-level co-occurrence matrix is the two dimensional matrix 
dE & gest tou 
of joint probabilities p ; 7 between pairs of pixels, 
separated by a distance, d, in a given direction, r. It is popular in 
texture description and based on the repeated occurrence of 
some grey level configuration in the texture; this configuration 
varies rapidly with distance in fine textures, slowly in coarse 
textures. 
Finding texture features from gray-level co-occurrence matrix 
for texture classification in this experiment are based on these 
criteria (Mihran, 1998): 
Energy: 
2,2, P0. uU 
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Entropy: 
SN P, j Mog P, GG. 7) (2) 
I 
Contrast: (typically k = 2,1= 1) 
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