International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
Comparing the spectral and texture classifications in table 2, we 
see that spectral classification is better suited for those 
landscape units with a specific spectral response pattern and 
well differenciated from the rest of the units, such as pasture 
land and cereal crops, or fallow. The distribution of grey levels 
in these two classes is very homogeneous, so they are more 
difficult to discriminate by texture methods. On the other hand, 
texture techniques are very efficient in classifying lanscape 
units that contain a high spectral heterogeneity, such as 
scattered trees, forest-shrub and dense shrub. These classes are 
not very accurate when classified using only spectral band. 
Another interesting aspect is the the integration of spectral and 
texture bands for classification has a synergic effect on the 
résults, in some cases even improving the accuracy of both 
groups of classes. 
However, it is important to note that the reported results refer to 
the inner areas of the texture units and not to the borders 
between textures. In these areas, the border effect decreases the 
overall accuracy to 47%. An example of this effect is shown on 
the detail image of figure 6. Some previous tests have shown 
how the post-processing operation, described for the energ 
filters, increases the accuracy in the border areas in a 27% (Ruiz 
et al., 2001) 
      
Figure 6. Example of the border effect in texture classification. 
4. CONCLUSIONS 
This study has been focused on two main applications of texture 
analysis in remote sensing: the classification of forest landscape 
units and urban areas. The former holds a special interest for 
mapping forest areas, the latter is a first step in monitoring 
urban sprawl. Some important aspects can be concluded: 
- The texture methods provide an alternative to the spectral 
methods for the classification of forest units with a high 
spectral heterogeneity, or when the classes are defined by 
differences in vegetation density. 
In urban classification, the texture methods are useful for 
discriminating old urban areas and new residential spots, 
but they introduce important errors in the classification of 
industrial areas, so spectral information should be used in 
addition to texture. 
A universal criteria in order to use the idoneous texture 
extraction method for classification does not seem to exist. 
Therefore, the selection should be in funtion of the type of 
landscape units defined in each application. 
Furthermore, the combination of different texture methods 
improves the classification results, especially when 
combining statistical methods based on the GLCM with the 
details of different levels obtained from the wavelet 
transform. The Gabor filters allow an important part of the 
texture information to be condensed into a few variables. 
Before beginning the texture classification process, it is 
important to previously select the methodological 
parameters and features to reduce the volume of data and to 
optimize the discrimination power of these techniques. 
The main limitation for the standard application of texture 
methods in image classification is probably the border 
effect, inherent to texture analysis and which introduces 
important errors in the transition areas between texture 
units. Further work should be done to reduce this effect. 
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Ferro, C.J. and Warner, T.A., 2002. Scale and texture in digital 
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Haralick, R.M., K Shanmugam and Dinstein, 1973. Texture 
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Hsiao, J.Y. and A.A. Sawchuk, 1989. Unsupervised image 
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Randen, T. and Husoy, J.H., 1999. Filtering for texture 
classification: A comparative study. IEEE Trans. Pal. Anal. 
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Ruiz, L.A., Acosta, P., Fdez.-Sarria, A., Porres, M.J., Pardo, 
LE. 2001. Mejora de la eficiencia en la segmentación 'de 
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Sutton, R.N. and E.L. Hall, 1972. Texture measures for 
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Unser, M., 1995. Texture classification and segmentation using 
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Van de Vower, G., Scheunders, P., Van Dyck, D. 1999. 
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ACKNOWLEDGMENTS 
The authors wish to thank the financial support provided by the 
Spanish Ministry of Science and Technology and the FEDER 
(projects REN2003-04998 and BTE2002-04552), as well as ? 
the Politechnic University of Valencia (project 2002-0627). 
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