International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
analyze the performance of the neural network ART2 in the 
thematic classification as related to data of field work, using 
Kappa statistics procedures; (4) to perform a temporal analysis 
with data of the years 2002 and 2003, aiming to investigate the 
dynamics of occupation from the physical space, evaluating the 
changes at the thematic classes identified by the neural network 
ART? for both years. 
2. AREA UNDER STUDY 
2.1 Localization 
The area under study is located partially at the municipalities of 
Sinop, Cláudia and Itauba, at northern Mato Grosso State, 
Central- West Brazil, between geographical coordinates S 
10?48'55"- S 12?00'46" and W 54?54'03" - W 55?46'53" (Figure 
1). This area is situated along a section of highway BR-163 
Cuiaba-Santarém, encompassing an area of 382,000 ha. 
Be, La: 108210" 
¥ Lag. 0: 5508205 
um 
“ 
   
    
  
Foil 
ESTADO DO MAT 
  
La.S: 1148313" 
Long. 0: 555153951" 
Figure 1. Location of the study area, in a mosaic of two images 
ASTER (bands 4, 3 and 2). 
3. DATA AND METHODS 
3.1 ASTER images 
Spectral data obtained by the ASTER sensor system were used 
in this study (Table 1). The images referring to year 2002 were 
acquired at NASA and EROS Data Center (USA), and those of 
2003 at ERSDAC (Earth Remote Sensing Data Analysis 
Center), Japan, under Agreement Nr. H140250. All scenes were 
of type 1B, which are delivered to users with radiometric and 
geometric calibrations. The images from 2002 were used 
complementarily, aiming to investigate the dynamics of land 
use/land cover in the area under study. 
  
  
  
  
  
  
  
  
YEAR ID IMAGE 
2002 pg-PR1B0000-2002050402 019 001 
¢-PR1B0000-2002050402 181 001 
2003 g-PR1B0000-2003090902 005 001 
pg-PR1B0000-2003090902 167 001 
  
Table 1. ASTER images used. 
o 
3.2 Methodology 
Initially a pre-processing of data is done through correction of 
the cross-talk problem, of resampling from SWIR bands (spatial 
resolution: 30 to 15 m), of image registration, of atmospheric 
correction and rectification of ASTER images from both data 
124 
sets 2002 and 2003. Afterwards the automatic image 
classification is done using a non-supervised ART2 algorithm 
considering Artificial Neural Network (ANN), followed by a 
post-classification to minimize the presence of isolated pixels. 
Finally the evaluation of accuracy is done, using Kappa 
statistics, related to ground truth, with maps on land use/land 
cover are generated for both data sets considered. 
4. RESULTS 
The cross-talk problem (Iwasaki et al., 2001) was solved using 
a "cross talk correction" program developed by ERSDAC 
(2001). Afterwards resampling of SWIR bands from 30 to 15 m 
was done, in order to integrate with VNIR. 
For the registration of the ASTER images, 20 control points 
were identified, using a first grade polynomial and resampling 
of pixels by the nearest neighbor algorithm. During the 
evaluation of the exactness of registration using as reference the 
image from 2003, a RMS error of 0,27 was obtained. This result 
is considered as reasonable, because for a spatial resolution of 
15 m of ASTER images, the internal error of points used for 
mapping (4 m) is less than half a pixels' spatial resolution of the 
images. As for the 2002 image, the RMS error of 0.05 was 
considered excellent. 
In order to obtain reflectance values on the surface, an 
atmospheric correction was done using the ACORN 4.0 
program, based on the radiation transference model 
MODTRAN 4, which transforms radiance values of ASTER 
images for surface reflectance values. Data of water vapor were 
obtained from MODIS sensor data, located at the same Terra 
satellite corresponding to the same dates of obtainment from 
these ASTER images (MODIS, 2003). 
To get uniform ASTER data for 2002 and 2003, the method of 
pseudo-invariant targets present in the image were used (Hill & 
Sturn, 1991). This procedure is used to eliminate those 
differences caused by factors which affect the image 
acquisition. The digital values obtained from these pseudo- 
invariant targets (clear and dark) at both dates, were adjusted by 
a linear regression to digital values of the reference image 
corrected, for clear and dark targets (Mendoza, 2004). 
To evaluate the discrimination between land use/land cover 
classes, an analysis of the spectral behavior given by the 
reflectance values and the wavelengths in the spectral range of 
500-2500 nm was performed, which includes 9 bands of 
ASTER. At Figure 2 a graph of the average reflectance of 
typical samples of thematic classes defined in the area under 
study is presented for the scene from June 27° 2002, 
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