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Results from the SIR-C experiment reported in Hess et al. 
(1995) suggest that the use of multi-frequency SAR data can 
improve the discrimination of vegetation in the tropical 
floodplain. According to the authors, backscattering statistics 
indicate that both C and L band are necessary for accurate 
delineation of ground classes, such as flooded forest, 
macrophyte stands and non-flooded forest. 
According to Rosenqvist (1995) L band backscatter was 
sensitive to changes in rice growth, reaching the highest 
backscatter as the plants grow to their full length of about 100 
cm. There was around 8 dB difference in the rice backscatter 
from the beginning of the growing season to the period of 
maximum growth. 
This paper describes a study performed to assess the suitability 
of multiband SAR data (L band and C band ) for 
discriminating among stands of macrophytes with differences 
in height and density in a Amazon reservoir. In this study, 
although the SAR data had been acquired at different 
incidence angles ( 35? and 76" for the L and C band 
respectively), it was hypothesized that by combining L and C 
wavebands one could separate macrophyte stands according to 
the canopy height and density. 
2. THE STUDY SITE 
Tucuruí reservoir was selected as test site because it has been 
subjected to a series of studies since 1988 (Abdon and Meyer, 
1990). Tucuruí is the first large reservoir in operation in the 
Amazon region. It is located 300 km south Belém, limited by 
the coordinates of 3° 43' S/ 49° 12' W and 5° 15' S/ 50°00"W in 
the Tocantins river basin (Figure 1). 
  
  
  
  
  
Figure 1 - The study site location 
At the maximum height (72 m) the reservoir surface is 
estimated in 2 700 km 4. The water level can reach 68 meters 
in normally dry years and even 58 meters in the extremely dry 
years. 
The study area includes a wide variety of aquatic vegetation. 
The annual rise and fall of the reservoir’s water level imposes 
a constant change in the area occupied by the different aquatic 
plant genus along the year. Some groups of aquatic vegetation, 
however, are dominant in the reservoir: a) the free-floating 
such as Eichhornia sp., Salvinia sp. and Pistia sp.; b) the 
emergent such as the Typha sp.; c) the floating leafed such as 
Scirpus sp. 
3. REMOTE SENSING DATA 
The data used in this study are the following: 
193 
e airborne C-band SAR wide mode image acquired during 
the SAREX 92 mission in Brazil. The images were 
processed in the Canadian Centre for Remote Sensing 
(CCRS) being submitted to slant to ground range correction 
and antenna pattern correction. 
e color aerial photography at the scale of 1:10 000 taken 
concurrently to the SAREX 92 mission. 
e orbital L band JERS-1 data (P397/R308 and P395/R307). 
e georeferenced Thematic Mapper/Landsat digital images 
Table 1 presents the main features of the SAR data used in this 
study. 
Table 1 - SAR data used in the study 
  
  
  
SAR Date Pixel Incidence 
data Spacing | Angle 
C Band | April, 14 | 15 m x| -76? 
1992 6.9m 
L Band | March, 7 | 12.5 m x | + 35° 
1994 12.5m 
  
  
  
  
  
  
In spite of the two year difference in data acquisition, both sets 
were obtained during the beginning of the rising water season. 
Previous studies in the area have shown that the main variable 
affecting the spread of macrophytes in the reservoir is the 
water level. Therefore, the differences in the backscatter from 
1992 to 1995 data set can be assumed to be more related to 
changes in the wavelength than in target variables. Figure 2 
shows the changes in water level in April 1992 and March, 
1995. 
4. ANCILLARY DATA 
During the SAREX 92 mission ground conditions were 
documented by aerial, boat and ground survey. The following 
information was collected during boat survey for several 
macrophyte stands: GPS coordinates, dominant genus, 
qualitative information such as stand density, homogeneity 
and height of the aquatic vegetation stands. These information 
helped to produce a reference map based on the color aerial 
photography visual interpretation. This map was taken to the 
ground in the following year and the final reference map 
produced (Novo et al. , 1996) 
  
  
  
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[ "- A --april 92 - march 94| 
  
  
  
  
Figure 2 - Reservoir water level during the SAR data 
acquisition. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996