3. DATA ACQUISITION AND METHODS 
The evaluation of the multiseasonal RADARSAT datasets 
(May, 15th and October, 23rd 1996 with incidence angles 
between 36° - 42° and 30° - 37°, respectively) was performed 
according to the following steps: pre-processing of the scenes to 
reduce speckle noise, scaling of the data from 16 to 8 bits real 
integer and extraction of the backscatter values (linear gamma 
values) from previously selected sample areas. The digital 
number that is assigned to a specific pixel in the radar image is 
related to the return signal (echo) from a corresponding ground 
cell at the position (x, y). It is also related to the radar 
backscatter cross section (o^) of the cell, which is defined as the 
ratio between the incident by the return energy to each cell 
(Yanasse, 1991). Another definition related to backscattering 
that is often used at radar images to describe the reflectivity of 
an area is a “scattering cross section per unit project area" (y^) 
which is defined as the radar cross section divided by the area, 
normal to the direction of the propagation through which the 
surface area is illuminated, that is y° — o^ / cosq. 
The TM/Landsat scenes processed by IHS transforms were 
resampled and merged to RADARSAT images using a cubic 
convolution interpolation, with an error of fitting « 1 pixel) to 
identify the different patterns and to locate the sample areas. 
The field survey was made concomitant to the RADARSAT 
Scene acquisitions (May and October) in order to obtain the 
physiognomic-structural ^ characteristics of primary and 
secondary forest and also the conditions of the pastures. In those 
areas covered by primary and secondary forest (18 samples) 
different parameters were estimated: DBH, height, crown cover 
percent as well as the botanic species identification. All 
individuals with DBH > 10 cm for primary forest and DBH > 3- 
5 cm for secondary forest, at samples areas of 10,000 m? and 
2,600 m? respectively, were measured. The size of sample plots 
was limited by the time available for measurements, however 
the sample size was enough to include representative diameter 
classes, as well as floristic diversity in primary and secondary 
forests. The estimation of biomass values was modeled by DBH 
and height into the following allometric equations for primary 
forest (Brown et al.,1989): 
Y = 0.044 . (DBH? . height)?" ? and 
Y =- 2.17 + 1.02 In(DBH) + 0.39 In height 
according to Uhl et al.(1988) for the secondary forest. Diagrams 
of the dispersion were made to know the relation between 
biomass values and seasonal Radarsat backscatter values. In 
parallel, structural profiles were made through primary and 
secondary successions, in order to analyze and explain the 
influence of dendrometric parameters on the behavior of radar 
data. A qualitative evaluation of the pasture conditions at both 
RADARSAT acquisition dates (begin of the dry and the wet 
season) was also made, based on the backscatter changes. 
4. RESULTS. 
The joint investigations of landscape dynamics in the area under 
study with RADARSAT and TM/Landsat scenes, support by 
ground control, were the identification of the following 
vegeiation cover types: primary forest with and without 
bamboo, secondary forest (initial, intermediate and advanced 
stage of succession). Pasture, burned and deforested areas were 
also identified. Based on those information obtained during 
field surveys related to sampling areas (18) of different types of 
vegetation cover, it is possible to show the behavior of 
RADARSAT backscatter (linear gamma values) for different 
seasonal conditions (Figure 2) 
  
Gamma Mean Values 
  
  
P 
P 
P 
P 
PFB1 
PFB2 
PFB3 
InSS1 
InSS2 
ItSS1 
ItSS2 
ItSS3 
ASSI 
ASS2 
ASS3 
ASS4 
ASSS 
[—e— May, 15 th —B— October, 23th | 
InSS - Initial Secondary Sucession 
ItSS = Intermediate Secondary Sucession 
ASS = Advanced Secondary Sucession 
PF = Primary Forest 
PFB = Primary Forest with Bamboo 
Figure 2. Diagram of RADARSAT backscatter from primary 
and secondary forest samples for different seasons. 
Generally speaking, the highest amplitude of backscatter values 
(y°) for different seasons, was observed in areas covered with 
primary forest with bamboo and secondary forests in growth. 
Those areas of primary forest with bamboo (Figure 3) have a 
relatively low biomass (76.78 to 113.12 ton/ha), which explains 
the high density of this species, where there is a high 
competition for the occupation of physical space vis-à-vis 
woody species that are commonly found in primary forests. The 
height of individuals of the genus Bambusa constitutes the 
upper canopy of the forest, presenting a significant spectral- 
textural response at satellite data, specially those ones that 
backscattering mechanism of the interaction is classified such as 
“direct scattering in the crown” (Dobson et al., 1992). The 
phases of growth and senescence of these bamboo communities 
are determinant for the variations of backscatter found. 
  
Figure 3. Typical features inside a forest with bamboo species 
(Guadua weberbaueri Pilger). 
528 Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
  
  
  
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