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At secondary successions, the amplitude of seasonal changes of 
backscatter increases with the successional stage, from the 
initial growth to advanced stage (age > 15 years). Those areas at 
initial growth (age <S years) showing a more homogeneous 
canopy and with low species diversity, had a similar response at 
both RADARSAT datatakes analyzed (Figure 4). It is important 
to note that during the RADARSAT imaging of May 15th and 
October 23rd ‘96, there was rainfall of around 25 mm/day, 
which minimizes the effect of moisture, when comparing the 
backscatter of both dates. 
  
  
  
  
  
  
  
  
  
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Figure 4. Physiognomic profile of an initial secondary 
succession. 
At Figure 5 one can observe the seasonal backscatter (y°) values 
plotted against biomass for the vegetation types under study. 
The diagrams of data dispersion, independently of the 
RADARSAT imaging date, show that there is a very low 
sensitivity of the models to the relation backscatter against 
biomass. 
  
  
  
  
  
  
  
  
  
  
  
  
  
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Aboveground biomass (ton/ha) May, 15th 
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boveground biomass (ton/ha) Ociobe 298b 
€ Primary Forest ® Secondary Forest 
  
  
  
Figure 5. Diagrams of RADARSAT backscatter (1°) against 
aboveground biomass values of forest and secondary 
succession. 
The backscatter mean values (y?) for areas of secondary 
succession present a variation range from 0.1563 to 0.3309 and 
for areas of primary forest of 0.2078 to 0.2991. Even when there 
are distinct mean values of aboveground biomass for primary 
forest (170.25 ton/ha + 49.28), primary forest with bamboo 
(93.61 ton/ha + 18.32), initial secondary succession (35.66 
ton/ha + 13.48), intermediate secondary succession (56.33 
ton/ha + 11.02) and advanced secondary succession ( 85.62 
ton/ha + 26.73) there is no significant correspondence. The 
intensity of sampling (18 plots) was considered sufficient to 
characterize the needed measurements, totaling 600 trees of 
primary forest and 284 trees of secondary forest, measured at all 
sample sections. On the forest with bamboo, where the field 
measurements are difficult, specially due to the intense 
interlacing of these bamboo in the under-growth, where all trees 
and 508 thatches/0.2 ha were measured (DBH>2.5 cm). 
The intermediate and advanced regrowth classes present a 
significant amplitude of backscatter values, whose variation 
cannot be fitted into a theoretical model (behavior), which could 
express medium and high biomass values. A theory to explain 
such configurations could be related to the type of management 
(frequent burning, soil compaction, land use type and duration) 
used in this area before the regeneration process. In practical 
terms, the floristic and biomass recomposition of such areas is 
different. Furthermore there are limitations of C-band for the 
penetration beyond the canopy, and as a result there is a low 
saturation level (sensitiveness) for higher biomass values. 
The C-band images appear to be of little use to monitor biomass 
density in tropical forest under regeneration (Luckman et al., 
1997), although the maximum retrievable biomass estimate, 
suggested by the backscatter response is 38.6 ton/ha. According 
to Imhoff (1995) the values for the broadleaf evergreen forest is 
around 20 ton/ha. At this study, the distribution of y? values 
against aboveground biomass allows to consider as adequate 
this relation at the maximum limit of 50 ton/ha. 
When we consider only the discrimination among those areas in 
the process of initial regeneration (Figure 4) from those sections 
that are structurally more developed or at climax (Figure 6) such 
as the primary forest, one can perceive that they occupy a 
distinct space of attributes at the backscatter. 
  
  
  
  
  
  
    
  
in. Platycyamus ulei à (Fabacose) 2 Sloarea brevipes [Else 
(Martius (Aracacoae) 5. Sor 'orocea sp (Moraceae] 
! Tetragastris 
!Sociatea exonhiza (Mart ) (^ ) 14. H Sra as ul Sup ([Euphorbi 15. Carapa guianensis Aublet (Meliaceae) 16. Metrodorea 
flavida Krause (Rutacoae) 17. Caron us Moracase }1 à Ectecies ened 19 nla 20. Carapa guianensie Aublet 
{Melacess) 21. Pseudolmedia laevis (R. ! PINS Mate) 2 tech = ca tapa guianensis Aublet (Melacose] 24. 
{Taie sp. (Sapindaceas) 25 Tot etragastris altissima (Aublet) Swert wart (Burseraceae) 26. Apeiba sp. (Ti 
  
  
  
Figure 6. Structural profile of the open tropical rainforest. 
This can be simply explained by the uniformity of the canopy of 
the initial natural regeneration, originated from only one stratum 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 529