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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXX V, Part B7. Istanbul 2004
The model in Equation 1 is linear and thus not affected by
saturation of backscatter response with increasing biomass
levels that has been reported as a general problem of forest
monitoring by radar (LeToan et al. 1992; Imhoff, 1995; Santos
et al. 2002).
Despite some difference in the response curves of the
logarithmic and exponential functions when relating biomass
and radar backscatter values, the P-band signal alone would
saturate around 100 ton/ha, as reported by Santos et al. (2003);
since here we also count with interferometric height (Equation
1), saturation of the radar response signal as a problem for
tropical forest biomass estimation does not occur any more.
In Figure 2 the variance of the forest biomass estimate is
graphically displayed in function of the observed data range of
interferometric height (h ;,,) and backscatter radar (6° yy). The
standard errors range between ca. 20-40 ton/ha. The biomass
estimates obtained by applying equation 1 are superior to
common approaches, because they are not only based on
backscatter signals, and because the variance of the estimate
does not increase exponentially with high quantities of
biomass.
Figure 2. Variance of biomass estimation as fuction of height
interferometry and basckscatter.
The segmentation of the DHM yields a division of the study area
in landscape patches by polygons, that would reflect individual
forest stands or management units of farms. As described above,
the mean interferometric height and mean P-band radar
backscatter are calculated for all polygons. A simple binary
classification is performed to distinguish forest cover and
agricultural/pasture areas. All polygons with mean interferometric
height > 2.6 m are classified as secondary succession or primary
forest; all polygons with hj, < 2.6 m are taken to correspond to
nonforest landuse, i.e. agriculture, pastures, etc.
Nevertheless, the biomass map was realized based on equation 1,
which describes only SAR data signals from the primary and
secondary vegetation. Polygons with nonforest classes are
masked out. The procedure yields a map that display the spatial
disctribution of standibng alive above ground biomass in forest
cover at the test-site in the Tapajós region (Figure 3).
5 ton/ha 350 ton/ha
Figure 3. Section of SAR interferometric height image and
biomass distribution map of land cover classes in the Tapajós
region. In the above figure, the dark areas correspond to
deforested areas (mainly pastures), the brightest grey levels are
primary forest, intermediate variations in tone reflect forest
successional stages.
4. CONCLUSIONS
This work shows a new approach to mapping and inventory
tropical forest biomass, which has become possible by
improved data quality related to the SAR data (considering both
backscatter signals and interferometric data). It largely enhances
biomass model precision due to the integration of
interferometric height measurements. It was also observed that
an adequate calibration of DSM and DEM is important for
height inferences, this is particularly true for initial and
intermediate successional stages, because the heights to be
measured are lower than for advanced stages. The segmentation
approach based on hierarchical region growth (representation by
pyramidal levels) applied on the DHM image demonstrated
potential for analysis and improvement of thematical
stratification by regions. The general problem of excessive
image segmentation, frequently observed in radar imagery, does
not occur when using the segmentation approach adopted here.
This study is a contribution to the Governamental Program
" . f - 4 QU
Science and Technology for the Management of Ecosystems
from the Ministry for Science and Technology (MCT), which is
looking for alternatives (remote sensing data) and for the
improvement of technological knowledge which might help in
the inventory and monitoring of forest resources in Brazil.
REFERENCES
Balzter, H. 2001. Forest mapping and monitoring with
interferometric synthetic aperture radar (INSAR). Progess in
Physical Geography, 25(2):159-177.
Chambers, J.Q.; Santos, J.; Ribeiro, R.J.: Higuchi, N., 2001,
Tree damage, allometric relationships, and above-ground net
primary production in central Amazon forest. Forest Ecology
and Management, 152: 73-84.
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