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In associated research at the same site the vegetation 
structural changes identified by radar analysis were shown 
to be significantly related to avian habitat quality (Imhoff 
and Milne, 1995) 
It is also becoming evident that in respect to tree 
branching patterns, models developed on boreal-temperate 
forests are not applicable to Australian flora. Work has 
begun on developing a canopy model that takes into 
account branch size and orientation as well as foliage 
cover in an attempt to separate foliage or green biomass 
from woody biomass in Northern Australian forests and 
woodlands. 
The ability to derive tree stand parameters directly from 
SAR depends on the development of inversion models 
that facilitate prediction based on radar scattering 
characteristics alone (Dong, 1995).  Correlative 
relationships between floristic induced structural changes 
and radar backscatter have been replicated in a modelled 
environment using wavelet transform techniques to 
suppress speckle noise and segmentation routines based 
on a Gaussian Markov Random Field Model (Dong et al., 
1998) 
This approach is currently being trialled in Kakadu 
National Park to test its ability to identify and classify like 
forest stands. If successful, these procedures stand to 
make a major contribution to the way SAR data is 
processed to derive geophysical information. Evaluation 
of a knowledge based classification technique that uses 
multi-frequency SAR to segment an image into different 
classes is being undertaken concurrently. 
CONCLUSION 
Wetlands are unique, diverse and valuable habitats for 
supporting aquatic and terrestrial life forms. They are 
areas of high conservation value and worldwide contribute 
significantly to global biogeochemical functioning. 
The study is innovative in that it attempts to relate radar 
backscatter to specific biophysical and environmental 
parameters. As seasonal change brings different soil- 
boundary-plant conditions, so backscatter can be expected 
to change. The objective of this study is to take measured 
environmental changes and relate these to received 
backscatter. 
The eventual ability to monitor and link diurnal, seasonal 
and episodic changes in biogeochemical properties to 
calibrated backscatter returns, provides the potential for 
radar to make a major input into the modelling of long 
term environmental change and to contributing to our 
knowledge of global processes. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
SELECTED REFERENCES 
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forested regions containing arbitrarily oriented woody 
structures, unpublished PhD thesis, The University of 
New South Wales, 193pp. 
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Dong, Y., 1995. A Long Wavelength Radar Backscatter 
for Forests, unpublished PhD thesis, The University of 
New south Wales, Sydney. 
Dong, Y., Forster B.C., Milne A.K., and Morgan G.A., 
1998, Speckle suppression using recursive wavelet 
transforms, International Journal of Remote Sensing, 
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Finlayson, C.M., Wilson B., Courie, I. Management of 
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Finlayson, C.M., Vegetation Changes and Biomass on an 
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547