191
vegetation
t cases, the
ilated using
in accuracy
nation. For
iwever, our
1 this study ,
2 structural
il variables
1 to similar
that it was
description
it lead also
to develop
e the effect
ome of the
itents were
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ructural or
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opy model
ire sensors
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vhen using
(fared that
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he soil and
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: minimum
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h level of
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nal use of
ime is only
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f hundreds
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relative to
lost of the
irmation is
iis type of
jvelopment
of biological models. The second problem is relative to the choice of the approach to be used. From these
preliminary results, it seems that inverting physical radiative transfer models did not necessarilly provide very
accurate estimates of canopy biophysical parameters. A compromise has to be investigated in between the
realism of the model that generally induces more complexity and more parameters, and the invertibility that
most oftenly requires a simplified model with very few variables to be estimated. Presumably, an alternative
approach would necessitates some a priori knowledge on the target, such as the specy, the type of soils, all kind
of information that could be derived partly from remote sensing and used to constrained the inversion process.
ACKNOWLEDGEMENTS
We are indebted to Dr. Kuusk for the improvement of the Fortran code of the SAIL model in
order to take into account the hot spot effect. Many thanks to J. Clark, J. Eastwood, J.F. Hanocq, T. Malthus,
andM. Steven for their support during the field experiments.
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