1114
Figure 2 : Comparison between simulated aboveground biomass and measurements.
COUPLING WITH A REFLECTANCE MODEL
The modelling of the optical behaviour of a sahelian landscape must be done at a spatial scale compatible with
the (coarse) spatial resolution of the sensors used for regional applications (a few km 2 ). The landscape is
typically a sandy soil partially covered with mainly three vegetation layers: a herbaceous layer (20-80% cover)
dominated by annual grasses, a shrub layer (0-20% cover) and a sparse tree layer (0-5% cover) (Le Houirou,
1989). In the field of view of the remote sensor, however, the heterogeneous landscape is seen as an integration
of contributions from components with contrasting spectral behaviours. At that scale, the effects of the shrub
and tree layers have been neglected as for the ecosystem model, but the herbaceous layer being rarely totally
covering, bare (bright sandy) soil must be considered.
A Simple Area Additive reflectance model of the landscape
The soil-vegetation composite reflectance problems have already been investigated by Richardson and Wiegand
(1989) with the experimental data of Huete (1985) for a developing cotton canopy. Two composite scene
reflectance models were compared: the additive-independent reflectance model in which the response of
different components are considered independent and are added after being linearly weighted by their
respective cover fractions, and the transmittance-reflectance interactive model where light reflecting both from
the soil through the canopy and from the canopy itself are considered. Although their results confirm that the
composite canopy reflectance is an interactive mixture of plant, soil and shadow reflectances, in the present
study, the soil and the vegetation components will be considered independent This assumption, which has also
been made in several studies on semi-arid environments (Graetz and Gentle, 1982; Pcch et al., 1986; Rambal et
al., 1990; Hanan et al., 1991) is reasonable considering the fact that in the Sahel the grass canopy is rarely very
tall such that shadowing and adjacency effects at our spatial scale have been neglected. Besides, the effect of
soil beneath the canopy is implicitly accounted for in modelling the reflectance of the vegetation component
The vegetation itself can be separated into green and dry components. However, they have been considered
independent components and their complex interactions overlooked, mainly because after maturation they
actually coexist in comparable amounts only for a short period of time. Litter biomass also influences the
optical properties of the ground, but it is too intimately mixed with the soil to be considered a separate
component. Instead of being neglected, it is included in the soil component So, the scene reflectance R in a
given waveband and at any date during the growing season is written :
