International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
The potential of using drainage systems, i.e. the management
of water table depth, to function as sub-irrigation system
without increasing the accumulation of salts in the root zone
and is a valuable agricultural resource in arid regions (Benz
et al., 1984).
Plant water stress can limit productivity in both natural and
agronomic plant communities.: Short term as well as long
term water stress has the same effects on plant physiology
and canopy architecture. Changes in water status of a canopy
can have indirect effects on remotely sensed optical
reflectance and thermal emittance.
Surface temperature (T,) is a major component in the energy
balance equation. Several models have been developed to
evaluate crop water use, water stress, crop yield and soil
moisture (Reginato et al, 1976; Idso et al, 1981; Price,
1982; Reginato et al., 1985; Jackson ef al., 1987).
Several authors have investigated the combination of the
thermal band 6 of Landsat TM with the reflective bands in
the Red and NIR, band 3 and band 4, respectively. The
relationship between NDVI and T, is linear with negative
slope (Gurney ef al., 1983; Hope, 1986; Moran ef al, 1990),
This relationship could be diagnostic of plant water stress,
particularly, at large NDVI values. For a given
meteorological condition, the surface of bare soil would tend
to have a stable maximum surface temperature once soil
moisture is depleted. Accordingly, spatial variability in plant
available moisture (in the root zone) would not be reflected
in the T, of pixels dominated by bare soil (at small NDVI
values). Moreover, an increase in vegetation moisture stress
will cause the T, of pixels with large NDVI values to
increase. For partially irrigated fields and homogeneous crop
cover, the NDVI would be relatively unaffected by soil
moisture difference, whereas T, values would be low over
the irrigated portion and high over the dry portion (Moran et
al, 1990). Moreover, this was explained in terms of the
increase in the latent heat flux (LE) associated with greater
amount of transpirationally active vegetation (Hope and
McDowell, 1992). Table 1 list and define these vegetation
indices.
1144
In recent studies, the soil adjusted vegetation index (SAVI)
has been used in the combination of spectral and thermal
bands (Choudhury, 1994 and Moran ef al., 1994). The SAVI
has the advantage of being more sensitive to the increase in
vegetation cover and less sensitive to spectral changes in the
soil background than the NDVI (Huete, 1988). Moran ef al.
(1994)
index/temperature trapezoid (VIT) in an attempt to combine
proposed the concept of the vegetation
spectral vegetation index with composite surface
temperature. Since spectral vegetation indices are non-
linearly related to vegetation cover (Vc) then Vc is
substituted in the Y-axis in the trapezoidal relationship
between Vc and the temperature difference
(T. -T.).
Recent research has examined technologies involving remote
sensing to quantify water stress. Moran et al. (1989)
investigated the effect of water stress on canopy architecture
in alfalfa (Medicago sativa L.) and the sequential effect on
canopy reflectance. They found water-stressed canopies to
have a lower spectral reflectance in the NIR and red
wavebands when compared with unstressed canopies. A ratio
of the two wavebands was most successful in estimating the
onset of stress. Moran et al. (1994) investigated the concept
of a water deficit index, which is defined as the ratio of actual
to potential ET. This index exhibits the ability to predict ET
rate and relative field water deficit for both full-cover and
partially-vegetated sites. The measurement can be calculated
from remotely sensed data (red and NIR) gathered with
ground, aircraft, or satellite-based sensors. On-site
measurements used in the calculation include net radiation,
air vapor pressure deficit, air temperature, and wind speed.
The results of Shakir and Girmay-Gwahid (1998) showed
that in the wave length range of 850 - 1150 nm the stressed
plots showed lower reflectance than unstressed plots.
However the reflectance of stressed plots was higher above
the 1150 nm.
This study aims to studiy the effect of varying water table
depth alfafa spectral reflectance. And to examine if water
stress is likely to occure due to the variations of watertable
levels.
