17
GOES and METEOSAT
zil (Holben et al., 1994)
here are plans to expand
ernational research and
\alysis of remote sensing
i of NASA and ADEOS
EFFECT
at describe the surface
rmospherically resistant
1 for remote sensing of
duled to be launched in
at TM, and the SeaWiFS
■linear gain the SeaWiFS
takes advantage of the
, in addition to the red
t compose the present
f ARVI to atmospheric
rrection process for the
diance between the blue
47
)
ally resistant vegetation
ation in the red channel
ation content of p is
t in the blue channel is
much smaller than that
at the reflectance in the
nospheric effect in this
tic and natural surface
similar dynamic range to
1 times less sensitive to
ant is much better for
e to small size aerosol
rticle size (e.g. maritime
le red channel is a bias
T was chosen so that on
positive and sometime
ospheric effect but also
resistance of ARVI, it is
expected that remote sensing from MODIS of the vegetation index over most land surfaces
will include molecular and ozone correction with no further need for aerosol correction,
except for dust conditions, like in the Sahel.
Fig. 7: The original vegetation
index, NDVI (dashed lines) and
the new vegetation index, ARVI
(solids lines), as a function of the
fraction of the surface covered by
vegetation for forest, grass and
alfalfa. Computations were
performed using the 5S radiative
code (Tanre et al., 1990). Solar
zenith angle is 60° and nadir view.
(After Kaufman and Tanre, 1992).
5. Polarization Measurements
FRACTION OF VEGETATION
Polarization measurements add an additional dimension to remote sensing. The
potential of polarization has been demonstrated in characterizing the atmospheres of
planets with large optical thickness like those of Venus and Saturn (Hansen and Hovenier,
1974; Santer and Herman, 1979; Dollfus, 1979) or for studying the surface of Mars where the
atmosphere is very tiny (Egan, 1969). Extensive measurements of the earth-atmosphere
system were provided by photographs in polarized light taken during the American space
Shuttle missions (Egan et al., 1989; Roger et al., 1994). Specific experiment was also
performed from balloon over ocean (Deuze et al., 1989)
What can we expect from polarization measurements over land? A major concern for
the use of polarized light over land surfaces is the capability to discriminate between
polarization generated in the atmosphere and that generated by the surface. In spring 1990,
an experiment was conducted in the southern part of France over land surfaces (Deuze et
al., 1993) with the POLDER airborne simulator (Deschamps et al., 1994). The 'La Crau' site,
in the south part of France over which the instrument flew, is composed of several zones
with different kinds of vegetation, grass, rice, wheat, sparse grass and bare soils. The land
cover was therefore non-uniform and displayed radiance contrasts. The surface
contribution to the polarized radiance was attenuated by the atmosphere. For wavelengths <
0.7 gm, the measured polarized reflectance at the top of the atmosphere exhibited a smooth
pattern suggesting that the polarized light is coming mainly from the atmosphere. At
A.=850nm, the images included high frequency variability indicating the larger relative
surface contribution. Since this experiment shows that polarized radiance in the green and
in the blue parts of the spectrum is mainly controlled by the atmospheric processes, the
satellite signal can be used for retrieving aerosols properties. In near future, polarization
measurements from satellites will be performed by the POLDER instrument (Deschamps et
al., 1994) aboard the ADEOS mission of NASD A in 1996 and by the EOSP aboard the EOS-B
of NASA in 2003.
