50
to convert radiance into reflectance. The use of equation (1), applied both to panel and ground measurements
permit to limit the reference to the panel (pratically difficult to be extensively used during this campaign) and
instead rely the conversion on a computation of the global irradiance. An other traditional way to obtain ground
reflectance, which has not been followed during the campaign, is to cross measure on the panel as often as
possible. By doing so, uncertainties on the aerosol models (such as the refractive index), which certainly affect
the comparison between laboratory and field measurements, can be avoided.
4. RESULTS
The measurement campaign lasted on average two days per measurement area. The sun radiometer was
operated all day during a measurement campaign, in order to provide the aerosol optical depth, at wavelengths
given in Table 1, in the morning and in the afternoon, using a standard Langley-Bouguer technique. As
described in § 3.2, these optical depths serve as inputs in a radiation transfer code to derive the total
atmospheric transmittance (i.e., the sum of the direct and diffuse irradiances measured at the surface, divided
by the exo-atmospheric irradiance). One obtains then the surface reflectance p(0 s , 0 V , 0) from the
measurements of normalized radiances using Eq. (1). Different measurements of surface reflectance have been
done on each measurement area to extract different parameters: spectral reflectance, BPDF and BRDF at
different times of the day, temporal evolution of reflectance during a few hours, and spatial variations of
reflectance.
4.1. Spectral reflectance
Measurements of spectral reflectance have been performed at various times and for various viewing
angle configurations with the REFPOL and ground radiometer instruments (Table 1). We report in Figure 1, as
an illustration, the measurements of spectral reflectance made with the ground radiometer at nadir over a flat
area in Algeria 5 on March 6, 1993. The spectral signature is measured when the sun is high (from 11,5 h UT
to 11,8 h UT), so that the zenithal solar angle variations do not exceed 1°. The sun zenith angle is about 35°.
Every 20s, a measurement is done which is, then, converted in surface reflectance. Figure 1 represents an
average of these measurements. The applied calibration coefficients have been chosen to be the average of the
calibration coefficients derived from laboratory calibration experiments of February 5 and March 22, displayed
in Table 3. The reflectance increases with wavelength (Figure 1), as expected, and reaches the unexpected high
value of 0.83 in the shortwave infrared The values of Figure 1 are surprinsingly rather different from those
obtained by Jaccoberger (1989) on sand dunes at the site of Bahariya (desertic Egypt), who found 0.38, 0.5 and
0.6 at 550, 650 and 850nm respectively (to be compared to our values, respectively 0.29, 0.55 and 0.67).
4.2. BRDF and BPDF
The radiometer-polarimeter REFPOL has been used to acquire several measurements per day of BRDF
and BPDF. The experimental protocol was as follows. Once a test area was chosen, the car carrying the
REFPOL instrument was driven along an axis such that when the car stops, the scanning plane of REFPOL
makes an angle of either 0°, 45°, or 90° with the solar principal plane. This axis was determined before the
experiment by disposing a number of markers on the test area. Due to driving difficulties on sandy ground, the
scanning plane orientation differs sometimes from the desired orientation by at most 5°; however, it is
measured once the car has stopped with an accuracy of the order of the degree. It is important that the test area
be not altered by car tracks; this implies in practice that one of the observation planes be measured on a test
area not strictly coincident with the test area used for the two other observation planes. The total acquisition of
3 observation planes lasted about 30 to 40 minutes, with a corresponding solar zenith angle variations of at
most 1° around midday and 9° in the morning and in the evening.
A representative example of the BRDF measurements is shown in Figure 2, which represents a BRDF
measured in Algeria 5 on March 5, 1993, around noon (0 S = 42°) and in the afternoon (0 S = 64°). The BRDF
shown in Figure 2 appears under the form of polar plots, where the polar angle represents the relative azimuth
0 between sun and view directions, and the radius represents the viewing zenith angle. The measurements of
reflectance have been normalized to nadir reflectances (the BRDF value at nadir is 1). The 0 = 45°
measurement has been duplicated symmetrically with respect to the 0 = 0° axis, and an isocontouring procedure
has been processed to interpolate the various measurements.
Figure 2 shows that when the sun is relatively high (here, 0 S = 42°), the reflectance is nearly Lambertian
in the forward scattering plane, except at 450nm (not shown) where the reflectance increases by 20% in that
plane. Some backscattering occurs in the backscattering plane, with an amplitude which decreases steadily with
wavelength (30%, 20%, 15% and 13% at 450, 650, 850 and 1650nm respectively). Directional effects are more
