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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
(angles, the position of the panel with respect to the sun and to 
the sensor) should be consistent from one measurement to next. 
23 Sky radiance 
The spectral sky radiance signal is measured by pointing the 
ASD sensor towards the sky, in the same vertical plane in 
which previous measurements have been performed. The 
viewing zenith angle should be equal to that of a radiance beam 
whose specular reflection on the water would yield a radiance 
beam equal to the Zenith angle used for the seasurface 
measurements. Measurements under cloudy skies are of little 
interest since the sky radiance distribution becomes less 
uniform, giving less information on the wavelength 
dependency. The best conditions are those for a clear, uniform 
sky. 
24 Remote sensing reflectance 
The reflectance Rrs (0, 6, A) is found according to following 
formula: 
Rrs (0, 6, à) = Lw(0, 6, à) / Ed(A) (2) 
Where 0, $, X stand for zenith and azimuth angles, and the 
wavelength at which the reflectance is calculated. Lw(0, 6, À) 
is the waterleaving radiance at a particular wavelength and at 
the viewing geometry. It is not possible to detect this 
component directly. At a given wavelength, the measured 
seasurface radiance is the combination of the waterleaving 
radiance (Lw) and the sky radiance reflected from the 
seasurface (Lr): 
Lt(0,0) ^ Lr(0,9) * Lw(0,0) (3) 
where Lt stands for the total radiance detected by the sensor 
pointed towards the seasurface at a zenith angle 0 and an 
azimuth angle ¢. So Lw can be found by subtracting Lr from 
the total radiance. To find the Lr, the sky radiance data is used, 
by supposing that a portion p of the sky radiance Ls(0,0") is 
reflected by the seasurface: 
Lr(0,4) = p . Ls(0,9^) (4) 
Here, p is a proportionality factor, defined as the total skylight 
reflected from the wave-roughened sea surface divided by sky 
radiance at the same given zenith and azimuth angles. Finally, 
starting from collected data, the reflectance at a particular 
geometry and wavelength is calculated as: 
Rrs = (Lt-p.Ls) / | (1/pg).Lg 1 (5) 
assuming to a good approximation that Spectralon is a 
Lambertian reflector (Mobley, 1999). 
3. SAMPLING LOCATION AND PERIOD 
Within the frame of the project, a set of research cruises have 
been performed from right after the ice cover melts to late fall. 
327 
10 subregions of the ecosystem have been predefined, based on 
the previous knowledge obtained from oceanographic 
researches on the system. The set of parameters have been 
measured following SeaWiFS protocols (Mueller and Austin, 
1995 cited in Larouche 2000). The stations are shown in the 
figures 1 and 2: 
52°, 
    
bai 
38° 57° 56 
   
  
‘ad T 
62° 61° 59 
   
70° 69° 68° 67° 65° 67 Of 63 
Fig.1 The stations in the estuary and the Gulf of St. Lawrence. 
  
  
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Sea WiFS campaign 
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Fig.2 Estuarine stations. 
The radiance data is collected both at the stations and at the 
transects between stations, while the ship is in motion. A 
number of spectra has been obtained at each station and from 
each transect (except for when it rained). A spectrum is 
obtained by taking a series of 10 separate measurements from 
each of the seasurface, panel, shaded panel and sky. Before 
processing, the spectra must be checked to eliminate the 
saturated ones either manually or automatically using a 
software program. Furthermore, up to two spectra which 
deviates highly from the average are removed. Then, the 
remaining spectra are averaged for each series of measurements 
and the reflectance spectra is computed for each seasurface- 
panel-shaded panel-sky sequence. 
4. PRELIMINARY RESULTS AND DISCUSSION 
Given the high spatial variability, the first step is a spatial 
classification of the spectral behaviour based on preliminary