International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
investigation of data throughout the estuary-gulf system. Such 
an approach may eventually reveal useful correlation between 
optically active components and spectral behaviour.Systematic 
differences between different regions suggest that it is possible 
to classify the St. Lawrence system into sub regions 
characterized by different inherent and apparent optical 
properties. The preliminary results suggest high Gelbstoff and 
low suspended sediment influence in the estuary, while gulf 
region is mainly dominated by oceanic Case-I waters. (Figures 
3 and 4) 
Sta 112 May 2000 
0.016 
DOM. — 7 
0.012F 
Qo A 
nc 
© Y 
0.008 - 
0.006 + \ 
0.004 r \ 
Reflect 
0.002 } ta 
  
| TZ | 
  
400 450 50 50 60. 60°. 705 750 aw 
Wavelength [nm] 
Fig.3 Station 112, Gulf. Closer to Case-I properties. 
(Two sets of measurement) . 
Sta013 - Rho - 0.028 May 2000 
  
D.025 T T 
0.02} ZN J 
0.015} A 4 i - 
Reflectance 
2e 
ce 
- 
T 
L 
post Y - 
  
  
À 1 1 1 | 1 Sp ge = 
450 500 550 600 650 700 750 800 
Wavelength [nm] 
  
0 
e 
Fig.4 Station 13, estuary. Closer to Case-II properties. 
(Two sets of measurement) 
Sky reflectance by the seasurface is the main contaminant 
factor. Selection of p is the main focus and it is important as 
well in overcast skies, where it can be less than 0.028 (the 
recommended value for overcast skies in the literature, Mueller 
et.al, 2000) Shorter wavelengths seem to be less consistent 
since they are more affected from sky reflectance, whitecaps, 
seastate, and wind. 
References 
and J.-C. Therriault, 1998. 
in Pigment-Poor 
N.T. O'Neill 
Remote Sensing Potential 
Jacques A, 
Chlorophyll 
328 
Moderately Turbid Case II Waters: Lower St. 
Estuary . CJRS, vol. 24, no. 2, pp. 194-199. 
Lawrence 
Jacques, A. (2000). “La teledetection passive de la chlorophylle 
dans l’Estuaire maritime du Saint-Laurent: optimisation 
spectrale des algorithmes de télédétection et application au 
SeaWiFS" PhD thesis, Departement de Géographie et 
Télédétection, FLSH, Université de Sherbrooke, Québec, 
Canada. 
Koutitonsky, VG et GL Bugden, 1991. “The physical 
oceanography of the Gulf of St. Lawrence: A review with 
emphasis on the synoptic variability of the motion. In: The Gulf 
of St. Lawrence: small ocean or big estuary?, J.C. Therriault 
(Ed.), Can. Spec. Publ. Fish. Aquat. Sci., Vol. 113, pp. 57-90. 
Mobley C.D., 1999. Estimation of the remote-sensing 
reflectance from above-surface measurements. Applied Optics, 
38(36), pp.7442-7455. 
Mueller J.L., C. Davis, R. Arnone, R. Frouin, K. Carder, Z.P. 
Lee, R.G. Steward, S. Hooker, C.D. Mobley and S.McLean, 
2000. "Above-water radiance and remote sensing reflectance 
measurement and analysis protocols", Chapter 10, NASA/TM- 
2000-209966 OCEAN OPTICS PROTOCOLS FOR 
SATELLITE OCEAN COLOR SENSOR VALIDATION, 
revision 2 edited by Giulietta S. Fargion and James L. Mueller. 
NASA-GSFSC, August 2000. 
Pierre Larouche, 2000. “Results from the 2" St. Lawrence 
Estuary and Gulf SeaWiFS Validation Cruise”, Sixth 
International Conference on remote Sensing for Marine and 
coastal Environments, Charleston, South Carolina, 1-3 May 
2000. 
S. Sathyendranath (2000) “Remote Sensing of Ocean Colour in 
Coastal, and Other Optically-Complex, Waters" Reports of the 
International Ocean-Colour Coordinating Group. IOCCG 
Report no:3, 2000. 
  
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