International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
imaging conditions were well within bounds for reliable oil 
slick detection. 
One additional feature of interest appears on the 29 May image. 
The platform is obviously trailing a small, wind-driven slick 
that extends 10 kilometres to the southwest and the bend nearly 
perpendicular to ESE. This bend seems to be due to a change of 
surface current. Oil platforms and vessels appear as bright 
spots, generally indistinguishable unless the well locations are 
superimposed on the images. A few vessels can be 
distinguished by the presence of short, faint lines that indicates 
a trailing ship wake. The size of the longest slick detected was 
25 km. The characteristics suggest that the slicks are ephemeral 
surface events from a moving source, probably oil spills from a 
passing vessel moving down from north to south. 
3.4. Field Observation in Offshore Fujairah (Feb 2003) 
A Sea surface observations with a synchronized data acquisition 
of SPOT-5, in Fujairah Offshore Anchoring Area (FOAA) 
(Figure 4). Space borne observations were carried out on Ist & 
2nd February 2003 with the cooperation of UAE Coast Guard. 
Observation points were located by both a GPS system on 
board and portable GPS receivers. Spilled oil and seafloor 
sediments were sampled for chemical analysis. Water 
temperature was measured by both thermal infrared 
thermometer and contact thermometer. 
v 
         
  
  
    
     
   
  
     
Check Point 
   
56°25.193’| 25°23.069° 
56°25.177°|25°23.127° 
56°29.681°|25°20.200° 
556°33.109°|25°15.221° 
56°29.318(25°11.338’ 
   
  
  
Fujairah 
^. 
de 
e 
s * am Hodursui 1 SAR Lomas ap 
("ox 
EG CL 4 + RE N © amd ht kt 
Ba TLS Frain LT Fo rere 4 Med IUS 
Figure 4. Field Observation in Offshore Fujairah (Feb 2003) 
5. CONCLUSION 
We focused on discriminating between direct hydrocarbon 
pollution such as big spills by tanker accidents, discharged oil 
caused by routine maintenance, and leaking oil from offshore 
exploration and development operations by means of satellite 
imagery. Satellite-borne sensors have different electromagnetic 
characteristics with varying limitations for detecting marine 
surface features, therefore a combination of sensors is required 
to monitor marine oil pollution effectively. This case study 
indicates that most oil spills are found along the major shipping 
routes and in anchorage area as well as in such areas with 
intensive large-scale oil production activities with leakage or 
tank-washing discharges. The results will help in locating 
potentially vulnerable areas, and serve as a reference in future 
routine monitoring. Oil spills can occur both in the open sea and 
along the coasts. 
Operational monitoring system for oil pollution using satellite 
images of the Arabian Gulf is recognised as a regional priority, 
this could be achieved only with the cooperation of all 
concerned organizations at national and regional level. This will 
be based on an integrated GIS focusing on delivering real-time 
information on coastal marine environments Figure 5). 
5. REFERENCES 
Alpers, W., and H. Huhnerfuss. 1988. Radar signatures of oil 
films floating on the sea surface and the Marangoni effect. 
J.Geophys. Res., 93, 3642-3648 
Bern, T.-L, T. Wahl, T. Andersson, and R. Olsen. 1992. Oil spill 
detection using satellite based SAR: Experience from a field 
experiment. Proc. IstERS-1 Symposium, Cannes, France, 4-6 
November 1992, 829-834 
Espedal, H.A., O.M. Johannessen, J.A. Johannessen, et al. 
1998. COSWATCH'95 ERS 1/2 SAR detection of natural film 
on the ocean surface. J. Geophys. Res., 92, 24969-24982 
Gade, M.. W. Alpers, H. Huhnerfuss, et al. 1998. Imaging of 
biogenic and anthropogenic ocean surface films by the 
multifrequency/multipolarization SIR-C/X-SAR. J. Geophys. 
Res., 103, 18851-18866 
Gade. M., and S. Ufermann. 1998. Using ERS-2 SAR images 
for routine observation of marine pollution in European coastal 
waters. Proc. of IGARSS 98, Seattle, USA, July 6-10, 1998 
Huhnerfuss, H., Alpers W., Fast O.. et al. 1986. On the 
discrimination between crude oil spills and monomolecular sea 
slicks by airborne remote sensors - today's possibilities and 
limitations. Proc. Of IGARSS'86, Zurich, 8-11 September 1986, 
1359-1364 
Huhnerfuss, H., W. Alpers, W.L. Jones, et al. 1981. The 
damping of ocean surface waves by a monomolecular film 
measured by the wave staffs and microwave radars. J. Geophys. 
Res., 86, 429-438 
Ivanov, A.Yu. 2000. Oil pollution of the sea on Kosmos -1870 
and Almaz-1 radar imagery, Earth Observation & Rem. 
Sensing, 15(6), 949-966 
Ivanov, A.Yu., K. *. Litovchenko, and S.A. Ermakov. 1998. Oil 
spill detection in the sea using Almaz-1 SAR. J. Adv. Mar. Sci. 
Tech. Soci., 4(2), 281-288 
Kotova, L., H.A. Espedal, and O.M Johannessen.1998. Oil Spill 
Detection Using Spaceborne SAR: a Brief Review. Proc. 27" 
Int. Symposium on Remote x ensing Environmental, 8-12 June 
1998, Tromso, Norway, 791-794 
Lu, J., L.K. Kwoh, H. Lim, et al. 2000. Mapping oil pollution 
from space, Backscatter, February, 23-26 
662 
Interi 
  
Masu 
Obse! 
Japan 
229 
Okan 
result 
to Ja 
Hamt 
Pavlc 
-Spill 
Obsei 
Sabin 
Inter 
Surfa. 
Office 
‘alen 
electr 
Meteo 
Witte, 
radar.