to have the consistent band numbers and wavelength. Then the
resampled spectrums and the maximum spectral angle 0.05
were used to classify. The classification result of SAM was
shown as Figure 6. Comparison with the result and a known
distribution map, the extraction effect of oil slick was good.
Known
oil
Hydro
carbon
sample
well
Figure 6. Hydrocarbon information extracted from Hyperion
image by SAM
4. RESULTS
(1) When the content of crude oil in soil is little, the double
absorption characteristic in 1748nm and 2330nm for petroleum
hydrocarbons in soil is very weak, and it is easy to be interfered
by other soil composition. Then the accuracy of detection using
the feature for petroleum hydrocarbons in soil was reduced.
When the crude oil is up to certain amount, it can make a
hyperspectural remote sensing detection for soil with petroleum
hydrocarbons using the diagnosis characteristic of spectrum.
(2) The reflectance of water that was covered with oil slick was
higher than seawater, while the slope that was indicated the
changing rate was lower. The broad absorption feature was
shown in 508nm with the decreasing of the oil slick’s thickness.
And the absorption characteristic peaks of oil slick reflectance
were not obvious in the other band regions.
(3) Based on the three bands in Qaidam Basin’s Hyperion
image, which was near the absorption characteristic peaks in
1730nm, Three-Band-Ratio algorithm and Absorption-Depth
method were used to extract oil-gas hydrocarbon and delineate
the target area of oil-gas reservoir.
(4) Based on the identification of characteristic spectrum of
alteration mineral and Hyperion image in Qaidam Basin, Linear
Spectral Unmixing (LSU) and Spectral Angle Matching (SAM)
can be used to determine he mineral composition counterparts
of endmember. Then the target area of oil-gas reservoir can be
determined indirectly.
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
(5) Combining with the optimal bands in the region of
visible/near-infrared, Spectral Angle Matching (SAM) was used
to extract the thin oil slick of microseepage in Liaodong Bay. In
addition, the spectral angle was determined by experience.
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ACKNOWLEDGEMENTS
This research is financially supported by National Natural
Science Foundation of China (Grant No. 40971186). And an
expression of thank for the help of China Aero Geophysical
Survey & Remote Sensing Center for Land and Resources and
PetroChina Exploration and Development Research Institute.
