Full text: Proceedings, XXth congress (Part 4)

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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
belong to group of AIOH bearing minerals e.g. Pyrophyllite and 
Alunite. Jarosite represents sulphite minerals and has absorption 
feature at 2260 nm. Minerals with absorption feature near 
2327.5 nm belongs either to CaCO; or MgOH bearing minerals 
— this group of minerals represent Calcite, Chlorite or Talc. 
Group of minerals which has absorption feature near 2205 nm is 
represented by Montmorillonite, Kaolinite, Muscovite or Illite. 
Whilst will be not possible to map particular minerals using 
ASTER imagery, it will be possible to differentiate between 
mentioned mineral groups. 
Selection of endmembers. Selecting of different types of 
endmembers which represent spectrally most extreme pixels in 
the scene has been provided by support of pixel purity index 
technique (PPI). PPI is a means of finding the most “spectrally 
pure” pixels typically correspond to mixing endmembers. The 
PPI is computed by repeatedly projecting n-dimensional 
scatterplots onto a random unit vector. The extreme pixels in 
cach projection are recorded and the total number of times each 
pixel is marked as extreme is noted (ENVI User’s Guide). 
The spectra with specific spectral characteristics or of areas 
important for geological setting has been also studied, but have 
not been noted as extreme and are not used for spectral 
analyses. The image scene has been divided into several areas 
according to conclusions of image interpretation and has been 
focused to map geological and geographical phenomena 
occurring on peninsula. 
Matched filtering is an ENVI software technique which 
performs partial unmixing — finding the abundances of user 
defined endmembers. Not all of the endmembers in the image 
need to be known. This technique maximizes the response of 
the known endmember und suppresses the response of the 
composite unknown backgroung, thus “matching” the known 
signature. It provides a rapid means detecting specific materials 
based on matches to library or image endmember spectra and 
does not require knowledge of all endmembers within an image 
scene (ENVI User’s Guide). Bands 4-9 have been processed by 
Matched Filtering in order to map area according to its SWIR 
spectral signatures. Following spectra have been collected: 
a/ WpoolW — which represents the pixels with 2205 nm 
absorption, no pixels with absorption at 2205 and without 
absorption at 2237.5 nm at the same time have been found in 
the image scene. 
b/ Solonchak — represents pixel with deepest absorption feature 
at 2165 nm 
c/ Dunes bright — represents pixels with absorption at 2165 nm 
and with no absorption at 2237.5 nm 
d/ Top of duine — represents pixels with absorption at 2165 nm 
and 2237.5 nm 
e/ NE pool — represents pixels with deep absorption at 2237.5 
nm 
    
Spectral Library Viewer 
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Figure 7. Spectra of selected endmembers in the SWIR. 
The study area has been successfully mapped using matched 
filtering procedure. Results of matched filtering are shown as 
three endmembers colour composite (in red, green respectively 
blue colour) where higher matches are represented by brighter 
pixels. Figure 8 shows western part of Red Series outcrops 
where pixels with different spectral signatures are mapped. The 
randomly collected spectra of bright pixels demonstrate that 
technique is able to classify image according to spectra 
signatures (plot). 
  
  
  
Wavrlenalh 
Figure 8. The matched filtered image of west part of Red Series 
shows different spectral signatures along the profile (red line). 
Red pixels (both in image and plot) have absorption feature at 
2205 nm and 2237.5 nm, green and blue have absorption both 
2165 nm and 2237.5 nm, when green one have deeper the first 
absorption feature and blue ones the later. 
3. CONCLUSIONS 
Analysis of ASTER spectral reflectance data of Cheleken 
Peninsula provides promising results. ASTER imagery allowed 
us to carry out preliminary geological investigation of the area 
and find encouraging research methods in terms of mapping the 
main geological phenomena occurring around the peninsula. 
False-color composite images are useful to get an overview 
about the area and map different types of rocks and land covers. 
Band rationing is a mean to map Red Series (ASTER band 1/ 
band 2) and distribution of hydroxyl and carbonates bearing 
minerals. Thanks to Matched Filtering technique surprising 
facts have been discovered — two types of areas influenced by 
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