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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part Bl. Istanbul 2004 
  
  
  
  
  
  
  
  
  
  
  
  
  
Test region Percentage of pixels with accuracy better than Percent of bad 
DLR-DTM im 2m 5m 10m correlation Bemarks 
01 17.0 16.1 30.8 15.2 20.8 
02 20.1 17.2 25.9 14.1 227 
03 20.9 18.0 30.7 15.9 14.4 
04 19.7 16.7 27.4 13.6 22.6 
05-1 4.9 4.6 10.2 14.3 66.0 very bad correlation 
05-2 8.0 7.1 16.1 13.8 55.0 very bad correlation 
06 14.9 14.1 31.7 25.1 18.2 
  
  
  
  
  
Table 5. Accuracy of DTM for the test regions (raw DTM 20m pixel size interpolated to reference DTM) 
  
Test region (DLR-DTM) 
  
Accuracy of DTM 
03 04 031 05 2 06 
  
  
  
  
RMSE +26 13 
  
  
  
  
  
  
t24 4.2.5 + 14.2 t67 12.8 
  
Table 6. The RMSE of DTM generated for different test regions from HRS SPOT 5 
5. THE ACCURACY OF DTM GENERATED ON THE 
BASIS OF PANCHROMATIC HRS SPOT 5 STEREO 
IMAGES 
Epipolar images and OV's have been generated for two stereo 
images: 01-02 and 03-04. PCI Ortho Engine has been used for 
matching and DTM generation. Matching and DTM generation 
have been performed for both stereo scenes with pixel 20m as 
16-bit image data in GeoTiff format. DTM have been extracted 
only for the 7 test regions. Next, the DTM have been 
interpolated to the pixel size as given in reference DTM data. 
Generated DTM has neither been verified in order to eliminate 
gross errors nor edited. The result of comparison tests is shown 
in table 5. 
For five of the test regions 60% of results of DTM is in the 
range from Im to 5m. The detailed analyses of histograms of 
images representing DTM and results are shown in table 6. 
6. CONCLUSION 
The use of well-elaborated methodology of correlation 
measurement on the panchromatic HRV SPOT 4 images 
permits to achieve DTM with the accuracy similar to the 
accuracy of raw DTM generated on the basis of the 
panchromatic HRS SPOT 5 images. SPOT 4 Pan stereo 
data can be used for generation of contour lines with 20 
m interval and orthophotomaps in scale 1:25 000. 
Technology for generation of DTM for orthophotomaps 
in scale 1:25 000 from HRV SPOT 4 Pan stereo data can 
be used for mapping and up-dating topographic maps in 
Africa and in Europe including Poland. This technology 
can be also adopted for new satellite data like IKONOS 
and QuickBird stereo data. 
To increase the accuracy of raw DTM generated on the 
basis of the panchromatic HRS SPOT 5 images the use of 
suitable editing and filtering techniques as well as 
additional supplementary measurements (breaklines, 
etc.), especially for mountainous and hilly terrain is 
recommended. 
The use of proper methodology for correlation measurement on 
the basis of the panchromatic HRS SPOT 5 and for HRV SPOT 
4 stereo images will permit to generate DTM with accuracy in 
elevation better than 2m. 
REFERENCES 
References from Journals: 
Cooper, P. R.. Friedman, D. E, Wood, S. A. 1937. 
The Automatic Generation of Digital Terrain Models 
from Satellite Images by Stereo. Acta Astronautica, 
15 (3), pp. 171 — 180. 
Day, T. Muller, J. P., 1988. Quality Assessment 
of Digital Elevation Models Produced by Automatic 
Stereo — Matching from SPOT Images Pairs, 
Photogrammetric Record, 12 (72), pp. 797 — 808. 
El-Manadili, Y., Novak, K., 1996. Precision Rectification 
of SPOT Imagery Using’ the Direct Linear 
Transformation Model. Photogrammetric Engineering 
and Remote Sensing, Vol. 62, pp. 68-70. 
Krupnik, A. 2000. Accuracy Assessment 
of Automatically Derived Digital Elevation Models from 
SPOT Images. Photogrammetric Engineering and 
Remote Sensing, Vol. 66 (8), pp. 1017-1023. 
Toutin, Th., 1999. Stereo-Mapping with SPOT-P and 
ERS-1 SAR Images. International Journal of Remote 
Sensing, 20 (15). 
Westin, T., 1990. Precision Rectification of SPOT 
Imagery. Photogrammetric Engineering and Remote 
Sensing, Vol. 56 (2), pp. 247-253. 
References from Books: 
Linsenbarth, A., 1987. Satelitarne systemy teledetekcyjne. 
Wydawnictwa Politechniki Warszawskiej. 
Kaula, W. M., 1966. Theory of Satellite Geodesy. 
References from Other Literature: 
Angleraud, C. Becek, K. Trinder, J. C. 1992. DEM 
determination from SPOT. In: The International Archives 
of the Photogrammetry, Remote Sensing and Spatial 
Information Sciences, Washington D. C., USA, Vol. 29/B4, 
pp. 969-973.