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After resampling the DSM to a pixel spacing of 10 m, the
comparison with the DEM was evaluated in order to emphasize
possible systematic or gross errors. As shown in the frequency
histogram of figure 8 the distribution of differences shows a
distribution with the 90% of pixel exhibiting a difference with
the reference elevation of + 20m.
FREQUENCY (%)
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CLASSES (meters)
Figure 8. Frequency histogram showing differences in the
comparison between the satellite-derived DSM and the DEM
used as reference
4. ORTHOIMAGE GENERATION
The orthorectification of the QuickBird image, based upon the
discussed DSM, has been performed using PCI Geomatica
software. The software adopts different geometric correction
models, among them the parametric rigorous model and the
rational polynomial model are the most accurate.
The rigorous model can be applied through the knowledge of a
certain number (around 20) of ground control points well and
evenly distributed over the whole scene.
The Rational Polynomial Model can be theoretically applied
without knowing ground control points, but just using the
coefficients (RPC, Rational Polinomial Coefficient) delivered
with metadata. In this work the transformation between UTM-
WGS84, that is the reference system in which RPC are
computed, to the National Gauss Boaga grid system, that is the
final required system, has been applied using a set of GCP in
the latter system.
It has to be noticed that the extension of the QuickBird scene is
wider than the EROS one, so the orthorectification could be
carried out only for the overlapping area.
4.1 Orthoimage accuracy assessment
Results of the orthorectification tests are generally expressed in
terms of Root Mean Square Error (RMSE) along the East and
North grid axis computed using a series of known and
independent checkpoints which are clearly recognizable on the
orthoimage. Several test have been experienced in the past by
the authors (Barbarella, 2003). On the other hand, it is well
known from literature that the accuracy achieved in the
orthorectification may be fixed in 1 or 2 pixels.
The overall quality of the final orthoimage map could be also
checked by the comparison with cartography at the higher scale
than possible. The "first look" comparison between the raster
orthoimage and the vector map available, with its related and
scale-dependent accuracy, would be useful in the identification
of critical area where the procedure fails. In figure 9 the
overlapping of raster orthoimages and vector layer is shown.
and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
Figure 9. Overlay of portion of the raster orthoimage and the
map layer. Comparison of the main features highlights
differences between products
5. CONCLUSIONS
The generation of Digital Surface Models from satellite high
resolution optical images and its use in the ortho-reprojection of
external HR satellite images (we discussed the case of a
QuickBird image) should be considered as a productive
methodology when the accuracy requested in map production
has to meet the requirements of cartography at scale as large as
1:10000. In particular, within the spatial methodology for
terrain modelling, the use of stereo-pairs acquired by the EROS
constellation may be considered one the possible choice,
considering the low cost of the raw data. Problems may arise in
the correlation procedure (low data quality, cloud coverage,
atmospheric effects or shadowing in densely urbanized area),
producing lack of data in the DSM or erroneous elevations.
REFERENCES
Barbarella, M., Mancini, F., Zanni, M., 2003. Rectification of
high resolution satellite data: evaluating accuracy for map
updating. Proceedings of the ASPRS/MAPPS conference
"Terrain data: application and visualization, making the
connection", Charleston, SC, USA, Oct. 2003.
Barbarella, M., Mancini, F., Zanni, M., 2003. Processing of
high resolution satellite data for map updating. Proceedings of
30th International Symposium on Remote Sensing of
Environment, Honolulu, Hawaii, USA, Nov. 2003.
Hirano, A., Welch, R., Harold, L., 2002. Mapping from ASTER
stereo image data: DEM validation and accuracy assessment.
ISPRS Journal of Photogrammetry and Remote Sensing, 57, pp.
356-370.
Jacobsen, K., 2003. Orthoimages and DEMs by QuickBird and
Ikonos. Proceedings of EARSeL: “Remote Sensing in
Transition", Ghent, 2003, pp.513 — 525
Siva Subramanian, K.S., Amitabh, S., Manda, S., 2003.
Evaluation of Digital Elevation Models created from different
satellite images. Proceedings of Map India Conference 2003,
New Delhi, India, Jan 2003
http://www. gisdevelopment.net/proceedings/mapindia/2003/tt. ht
m (accessed 27 Apr. 2004)
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