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Figure 7. A shaded relief of the generated DEM 
6. CONCLUSIONS AND RECOMMENDATIONS 
In this paper, we presented a comprehensive methodology for 
DEM generation from scenes captured by high resolution 
imaging satellites. The proposed methodology has two main 
characteristics. Firstly, the parallel projection has been used as 
the mathematical model approximating the relationship between 
corresponding scene and ground coordinates. The validity of 
this model is attributed to the fact that the imaging geometry of 
a narrow angular field of view scanner, moving with a constant 
velocity and attitude, resembles a parallel projection. In this 
regard, one should mention that the derivation of the parallel 
projection parameters does not require the knowledge of the 
internal and external characteristics of the imaging system. The 
involved parameters can be derived through a minimum of five 
ground control points. Secondly, the parallel projection model 
can be used to generate normalized scenes (i.e., resampled 
imagery according to epipolar geometry). The generation of 
normalized scenes is advantageous for DEM generation since it 
reduces the search space for conjugate points into 1-D along the 
epipolar lines as represented by corresponding rows. 
The resampled scenes are manipulated by an interest operator to 
extract point primitives with a unique grey value distribution at 
their vicinity. These points are then considered as candidates for 
the matching process, where the correlation coefficient has been 
used to evaluate the degree of similarity between hypothesized 
matches within. the involved scenes. Matched points are 
projected into the object space using an intersection procedure. 
Finally, derived object points undergo an interpolation 
procedure to produce a dense DEM over the area in question. 
Reported results from real datasets verified the validity of the 
developed approach for normalized scene generation, where 
almost zero y-parallax is observed between conjugate points. 
The derived ground coordinates from the SPOT-1 and SPOT-2 
data have been proven to be accurate within half a pixel. 
However, the derived ground coordinates from the SPOT-5 data 
have shown poorer performance, especially in the planimetric 
coordinates. Such inaccuracy can be either attributed to poor 
quality of the ground control points and/or problems with the 
data acquisition process. 
  
Future research work will be focusing on further investigation 
into the SPOT-5 dataset to identify the cause of the poor quality 
of the derived ground coordinates. Moreover, we will derive a 
quantitative evaluation of the quality of the derived DEM by 
comparing it to LIDAR data over the same area. 
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