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ACCURACY ANALYSIS OF DIGITAL ORTHOPHOTOS FROM VERY HIGH
RESOLUTION IMAGERY
Ricardo Passini * , Karsten Jacobsen **
* BAE SYSTEMS ADR, Mount Laurel, NJ, USA
** University of Hannover, Germany
*rpassini(Z)adrinc.com
**jacobsen@ipi.uni-hannover.de
WG IV/7
KEY WORDS: High resolution, Satellite, Orientation, Matching, DEM/DTM, Orthoimage
ABSTRACT:
The generation of digital Orthophotos now days can be done with aerial, but also very high resolution space imagery. For a real
competition the geometric and radiometric quality has to be on the same level. Different QuickBird images have been used for the
generation of orthophotos with Im pixel size. The whole procedure from the orientation up to the final step has been analyzed in
detail. Rational polynomial coefficients (RPC) and bundle orientation using orbit information was used for the handling of
QuickBird Basic and Standard Imagery. The special problems of individual and combined scenes are analyzed.
QuickBird Images covering quite different areas were used. The effect of varying control point distributions on the accuracy,
determined with independent check points was studied. Different sources of ground control like digital orthophoto quads, existing
information from airborne photo flights and GPS-control points have been used. The required height information came from
different digital elevation models (DEM) and ground survey. Satisfying results have been achieved.
1. INTRODUCTION
Accepting the rule of thump for which in topographic maps a
pixel size of 0.05 to 0.1 mm in the map scale is required, with a
Ground Sample Distance (GSD) or a pixel size in the terrain of
61 cm a map at a scale up to 1:6,000 can be designed. Also
accepting the fact that in an ortho-image there should be a
minimum of 8 pixels/mm (otherwise the pixilation becomes
visible), then based on a GSD of 60 cm the ortho-image design
scale can be as big as 1:4,800. 61cm is the nominal GSD of the
QuickBird B/W Panchromatic band for a nadir view, hence
when working with this satellite imagery, maps up to a design
scale of 1:6,000 and orthophotos of 1:4,800 are possible. In
addition to the aspect of information contents, also the
geometric potential is important. This is depending upon the
precise identification of objects in the images and the image
geometry itself along with a sufficient mathematical model.
In the present investigation different available mathematical
models for the ortho-image generation using QuickBird
imagery have been studied. Different sources of Ground
Control Point (GCP) information, different number and
distribution of GCPs, different number and arrangement of
images and different environmental scenarios (i.e., dry urban
desert, humid farming areas) have been included in the study.
2. SENSOR INFORMATION
Basically the QuickBird Images are of line scanner type. As
such the image geometry is central perspective in the line
direction. In this sense the exterior orientation parameters of
each line are different, but the relationship of the exterior
orientation to the satellite orbit is only changing slightly. Hence
for the classical CCD-line cameras, the attitudes are not
changing in relation to the satellite orbit. The Earth is spinning
in this system. The projection centres are located in the satellite
orbit — this can be expressed as a function of the image
components in the orbit direction.
The new generation of sensors has the flexibility of changing
view direction while acquiring the image. In this sense the
sensors can change continuously the view direction in such a
way that their image lines are located parallel to local or
national East — West map projection grid direction. This is a
continuous on the orbit change of the yaw and roll movements
to reach the scene border line with a fixed east value. This is
shown in Figure 1.
Figure 1: imaging
geometry of the very
high resolution satellite
systems with flexible
view direction
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