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The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part Bl. Beijing 2008
design matrix, to select the estimable parameters and finally to
solve the linearized collinearity equations system in the least
squares (LS) sense.
SATELLITE
POSITION
O: right ascension of the ascending node
i: orbit inclination
e: satellite elevation at image centre
a: satellite azimuth at image centre
SENSOR
ATTITUDE
<|>=<|)o(t)+ao+a!t+a 2 t 2 (roll)
0=9 o (t)+bo+b i t+b 2 t 2 (pitch)
V=Vo(t)+c 0 +Cit+c 2 t 2 (yaw)
VIEWING
GEOMETRY
d_pix: pixel size
I 0 ,Jo,di: self-calibration parameters
Tab 2. Full parametrization of the SISAR model
The SISAR model was tested on Cartosat-1 images with
different features (for the features of all images see Tab. 3).
All the images in forward looking (FORE) have a swath of
30km and in aft looking (AFT) have a swath 26.6km except
Rome image that is not standard acquisition (swath 7.5km),
since only a short part of the CCD array (3000 pixels vs. a total
of 12000) was active.
Image
off-nadir
angle (°)
Control
points
AFT
FORE
Mausanne
14.45
29.10
32
Rome
4.97
26.09
43
Warsaw
4.97
26.04
29
Castelgandolf
0
12.35
28.20
25
Tab 3. Data set available
For the last images the showed results are focused on the DEM
extraction rather than the orientation model.
Fig 4. RMSE at check points depending upon number of
control points, trend for Mausanne image (North, East, Height
components)
The RMSE of check points (CPs) residuals, computed with
SISAR software, underlines that the accuracies are similar to
the GSD in horizontal and about H/B (1.60) multiplied for y-
parallax (3.7m) in vertical. The similar results are obtained by
OrthoEngine software with worse accuracy for Mausanne
image and better accuracy for Warsaw image with respect to
SISAR ones (Fig. 4,5,6).
Cartosat stereo - Roma gsd 2.50 [ml RMSE CP
Figure 5. RMSE at check points trend for Rome image (North,
East, Height components)
Cartosat stereo - Warsaw gsd 2.50 |ml RMSE CP
Figure 6. RMSE at check points trend for Warsaw image
(North, East, Height components)
2.2,1 RPC generation with geometric reconstruction
The RPCs can be generated according to a terrain-independent
scenario, using known physical sensor model, or by terrain-
dependent scenario without using any physical sensor models
(Tao et al., 2001b). In the last method the solution is highly
dependent on the actual terrain relief, the distribution and the
number of GCPs and it does not provide a sufficiently accurate
and robust solution if the above requirements for control
information are not satisfied.
For the previous motivations, an innovative algorithm for the
RPCs extraction, with a terrain independent approach, was
implemented into the software SISAR. The basic steps of this
algorithm are to build a 3D ground grid enveloping the terrain
morphology of the imaged area starting from a rigorous
orientation, and to estimate the RPCs that fit to this virtual
space.
At first an image discretization was made, dividing the full
extend image space in a 2D grid. Then the points of the 2D
image grid are used to generate the 3D ground grid: the image
was oriented and by the knowledge of the orientation sensor
model the collinearity equations were derived and used to
create the 3D grid, starting from each point of the 2D grid
image. In this respect it has to be underlined that the 2D grid is
actually a regular grid, whereas the 3D one is not strictly
regular, due to the image attitude. Moreover, the 3D grid points
were generated intersecting the straight lines modelled by the
collinearity equations with surfaces (approximately ellipsoids)
concentric to the WGS84 ellipsoid, placed at regular elevation
steps.
