33, 2012
ints
15° have been
he pairs with a
rmance of each
y.
iS | LE90
11 1.24
73 1.14
83 0.95
69 1.01
87 1.24
66 1.08
75 1.12
73 0.99
58 0.97
96 0.99
65 1.01
72 1.08
81 1.06
90 1.14
: 0.26-0.36)
1S | LE90
93 1.52
97 1.52
92 1.38
78 | 1.24
89 | 1.32
01 | 1.34
17 1.47
ht — 0.18)
shly dependent
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B3, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
* A moderate stereo angle is definitely more efficient
than a narrow angle in term of accuracy, with no
difference, in term of completeness.
wide base pairs +
narrou base pairs
280 + = , 1
220 + + J
nb of points
180 r 4
160 F 4
140 € 1 L 1 i 1 i L L 1
-50 -40 -30 -20 -10 0 10 20 30 40 50
max incidence angle
Figure 5 Completeness versus incidence angles
We merged different combination of stereo measurements,
using 3, 7 and 9 pairs. A first set is composed of wide angle
stereo pairs, a second set is made from narrow angle stereo
pairs. Our main concern is the evolution of the accuracy when
the individual measures are aggregated. A decreasing RMS
error would suggest the statistical independence of the different
measures. The results below show that we are far from this
situation. Aggregating 2 stereo pairs (3 images) improves
clearly RMS and LE90 performances, but adding more images
brings only a slight decrease in both values. In the case of
narrow stereo angles, the aggregation benefit for 3 images is
higher, but not sufficient to compete with the performance
obtained from wide stereo angle measures.
Incidences | Stereo | Images Bias | RMS | LE90
-16.0..15.8 Wide 0.24 | 0.52 0.84
-11.0..10.4 | Narrow 0.37 0.68 1.15
-21.7..20.7 Wide 0.25 0.49 0.80
-16.0..15.8 | Narrow 0.37 0.61 1.00
-28.4.27.4 Wide 0.27 0.49 0.78
-21.7..20.7 | Narrow 9 0.38 0.62 0.96
Table 3 Multi stereo pairs
OQ
The benefit of the aggregation for the completeness is more
obvious. For all combinations, the 295 check points are well
defined in the aggregated DEM. This has to be also related to
the perfect symmetry of the acquisition around a nadir image:
This configuration minimises the hidden parts in a dense urban
environment. Obviously, this condition cannot be met
everywhere in the world because helio-synchronous satellites
fly only along a finite set of orbits, which are generally not at
the exact zenith of the area of interest.
6. CONCLUSION
We have presented a systematic exploration of the stereoscopic
capabilities of Pleiades imagery for the extraction of digital
elevation models in various environments. The agility of the
satellite has risen questions about what is feasible, and what is
efficient, regarding 3D mapping from multi-angle images
sequences. As expected, the answer depends on the context. In
an open landscape situation, without severe occlusions, a single
stereo pair should provide a nearly optimal result with a fairly
wide stereo angle. In urban area, the main profit of multi-angle
Figure 7 Melbourne DEM (detail)
images sequences is the reduction of occlusions behind
buildings. A symmetric configuration with two oblique views
on each side of a nadir image seems to be a good compromise in
this context. Additional images acquired on the same pass
would not increase the scene visibility and bring no significant
accuracy improvement. The stereoscopic angle has to be
consistent with the scene morphology to avoid occlusions but
we did not get convincing results from narrow angles
configuration.
