ls. The image
jhest common
ps are chosen
od and reliable
onvergence of
| least square
of the discrete
two pixels. In
imate values a
using image
id level we get
oints, used by
ng data of the
ints is defined
:d in the object
he intersection
ellipsoid. Next
ing line which
centre pixel a
t or is located
> found across
compute the
ormine corres-
f the feature
le image least
Jas V., 1991).
| matching a
of all image
performed by
mage patches
ansformation
neters of all
re one of the
ransformation
ne roundabout
> image. With
ed to n-1 with
nts.
RY IMAGE
omplex image
software with
particular the
the Moon and
uitable to test
pects for the
ges.
)ntinuties.
;E-kernels.
odules had to
ults with high
accuracy and only few blunders. Especially in the poorly
textured areas a great amount of matching succeed.
There are some difficulties particularly if image patches
include data of surface discontinuies.
Some of the results are published by Oberst J. et al.
(1995). Further details can be found in Scholten F. and
Uebbing R. (1996).
Additional tests will be carried out with real three line
scanner images of MOMS-02.
5. REFERENCES
Albertz J., Ebner H., Heipke C., Neukum G., Scholten F.,
1992. The Camera Experiment HRSC and WAOSS on
the Mars 94 Mission. International Archives of Photo-
grammetry and Remote Sensing, Washington D.C., USA,
Vol. XXIX, Part B1, pp. 130 - 137.
Fórstner W., Gülch E., 1987. A Fast Operator for
Detection and Precise Location of Distinct Points, Corners
and Centres of Circular Features, Proc. of Intercom-
mission Conference on Fast Processing of Photogram-
metric Data, Interlaken 1987, pp 281 - 305.
Heipke C., Piechullek C. (1994). Towards Surface
Reconstruction Using Multi Image Shape From Shading.
International Archives of Photogrammetry and Remote
Sensing, Vol. XXX (3), pp 361-369.
Heipke C. 1995. Digitale photogrammetrische Arbeits-
stationen. Habilitationsschrift, München.
Neukum G., et al. 1995. The Multiple Line Scanner
Camera Experiment for the Russian Mars 96 Mission:
Status Report and Prospects for the Future. Proceedings
of the 45rd Photogrammetric Week, Wichmann, Karlsruhe
pp 45-61.
Ohlhof, T., 1995. Lokale, Regional und Globale Punktbe-
stimmung mit Dreizeilenbildern und Bahninformation der
Mars 96 Mission.
DGK C, Nr.
Ohlhof, T., 1996. Local, Regional and Global Point
Determination using Three-Line Imagery and Orbital
Constraints. International Archives of Photogrammetry
and Remote Sensing, Vienna Austria, Vol. XXXI,
Commision lI.
Oberst, J., et al., 1995. Photogrammetric Analysis of
Clementine Multi-Look-Angle Images Obtained Near Mare
Orientale. XX. General Assembly, European Geophysical
Society, Hamburg.
Schlotzhauer G., Reulke R. 1994, An Error Modell for
Decompressed Image Data HRSC/WAOSS - Col
Meeting, Berlin 4. - 6. May 1994.
Scholten F., 1996. Automated Generation of Coloured
Orthoimages and Image Mosaics Using HRSC and
WAOSS Image Data of the Mars 96 Mission. International
Archives of Photogrammetry and Remote Sensing,
Vienna, Austria, Commision III, WG II/III.
Schwarz G. 1994. Argus Platform: Pointing and Stab-
ilization vs. HRSC/WAOSS Image Quality. HRSC/
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996
WAOSS CO-Investigator Team Meeting, Berlin, May
1994.
Tang L. 1994. Automatic Determination of Conjugate
Points in Multiple Images of Different Resolutions for
Photogrammetric Processing within the Mars'94/96
Mapping Experiments. International Archives of
Photogrammetry and Remote Sensing, Vol. XXX (4), pp
541-547.
Tsingas V., (1991) Automatische Aerotriangulation.
Proceedings of the 43rd Photogrammetric Week,
Stuttgart, Heft 15, pp. 253-268.
Uebbing R., 1996. An Automated Digital Approach for the
Generation of Digital Terrain Models Using HRSC and
WAOSS Image Data of the Mars 96 Mission. International
Archives of Photogrammetry and Remote Sensing,
Vienna, Austria, Vol. XXXI, Commision lll.
Software development for the HRSC/WAOSS Camera
experiment on the Mars 96 Mission is supported by
German Space Agency (DARA).
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