International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B3. Istanbul 2004
In this study, non-horizontal terrain areas are also selected and
tested, e.g. two gable roofs shown in Fig. 4. The coordinate
differences of non-gable corners are not very obvious. From
Point number 7901192 and 4861413 in Table 1, it shows that
max absolute is 0.31m, 0.31m, and 0.60m in X, Y, and Z
coordinate components respectively. Two distinct gable corners
are selected and compared from orthoimage patch 7901192,
their coordinate difference in X,Y are only (0.23m, 0.07m)
and (0.42m, -0.04m), but the Z difference reached -1.14m
and -1.71m. A gamble corner in orthoimage number
4861413 is measured and compared. It's difference is 0.26m,
0.01m, and -1.23m in X,Y, and Z direction. Obviously, the
height difference is large. But the X,Y coordinate
differences are not so large from these results.
B. Orthoimage patch of terrain area 4861413
Figure 4 The orthoimage patch from non-horizontal terrain area
During the process, some difficulties are found in this proposed
methodology. That means how to (1).find a time-invariant flat
terrain area (2).obtain well-contrast orthoimage patches with
suitable size and texture. Actually it is very difficult to find lots
of terrain areas that meet the (1) and (2) requirements. But the
reachable geometrical accuracies motivate us to do more studies.
For example, it is necessary to develop a mechanism to evaluate
whether an orthoimage patch is suitable for criterion (2) and
self-verify the output results. Namely, the criteria for self-
examination of geometric and radiometric quality should be
developed in order to ensure what the operator choose is good
enough for controls.
Additionally, the evaluations of radiometric quality and the
accuracy assessment of exterior orientation by using these
orthoimage patches as controls should be done in the future.
Meanwhile, tests by matching new aerial images with
orthoimage patches for orientation parameters no matter what
interactively or automatically should be done.
Some improvements could be also conducted for generating
orthoimage patches much more efficient and more accurate, for
example, the selection of suitable terrain area and the provision
of height approximation. In this study, only the approximation
of height information is used for the orthorectification. No
precise height information must be measured by the operator. In
the future test, digital surface model (DSM) could be included
880
for provision of approximation height information. Additionally,
the radiometric model in Data Snooping can be improved more
accurate.
Finally, horizontal plane is basic assumption, this is too limited.
The test for non-horizantal plan or the refinement of the result
from generated orthoimage patches can be done in the future.
S. CONCLUSIONS
A methodology is proposed to generate the orthorectified image
patches as controls for aerotriangulation in this paper. Even
further investigation and study should be conducted in order to
get more verification, the preliminary tests show that the RMSe
can reach 0.15m, 0.19m, and 0.29m in X,Y, and Z coordinate
components. The good geometric accuracy proves the
feasibility of the proposed method for the controls in aerial
triangulation.
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ACKNOWLEDGMENTS
I am grateful to China Engineering Consultants, Inc. Taipei,
Taiwan, that provides the test data set in this study.
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