2-2-4
The mathematical model for the two-dimensional case was pointed
All observations are processed in a forward and a backward filter.
The estimated state-vectors from both filters are combined in an
optimal smoothing algorithm. Besides the digitised trajectory in
terms of coordinates, attitude angles and velocities at every PPS-
second, which coincides with the moment of shooting of the CCD-
cameras, the expanded filter provides estimates of calibration
parameters for the sensors. The accuracy of the filtered points is
about 0.5 m in a UTM coordinate system based on WGS 84. In the
final step the sequence of points is replaced by a smooth line
consisting of geometrical elements (straight sections, transitional
and circular curves) forming the alignment of the road.
time in seconds
Figure 6: Results of the filter compared with OTF positions
From the direction of movement at the outage the difference of 0.6
m in the east component can be attached to a scalefactor of the
odometer. The length of the outage is about 1200 m, which results
in a scalefactor of about 0.05 %. The difference in the north
direction, which is perpendicular to the moving direction,
correspond to a gyro drift of about 0.08 ° / h. Both values are in the
error budget of the sensors.
With the smoothing algorithm the divergence can be reduced below
3.3 Filter results
0.4 m.
To analyse the filter behaviour and the filter results control points
were established on the former airport of Neubiberg, near Munich.
This airport is suitable for the test, because it features optimal
conditions for GPS measurements and optimal geometry for the
vehicle path like long straight lines with no height differences. The
airport and the path of a driven test route is shown in figure 5.
Figure 5: Airport Neubiberg with vehicle path
In this test at least 5 satellites were in view, enabling the
computation of OTF solutions as a reference. A total outage of all
satellites for 60 seconds was simulated to check the main filter.
During the outage the vehicle is on the taxiway, which is oriented in
west-east direction. In figure 6 the position differences between the
OTF positions and the results of the forward filter, of the backward
filter and of the smoothing algorithm respectively are shown.
3.4 Object measurement
By screening the video, the objects of interest are identified and
flagged for measurement. Since the video is synchronised with the
CCD-cameras, it is easy to find the flagged objects in the digital
images. A photogrammetric software has been developed which
supports the measurement of the location of objects in all images,
where they appear, and performs a robust adjustment to determine
the 3d-coordinates. The self calibration of the pair of cameras
provides the parameters of the inner and the relative orientation.
The transformation of the coordinates from the camera system into
the body system requires rotations and translation using parameters
which have been resolved by a test field calibration. The final
transformation into the world coordinate frame is based on the
position and the attitude of the system at the moment of exposure, a
result of the Kalman-Filter. The standard deviation of the relative
position of the objects is smaller than 5 cm as shown by Klemm
(Klemm 1997).The accuracy of the absolute position including the
computed trajectory is about 0.5 m.
The graphical user interface for the photogrammetric measuring
procedure is shown in figure 7. An interface to a geographic
information system is available to transfer the positions and to add
the attributes required for further use.
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