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d out the
icing the
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/e and the
2. Configuration of observation/Measurement
System
(1) Observation system
As shown in Figure 1, we mounted a video camera
on an airship type balloon. The total length of balloon is
5.2m and maximum diameter is 2.6m. When filled with
24m? of helium gas, it can lift up the photographing
equipment of around 5 kg to the altitude of 250m. The
balloon has two mooring ropes, which are used to adjust
the height of balloon according to the wind condition.
The video camera mounted on the balloon is deck
integrated type VHS-C camera. The size of CCD is 1/3
inch. Lens is 7 - 41mm zoom lens. Photographing
direction and zooming can be controlled by wireless
operation from the ground. The number of pixels
composing the video image is 660 for horizontal
direction and 400 for vertical direction.
In photographing the road, we placed circle mark of
about 1m in diameter as ground control points at 6 or
more positions and adjusted the camera so that both of
these control points and vehicles can be confined in a
video frame.
(2) Measurement system
As the basic study for the automatic system of traffic
measurement based on computer, we employed the
measuring method as shown in Figure 2 in our study.
Individual function were realized by image processing
equipment and EWS.
Unmanned
Balloon
Video Camera
Figure 1 Diagram of the observation using
unmanned balloon
After unloading the video tape on which the pictures
were taken at upper air, the tape is replayed and stored
as digital image in the frame memory device. At present,
it is possible to record the data for only 8 seconds, but
the moving images for longer time can be continuously
stored on the computer memory if digital video, etc. will
come to be in use more commonly in the future.
6 or more ground control points are specified in the
first frame of video image which is composed of plural
number of frames. Also, the initial position of the
vehicles to be monitored is specified in the image. In the
future, we are considering to automatically distinguish
the vehicle bodies from background(road) and to
mechanically select the vehicles subject to the
automatic tracing. At present, the number of vehicles
which can be specified and traced simultaneously in one
image is around 10.
As for the ground control points and cars for which
the initial position was specified, the image coordinates
are measured sequentially in the continuous frames at
the frequency of 1/60 second. In this study, we used
Quick Vector made by OKK Inc. (Japan) for real time
image matching.
Image coordinates of 10 cars and 6 ground control
points (GCPs) are outputted to and recorded in
engineering workstation every 1/60 second. Eventually,
actual length conversion factor is calculated from map
coordinates and image coordinates of ground control
points, and position coordinates of cars are outputted in
the form conforming to the map coordinates using
Video image
Frame memory
( Specification of GCPs’ initial position )
( Specification of initial positions of vehicles |
( Tracing by stereo matching )
(output of position coordinates |
(Real length conversion, position correction |
(Running speed, running locus]
Figure2 Flow chart of measurement
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B5. Vienna 1996
