stanbul 2004
of the data, as
stem
f plane and
alignment
nt was the
ped plane
FC,' IP-R
n result of
coordinate
n system
The road
ed in the
ion in the
1gitudinal
1 moves
lignment
int of the
ints after
International Archives of the Photogramme
"um
= Fie. C
Au qui teicilatios (Fai
ARES A 7 BE dE prem ee di LL LL i E e EE d) “Pohiats tds"
Fig. 11. Horizontal alignment information system of initial screen
data02
BC EC IP
x 6324.2 ; 176604. 3971
{st : 174.208 178706.946] 7304. 297 (9.8613
209430,6757 2094365271 209426 0012
à st # 17874 ,5040 179744. 7061 113153. 8008
209444 0315 209444, 7129 203452 9007
set A ^ 108739.4373 17633,8149 Pare), 8353
> T 80.0000
209441 8549 209432, 1899 209431. 5001
Fig. 12. Result of BC, EC, IP, R
Em DES
PA Pas Cucnscson rdi
RC ES
142 1 eu 575, 0
71 000.627 2946.57
NET. Sen 1757 7
200444.0315 20994 7003
rN i A343
fo mena 30969. 1068
ALSNKEEN MONA
Fig. 13. Horizontal alignment information system
EEE NUN
m Classifcaton |
MUGKSER Sti f 5 Program bi; San dang ki
Fig. 14. Vertical alignment information system
49
try, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004
4.3 Development of Road Facilities Information System
A facilities information system was developed to maximize
visual effect on the facilities installed on a road. In the data
input of the facilities information system developed in the study
as in Fig. 17, OPEN button pops up a dialog box to select a
data in DB. View is composed of 4 sections; top left, bottom
left, top right, and bottom right.
Top left views the real local photo of the data in DB, and top
right views. the digital topography of the target area. Bottom
left expresses the scattering of data onto grid in which each
point records and saves the attributes of facilities on it. Bottom
right views the close-up of a point on the photo in top left when
clicked with mouse. Addition of the study is that road manager
takes the motion picture of the present status of the road and
makes it available so that users can grasp the present status of
the road. Also, road managers take the road pictures over time
and save them as motion picture. This motion picture module is
in Fig. 18.
Bee Clseítics Window i: E ih o si
E Qe te Lr SeficlFT! a Ii [s
Fhato
i re F
= x Fra - @ 354 156
Tus Dis by S SEER
Fig. 15. Road facilities ir information system
FAT" Frost Fac Trés a
Fig. 16. Screen of moving image data
5. Conclusion
A more exact and economical road information system was
developed using digital photogrammetry. The conclusions are
as follows.
First, to obtain road information using digital photogrammetry,
a road was shoot in the 4 corners in each zone along road
extension and proceeded to bundle adjustment. RMSE was
4—7cm, indicating that it was within the allowable error of
reduced scale of 1:12,000.
Second, in digital photogrammetry, it was possible to obtain 3-
d coordinates of road center line and facilities through
orientation with natural points, when the error was 2—-5cm, a
practical range. It was thought that control score could be much