There are two measurement modes: one is manual 
and the other is an automatic DTM (Ohtani, Ishii, 
1992). The latter uses the stereo-matching by 
coarse-to-fine cross-correlation. This is a mode 
wherein a computer makes batch measurements by 
placing evenly spaced grid points on the left 
image to be processed by correlation. 
Out of the calculated 3D coordinates we can 
obtain the stereo-contour-lines, perspective view 
and cross-section of the object. 
Furthermore, since the measurement data can be 
output by the DXF format, our system a whole 
variety of applicability through AutoCAD*, 
CivilCAD(TOPCON), and the CAD system which 
is supporting DXF*. 
2.3 Camera Calibration 
For camera calibration we used the 
self-calibrating bundle adjustment software, which 
we had already developed. We have also developed 
a new software to detect automatically with 
sub-pixel precision the position of the targets 
placed on 3D test-field designed for calibration. 
This software establishes the correspondence 
between the image coordinates and the 3D 
coordinates of the targets already measured on 3D 
test-field by means of the orientation of single 
photograph. The software also detects the coarse 
position of the targets by means of image 
correlation as well as its fine position by 
detecting the edge with Laplacian-Gaussian filter. 
This 3D test-field (Fig.4) was 1000 mm in both 
height and width, on which were placed 121 
targets "in 3 depth stages, i.e., Omm, 100mm, 
200mm, 300mm, 400mm and digitally 
photographed from 7 different positions 
(Cf.Fig.5). We used the 3D coordinatesc of |: the 
targets measured by a  contact-type 3D 
measurement apparatus at the precision of = 10u 
m. 
Now, as to the details of camera calibration, 
confer to (Kochi, Ohtani, Nakamura and others 
1995). 
  
Fig.4 3D test-field 
*AutoCAD,DXF are U.S. registrated trade marks 
of Autodesk, Inc. 
78 
3D test-field Camera position 
   
Fig.5 Configuration of image acquisition 
3. SURFACE FLATNESS MEASUREMENT 
Lately, the exterior characteristics of train body 
are increasingly diversified. For example, often 
times its surface is plain without design, or sandy 
with sandblasting or simply lustrous, or three 
dimensionally deep with curve, many of which 
characteristics make it difficult to measure by 
automatic stereo-matching. 
Therefore, we first executed a preliminary testing 
with various simulated surfaces to see whether our 
surface measurement system really works and then 
applied it actually on a real train body. 
3.1 Simulated Surface 
We had already measured 80 points on a simulated 
surface of plain iron plate of 400mm X 300mm 
with the base length of 400mm and with the 
distance of 1000mm and obtained a satisfactory 
result of depth accuracy 0.39mm(rms) and target 
accuracy (Cf:(1)equation) 0.48mm (Kochi, Ohtani, 
Nakamura and others 1995). 
This time we went further as to test-measure the 
sandblasted lustrous simulated surface of 300mm 
X 300mm with a round protrusion in the center to 
assess the precision (Cf:Fig.6). 
On a sandy surface ordinarily the light from its 
source is diffused and reflected on the different 
parts of stereo images of the right and left 
cameras, thus causing the difference in ‘the 
shading between the obtained images of two 
cameras. However, in our experiment it did not 
affect our  stereo-matching much to . our 
satisfaction. 
The Fig.7 shows the cross section obtained from 
the measurement results processed through 
PI-1000. To confirm the accuracy of our system 
this result was compared with the result obtained 
by the contact-type-3D-measurement-apparatus of 
- $ y m on 80 different points on the same 
surface. In our measurement the base length was 
928mm with the distance of 1048mm. The 
experiment was quite satisfactory with the 
accuracy result of 0.23mm (rms) in depth 
measurement, compared with the targeted 
accuracy of 0.23mm. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B5. Vienna 1996 
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