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Version [AP| Co| Ch r Og % Y Z ux us uz x Hy 
| [mm] | [mm] | [mm] | [mm] | [mm] | [mm] | [um] | [ium] 
1 0| 30| 56| 11554| 11.7| 0.027| 0.023| 0.035| 4.207| 4.063| 3.657| 12.13| 11.98 
2 10| 30| 56| 11547| 0.36| 0.027| 0.023| 0.035| 0.086| 0.058| 0.114] 024| 0.22 
3 10| 30| 56| 11547| 0.42| 0.023| 0.019| 0.029| 0.068| 0.055| 0.084| 0.19| 0.17 
4 10| 30| 40| 9879| 0.42| 0.023| 0.019| 0.028] 0.062| 0.039| 0.056| 0.16| 0.14 
5 10] 30] 38 8969| 0.38] 0.026| 0.0201 0.032] 0.052] 0.040] 0.048] 0.13] 0.13 
6 10] 30{ 38 8963| 0.46] 0.033] 0.025] 0.039] 0056| 0.039 0.061] 0.14] 0.14 
Improvement 1 1 2 32.5 1.0 1.0 1.0 48.9 70.1 3211 505] > 545 
Improvement 2 | 3 0.9 1.2 1.2 1.2 1.3 F2 1.4 1.3 1.3 
Improvement 3 | 4 1.0 1.0 1.0 10 1.1 14 15 12 1.2 
Improvement 4 | 5 Ll 0.9 1.0 0.9 1.2 1.0 12 1.2 14 
Improvement 6 | 5 12 1.3 1.3 12 1.1 1.0 13; 1.08 1.08 
Table 2 Results of bundle adjustment and accuracy 
= A Scale for Points 500.000 [mm] 
verification. Scale for Vectors — 50.000 [micron] 
AD... rest Number of additional parameters p 
C9 iino deni. Number of control points = d x € 
Ch ee Number of check points Targets on rods of front structure 
T axccsessapecisssees Redundancy 7 
genns: Variance of unit weight a posteriori 
Ox, Oy, Oz . Theoretical precision of check point coor- 
dinates X 
Ux» Lys Hz..... Root Mean Square Error from comparison 
to check point coordinates in object space 
Hays Hy coeecnencs Root Mean Square Error from comparison 
to check point coordinates in image space 
The plots of checkpoint residuals of version 4 exhibit 
further systematic discrepancies which were traced. The 
small imaging scale and oblique imaging of targets on 
the rods of the testfield structure led to an influence of the 
(darker) background on the target area. This resulted in 
displacements comparable to those of local illumination 
gradients. Targets which were imaged too obliquely were 
eliminated for version 5. The relative precision of ver- 
sion 5 corresponds to 1 part in 100000 for both the X and 
Y axis. The relative accuracy is 1 part in 50000 for the 
same axes. The accuracy in image space corresponds to 
1/85 of the pixel spacing. An accuracy of 1/50" of the 
pixel spacing can be attained when using a minimum da- 
tum only. This difference might appear large, but must be 
partially attributed to residual effects of local illumina- 
tion gradients, which are partially absorbed when using 
more control points. These effects reached 0.03 pixel for 
the targets which were eliminated in the step from ver- 
sion 3 to 4 and are assumed to reach 0.02 pixel for other 
targets still in the data set. Systematic discrepancies can 
also be detected for targets in columns as shown in the 
plot of the differences to checkpoints in Figure 15. The 
overall accuracy improvement in image space attained 
by using a smaller template and eliminating targets with 
large degradations (version 2 to 5) is a factor of 1.8 and 
1.7 in x and y. 
& * S. o ^ 
Targets in columns on wall 
Figure 15 Differences to check points of version 5 (test- 
field as viewed from top). 
3.4 Accuracy with PLL Line-Synchronization 
The imagery was acquired at identical positions with pix- 
elsynchronous sampling and PLL line-synchronization 
within 30 seconds of each other. It is thus possible to 
compare the effect of the synchronization on the three-di- 
mensional accuracy under practically identical condi- 
tions. The image coordinates were again measured with 
LSM using a 5 x 5 template and the targets which were 
eliminated due to local illumination gradients and too ob- 
lique imaging conditions on the rods were removed from 
the data. Figure 16 shows a comparison of the image co- 
ordinates for 6 frames acquired at the left topmost station 
(see Figure 12). The average displacement between the 
two images of 0.125 and 1.988 pixel in x and y was re- 
moved before the plot. The average displacement in x 
was attributed to a difference in the sampling point and 
the difference in y was due to differences in the settings 
of the frame grabber for the selection of the active image 
region in vertical direction for the two acquisition modes 
(the determined value is only 0.002 pixel off the actual 
difference of 2 pixels). The large geometric deformation 
and instability (especially in x) of PLL line-synchroniza- 
tion is apparent from the figure. The RMS value of the