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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004
Table 1. Statistics of paired t-test in pixels [probability (p-
value)/(min difference, max difference)]
Auto3D-Socet |Auto3D-Photoshop Socet Set -
Set Photoshop
x-left 3.39E-05 0.002 0.177
(25 pm). (-0.735, 3.623) | (-1.252,2.931) (-3, 2.952)
x-right 0.895 0.242 0.233
(25 um) {-1.565, 1.308) | (2.762, 1.971). | C0.667, 2-333)
y 0.001 0.709 0.004
(25 um) | (-1.657, 1.632) | (-1.943, 1.429) (-2, 1.667)
x-left | 4.52E-10 0.033 0.001
(50 um) | (-0.738, 2.149) | (-1.750, 1.503) | (-2.524, 1.096)
x-right 0.008 0.063 0.661
(50 um) | (-1.085, 1.129) | (-1.553, 1.443) | (-1.904, 1.096)
y | 3.79E-05 0.086 0.083
(50 p 1) | (-0.654, 1.273) | (-0.935, 1.411) |(-1.238, 1.286)
1-2 727 = 12 4 23 p
M no a 8% 14% a 3%
h 33%.
0-1
0-1 47% 0-1
61% 61%
(a) (b) (c)
Figure 9, Distribution of differences (Auto3D-Socet Set) in
pixels (25 um images). (a) x-left. (b) x-right. (c) y.
2-3 -1-0 1-2 -2--1 1-2 -1-0
| 3% diis 6% / 14%
V?
(a) (b) (c)
Figure 10. Distribution of difference (Auto3D-Socet Set) in
pixels (50 um images). (a) x-left. (b) x-right. (c) y.
This range not only suggests not much significant difference in
practical of autostereoscopic and stereoscopic observations, but
also indicates the approximately close maximum errors on
point identification between these two systems. The results
demonstrate that the autostereoscope can be a reliable
measurement system in contrast with the traditional eyeglasses-
based systems, especially for handling a large volume of data
with limited resources and with the expectation of no
significant loss in photogrammetric accuracy. Finally, notice
that the 3D perception among all the seven participant
observers slightly degrades because some points are difficult to
be digitized as a consequence of the lower color contrast or
ambiguous definition and interpretation on their precise
locations. Nevertheless, our measurement errors are consistent
and follow the same or very similar distribution.
6. CONCLUSION
In this paper, we investigate the potential and performance of
autostereoscopic measurement as a possible technical
alternative in photogrammetric practice. For this objective, we
first analyze the general 3D geometry of an autostereoscopic
System. The analyses are devoted to the parameters of viewing
zone, including its geometric shape, corresponding size, and the
movement boundary of operators for photogrammetric practice.
Because the movement boundaries are addressed within the
optimum viewing zones for operators during photogrammetric
practices, we also estimate the perceived depth that directly
affects the accuracy of the autostereoscopic measurement. The
analysis indicates that longer perceived depth provides
observer a sharper 3D sense. Furthermore, to demonstrate the
performance of autostereoscopic measurement, we implement
several photogrammetric tests to compare both the stereoscopic
and autostereoscopic measurement with a standard
measurement. We first introduce the measuring systems and
our software, Auto3D, designed for DTI 3D monitor based on
the parallax-barrier system. Finally we present statistical
analyses for comparison. Our results show that over all more
than 6296 of the autostereoscopic measurements are less than
one pixel away from the popular stereoscopic measurements.
The consistency of autostereoscopic measurements from
different operators is better than 1 pixel for at least 60% of the
measurements.
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ACKNOWLEDGEMENT
This work is sponsored by the National Geospatial-Intelligence
Agency.
