International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004
The images are evaluated with the digital photogrammetric
system PHIDIAS. At the beginning of any test a portable field
with control points is photographed from various directions to
perform the orientation of the camera assembly (figure 5). The
field of control points contains several points, whose distances
are previously determined using an interferometer. These
distances guarantee superior accuracy and are introduced to the
calculating of the orientation as additional observations. The
orientation parameters are determined by bundle adjustment in
combination with self-calibration.
The targets are measured automatically using image processing
with PHIDIAS. The centres of the targets are determined with a
standard deviation of about 0.4 microns. The three-dimensional
coordinates of the targets are subsequently calculated by
forward intersection using the image coordinates of two or three
cameras. The scale of the images is 1 : 7 to 1 : 10, that means
the targets on the specimens may be determinable with an
accuracy up to 3 microns (perpendicular to exposure direction).
Figure 5: Assembly of measurement cameras
3.1 Use of cameras
Up to three cameras are available for the test series. For a rapid
overview one camera perpendicular in front of the measured
object is sensible. But a displacement of the specimen
perpendicular to the measured plane cannot be recognised.
Thus at least /wo cameras are used. À second camera allows to
determine three-dimensional coordinates. Then in opposite to
the one-camera-measurement deformations perpendicular to the
surface can be detected.
The assembly of /wo cameras has an important effect to the
quality of result, as well as using three cameras instead of two.
The difference between a measurement with the outer two
cameras (assembly of all cameras see figure 5) to a
measurement of one outer and the middle camera is between 4
microns and 6-8 microns to the measurement of three cameras.
In the border area far from the cameras the noise raises (figure
6)
a plate test
4. MEASUREMENT OF DEFORMATIONS AND
AUTOMATIC CRACK ANALYSIS
I. The evaluation software PHIDIAS calculates from the images
in every epoch three-dimensional coordinates of the targets and
its standard deviations. The deformations can be determined by
the difference of two measurement epochs. They show global
displacements like the deflection of a beam (figure 7a). Only
the difference of two adjacent displacement vectors focus
attention on the cracks (figure 7b).
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Figure 7: a) Displacement of targets of a shear test
b) Difference of neighboured vectors (vertical direction)
c) Original image (cracks drawn)
d) Schematic drawing
Cracks are extracted from the displacements. For this the
following method is developed and implemented. An overview
shows figure 8.
I Interface to PHIDIAS
Measurement Input of point coordinates
method - — [Measured value jt,
Standard deviation ©
II Displacement
x Crack probability
—— ————
i
IH Controlling
Manual or
Expert system
Ye mm at
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i >| IV Local intensify
A Rising contrast
1
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Analysis —
I
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| | XV Following algorithm another iterative
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\ Snap global crack structures optimization
4
VI Finite element analysis
Fox cutie Output by ORFEUS / MicroStation |
Figure 8: Way of crack analysis
I. By the comparison of the measured change of length
between two targets with the statistically distributed material
parameter, which is necessary for the creation of a real crack
(primary crack width), the existence of a crack can be
calculated as a stochastic value (figure 9).
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