The 3D reconstruction is a bundle adjustment method
performing the transformation between the image coordinate
system and the object coordinate system. This is an intersection
using the exterior parameters also obtained in the previous
calibration.
To obtain a representative measure of accuracy of the system
a targeted object is imaged inside the actual area. Calculated
coordinates are compared to the given values and the deviations
are used to estimate the accuracy. The given values are found
by accurate photogrammetric methods.
The precision of measured coordinates is estimated from
repeated measurements.
Results of this analysis are given in table 1.
X Y Z XYZ
Accuracy (RMSE) 0.056 0..101 0.082 0.141
Precision (O0) 0.051 0.035 0.135 0.148
Table 1. Results from accuracy investigation (all in mm.).
Different methods can be applied to verify the 3D model. In
our set-up, 3D graphics software was used to generate grid
models for visual verification. A more sophisticated approach
is surface modelling by generating synthetic images (Thune,
1991). Perspective views can be generated from the estimated
object model using the pixel values and the camera model in a
simple ray casting technique.
3.8 Data analysis.
The initial task of our system was to obtain characteristic
parameters of the functioning of the teatcup liner. Using 3D
object models from different phases of the milking process, it
is possible to estimate variable parameters like shape and size
of the surface. From these the required data of tension in the
liner and the distribution of the pressure from the liner on the
teat can be obtained by means of a physical model. This work
is performed by the Dept. of Agricultural Engineering at AUN.
An example of result from this analysis is given in figure 11.
4. Conclusions
This paper descibes the work of designing a videometric system
to meet the special requirements of measuring a moving surface
inside a small vacuum chamber.
The work consists of a system component description and an
analysis of each component regarding mainly their influence on
the overall accuracy.
Binary radiometric resolution of the images and use of only one
videoframe are the main contributors to the accuracy loss.
These choices were made in order to handle the dataflow from
the fast moving dynamic scenes and still be inside the accuracy
requirements.
Results from the calibration of the system with both mirrors
and CCD-camera indicates considerable local distortions in the
images. These were probably caused by low-cost optics and
mirrors which were impossible to model by global parameters.
Both the resulting spatial accuracy and precision of the system
were inside 2/10 mm and satisfied the requirements.
When higher accuracy standards are required other choices can
be made and another more sophisticated mathematical model
used.
The data provides for a new analysis of the dynamics of the
teatcup liner, and, the results are promising so far.
©
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Figure 11. Estimated 3D model of the teatcup liner (upper plot)
and pressure from the liner on the teat (lower plot).
5. Acknowledgements
Most of the experimental and practical image acquisition work
were done in close cooperation with Mr. Odd Rgnningen at
Dept. of Agricultural Engineering, AUN. He also initiated the
project and made use of the data in his further research on the
milking process.
Prof. @.Andersen gave valuable support during the calibration
work.
6. References
Baltsavias, E.P., and Stallmann, D., 1990. Trinocular vision for
automatic and robust 3-D determination of the trajectories of
moving objects. In: Close-Range Photogrammetry Meets
Machine Vision, A.Gruen, E.P. Baltsavias, Editors, Proc.SPIE
1395, pp.620-629.
