particles. A 3D PTV system consists of the following 
components: 
* Image acquisition system with up to four CCD cameras 
including a data storage device. 
* Illumination facility. 
e Tracer particles to seed and visualize the flow. 
Whether high-grade components or off-the-shelf products come 
into operation is depending on the experiment requirements as 
well as on the budget. The data acquisition system defines the 
spatial and temporal resolution. 
The system used at the ETH Zurich was upgraded from offline 
to online image digitization. In the previous system, the image 
sequences were firstly recorded on analogue videotapes and 
digitized afterwards, while in the new system two frame 
grabbers (Matrox Genesis) are used to provide online 
digitization and storage. The length of the recorded digital 
image sequences is nowadays restricted by the storage device 
capabilities. The data rate for a 60 Hz full-frame camera with a 
resolution of 640 x 480 pixels is about 19 MB/sec, and hence in 
an experiment which lasts for 1 minute four cameras deliver a 
total amount of about 4.5 GB image data. Hardware setups for 
3D PTV used at ETH Zurich are described in (Maas, 1992; 
Virant, 1996; Stüer, 1999). Figure 1 shows a hardware setup 
with four cameras used for the observation of the flow in a 
aqueous copper sulfate fluid between two electrodes (Lüthi et 
al, 2001). 
  
  
Figure 1: Experiment setup with four CCD-cameras 
3. SYSTEM CALIBRATION AND DATA ACQUISITION 
A calibration of the system is required to be able to establish 
correspondences between particle images and to compute 3D 
particle coordinates. Therefore a reference body with discrete 
targets is inserted into the observation volume before or after 
the experiment. The images of the reference body are used to 
determine the interior and exterior orientations as well as the 
additional parameters of the cameras. Using the mathematical 
model of spatial resection, the orientation and calibration 
parameters of a camera can be determined from one single 
image of the calibration reference body under suitable 
illumination, if the 3D coordinates of the targets are known. 
During the experiment synchronous image sequences of the 
particle seeded flow are acquired. The particles appear as bright 
spots that can be detected automatically from the images. An 
example of a particle image used for 3D PTV is shown in 
Figure 2. 
  
Figure 2: Particle image for 3D PTV 
4. PROCESSING STEPS 
After the acquisition of the image sequences the data is 
processed in the following steps: 
e Image preprocessing by highpass filtering to remove non- 
uniformities in the background illumination. 
* Detection of particles in the images. 
* Establishment of stereoscopic correspondences using 
epipolar constraints. For details see (Maas, 1992; Dold and 
Maas, 1994). 
* Determination of 3D particle coordinates. 
e Tracking in object- and image space. 
The results of the automated processing are trajectories of the 
particles in the three-dimensional velocity field. The processing 
scheme of 3D PTV is shown in Figure 3. 
  
Flow visualization 
Image acquisition 
    
  
  
  
  
  
  
Highpass filtering ||«& — | 
a7 Image 
Detection and preprocessing 
location of particles 
  
  
Y 
Establishment of 
_ correspondences Le 
Determination of Camera orientations 
3D-coordinates Calibration data 
Ls | s auprauon data | 
Add N°. 
Tracking in object T 
and image space Kinematic model 
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
| 
Particle trajectories 
  
  
Figure 3: Processing scheme. 
Additional particle positions are calculated during the tracking 
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