Editing Particle image velocimetry (section)

==Analysis==
[[File:PIVlab multipass.jpg|thumb|PIV analysis of a vortex pair. The magnification in the upper left shows the increase in spatial resolution that can be achieved using a modern multi-pass window deformation technique.]]
The frames are split into a large number of interrogation areas, or windows. It is then possible to calculate a [[displacement (vector)|displacement]] [[vector (geometric)|vector]] for each window with help of [[signal processing]] and [[autocorrelation]] or [[cross-correlation]] techniques. This is converted to a velocity using the time between laser shots and the physical size of each pixel on the camera.  The size of the interrogation window should be chosen to have at least 6 particles per window on average. A visual example of PIV analysis can be seen [http://demo.interactiveflows.com/analyze/ here.]

The synchronizer controls the timing between image exposures and also permits image pairs to be acquired at various times along the flow. For accurate PIV analysis, it is ideal that the region of the flow that is of interest should display an average particle displacement of about 8 pixels.  This is a compromise between a longer time spacing which would allow the particles to travel further between frames, making it harder to identify which interrogation window traveled to which point, and a shorter time spacing, which could make it overly difficult to identify any displacement within the flow.

The scattered light from each particle should be in the region of 2 to 4 pixels across on the image. If too large an area is recorded, particle image size drops and peak locking might occur with loss of sub pixel precision. There are methods to overcome the peak locking effect, but they require some additional work.

[[File:PIV analysis of a stalled flat plate.jpg|thumb|PIV analysis of a stalled flat plate, shear rate superimposed]]
If there is in house PIV expertise and time to develop a system, even though it is not trivial, it is possible to build a custom PIV system. Research grade PIV systems do, however, have high power lasers and high end camera specifications for being able to take measurements with the broadest spectrum of experiments required in research.

An example of PIV analysis without installation: [https://mybinder.org/v2/gh/openpiv/openpiv-python-example/master?filepath=index.ipynb]

PIV is closely related to [[digital image correlation]], an optical displacement measurement technique that uses correlation techniques to study the deformation of solid materials.