![]() ![]() We've also included some excellent videos where you can learn how to make paper mache masks:īut before we begin, let's make sure we know what paper mache is and how you make it. 64 pixels in pass 2, 32 pixels in pass 3).Below we've compiled a list of 13 tutorials, so you can learn how to make a paper mache mask: 128 pixels) and decrease gradually in the following passes (e.g. The general recommendation is to use about three passes (the more passes you use, the better will be the result, but it will also take a while to compute.). Read my paper for more information on this. The interrogation areas of later passes are not only displaced, but they are also deformed. This procedure yields a high vector resolution, a high signal-to-noise ratio, and a high dynamic velocity range. The displacement information of the first pass is used to offset the interrogation areas in the second pass and so on. That is why you should decrease the size of the interrogation windows in the following passes. But large interrogation areas will only give a very low vector resolution ("vectors per frame"). The larger the interrogation areas, the better the signal-to-noise ratio, and the more robust is the cross correlation. By selecting this algorithm, your data will be analysed in several passes: The first pass uses relatively large interrogation areas to calculate the displacement of your image data reliably. The FFT window deformation algorithm is enabled by default, and in most situations, it delivers the best results. ![]() PIVlab features three different correlation algorithms, DCC (single pass direct cross correlation), FFT window deformation (direct Fourier transform correlation with multiple passes and deforming windows) and Ensemble correlation. Proceed to Analysis -> PIV settings to setup the cross-correlation for your image data. Click Load images in the panel that appears on the left side of the screen. Some of the possibilities of PIVlab will be demonstrated.įirst, load some images by selecting File -> New session. This example will show you how to process a series of image pairs. A tool tip will appear and give you more detailed information. When you would like to see more information on a setting or a parameter, simply hover your mouse over the feature. When doing PIV analyses, the work flow should start at the left side of the menu, and continue to the right side. The GUI is menu-based selecting a menu item will change the panel that is displayed on the right hand side. When creating masks, manually rejecting vectors, selecting areas/ poly-lines etc., the left mouse button performs the desired task, whereas the right mouse button ends this task. This coordinate system can be adjusted / modified after calibration (see below). ![]() Positive u is top-to-bottom, and positive v is left-to-right. Velocities in the horizontal direction (x) are called 'u' and velocities in the vertical direction (y) are called 'v'. The coordinate system is defined as follows: The standard coordinate system of image data has its origin at the top left. Sessions can be saved and reloaded in PIVlab. A "session" is defined as a collection of single or multiple frames including any derived parameters and all the settings of the GUI. Single analyses consist of one single frame (one image pair + results) a time-resolved analysis consists of multiple frames (several image pairs + results). A "frame" is defined as a pair of images including any derived parameters. ![]()
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