ParaView/Tricks
This page contains a list of tips and tricks for ParaView, which may be useful for others.
Contents
Difference Between Two Timesteps
To look at the "delta" between two timesteps, follow these steps.
- Load your data file twice, so your pipeline browser has two separate instances of "flow.pht" or whatever file you open.
- Apply one Force Time filter to each input file, and specify the physical time (not time index) for each. This will force the time for each and make them independent of the global ParaView time control in the upper toolbar.
- Select both Force Time filters simultaneously, and apply a Programmable Filter. Your pipeline browser will now show arrows representing multiple inputs to the single programmable filter.
- Populate the programmable filter with the following code:
tmp = inputs[0].PointData['myAvailableFieldName'] - inputs[1].PointData['myAvailableFieldName']
output.PointData.append(tmp, 'delta of myAvailableFieldName') - You can now view the field, "delta of myAvailableFieldName," and change the time steps it uses to compute the time-delta by modifying the Force Time filter properties.
Example script: relative change in eddy viscosity
s = 'EV' a = inputs[0].PointData[s] b = inputs[1].PointData[s] tmp = (a - b) / b output.PointData.append(tmp, 'delta')
Stepping Forward in Time
Let's say you load your ParaView file (for PHASTA, *.pht or *.phts) as phtFile
. The times associated with each timestep referenced by the file are given by phtFile.TimestepValues
.
To step forward in time, set the time of the current view. For example, GetActiveView().ViewTime = myTime
. When you save an image, all visible sources will be rendered using data from that time (myTime
).
Saving Data at a Given Time
It turns out the data fields you access through Python are not updated simply by setting the active view's ViewTime
property. For example, if you're trying to extract data from a probe location or along a line, simply saving that pipeline object does not reflect the updated timestep. Instead, you need to call the UpdatePipeline(time=myTime)
method of your ProbeLocation
, Slice
, or other pipeline object. This method is inherited from SourceProxy
.
Visualizing Vortices
Two methods for visualizing vortices are taking iso-surfaces of either Q-criterion or the Omega-criterion (Liu 2016, "New omega vortex identification method"). To compute both, apply "Gradient of Unstructured Dataset" to the velocity field in ParaView, and name the result g
. Then enter one of the following expressions into a Calculator, and finally apply a Contour at the appropriate value:
- Q-criterion
-
-g_1*g_3-g_2*g_6-g_5*g_7+g_4*g_8+g_0*(g_4+g_8)
- Contour at whatever value shows the features you want; try 1e7 as a starting point, but Q has a huge range of magnitudes
- Omega-criterion
-
(g_1^2 + g_2^2 - 2*g_1*g_3 + g_3^2 + g_5^2 - 2*g_2*g_6 + g_6^2 - 2*g_5*g_7 + g_7^2) / (2 * (g_0^2 + g_1^2 + g_2^2 + g_3^2 + g_4^2 + g_5^2 + g_6^2 + g_7^2 + g_8^2 + 1e-14))
- Contour at 0.52 as recommended in the Liu (2016) paper to start; Omega is always between 0 and 1
There is also a third useful metric for visualizing vortices. This is lambda_2 criterion. This process is outlined below.
- Lambda_2-criterion
Step 1
First, you will need to compute the velocity gradient vector. This can be done using Paraview's Gradient of Unstructured DataSet
filter. Make sure the box labeled Computed Gradient
has an x and that u
is set as the Scalar Array.