I'm making improvements to a thermal-hydraulics code written in Fortran by having it write its mesh data to VTK files that can be opened in a visualizer. Previously, data was simply written to a text file that the user had to manipulate by hand. I write two files: one for scalar data, which includes the vertices of the sructured mesh cells and the scalar data inside them, the second file for vector data. Because of the solution algorithm, the vectors lie on the faces of the mesh cells, so I define their location using Polydata points.
I tested my modifications for a small, 500 cell mesh and it worked fine, but I've tried to move up to a bigger, 9,000 cell mesh. The vectors don't display right. The mesh has 18 cells in the x-direction, 18 cells in the y-direction and 29 cells in the z-direction. In the picture I attached below, you can see that there are 18 vectors in the y-direction, which is correct, but only 7 vectors in the y-direction. I reduced the z-direction mesh to 3 levels to reduce the complexity for here. I need to determine if this is an issue with the visualizer, the VTK file, or my code.
I checked the VTK file and it looks to me that everything is there. Actually, the previous attempt I made involved printing data so the z-direction coordinates varied fastest, then x, then y and that produced a staggered set of vectors in the z-direction. Making it so x varied fastest, then y, then z produced what you see above. I was surprised to see this made a difference because the actual content of the VTK file doesn't change. Of course, I have trouble with writing to VTK format because I can't find much information on it online, so I could be missing something obvious. I'm attaching the VTK file I wrote below to see if there's something I'm overlooking. It's a very long file, so I got rid of most of the data for this post and just left the two header sections and a few data points.
# vtk DataFile Version 1.0 Vector Data ASCII DATASET POLYDATA POINTS 972 double 0.33500000E-02 0.33500000E-02 0.00000000E+00 0.13000000E-01 0.33500000E-02 0.00000000E+00 0.25600000E-01 0.33500000E-02 0.00000000E+00 0.38200000E-01 0.33500000E-02 0.00000000E+00 0.50800000E-01 0.33500000E-02 0.00000000E+00 0.63400000E-01 0.33500000E-02 0.00000000E+00 ... up to 972 values POINT_DATA 972 VECTORS Axial_Liquid_Mass_Flow_Rate float 0.0000E+00 0.0000E+00 0.9075E-01 0.0000E+00 0.0000E+00 0.1636E+00 0.0000E+00 0.0000E+00 0.1636E+00 0.0000E+00 0.0000E+00 0.1636E+00 0.0000E+00 0.0000E+00 0.1636E+00 0.0000E+00 0.0000E+00 0.1636E+00 ... up to 972 values
In reference to Chris' comment:
First, the code actually uses two meshes in keeping with the staggered mesh approach: 1) a scalar mesh in which the continuity and energy equations are solved in (pressure, density, enthalpy, and void fraction are defined at the centers of the scalar mesh cells), 2) a momentum cell mesh in which the momentum equations are solved in (velocity is defined at the centers of the momentum mesh cells). The scalar mesh is defined by the user and the momentum mesh is built on top of it so that the centers of the momentum cells lie on the faces of the scalar cells.
I thought such a mesh would best be captured using the rectilinear format of VTK, but I couldn't figure out how to capture a non-square or rectangular geometry, such as the one shown here:
So instead, I used an unstructured grid because all the cell vertice information was easily obtainable (this was also easier to print out from the code because I didn't have to make considerations for the connectivity of the cells). The momentum cells will actually overlap each other because they are setup so that the centers are on the scalar cell faces. Therefore, only the centers of the cells are important, which is why I used points instead of a mesh to define the velocity vectors. See the previous figure if I add in a few momentum mesh cells, shown by the red dashed lines:
I modified the code so that each scalar cell now has six arrays associated with it: 1) x_location(i,j) - the x location, in meters, of the center of the scalar mesh cell 2) y_location(i,j) - the y location of the center of the scalar mesh cell 3) z_location(i,j) - the z location of the center of the scalar mesh cell 4) x_size(i,j) - the size of the scalar cell in the x direction 5) y_size(i,j) - the size of the scalar cell in the y direction 6) z_size(i,j) - the size of the scalar cell in the z direction
The i index represents a column of cells (a channel) stacked in the z direction. The j index represents a layer of cells, spanning the x,y directions.
A cell can be uniquely identified by the i and j indices. All scalar cell data is also given with respect to these indices (i.e. density(i,j), enthalpy(i,j), pressure(i,j), etc.).