def save2DcellReynoldsVTK(self, resPath, fileName, uu, vv, uv): '''Function to save single frame data for 3D vector field in VTK format now working for Reynolds Stress tensor 3 components ''' nx, ny, nz = self.cols, self.lins, 1 origin, spacing = (0.0,0.0,0.0), (self.xscale,self.yscale,0.0001) start, end = (0,0,0), (nx, ny, nz) uuvtk = np.ascontiguousarray(np.rot90(uu,k=1, axes=(1,0))) vvvtk = np.ascontiguousarray(np.rot90(vv,k=1, axes=(1,0))) uvvtk = np.ascontiguousarray(np.rot90(uv,k=1, axes=(1,0))) w = VtkFile(resPath + '/' + fileName, VtkImageData) w.openGrid(start = start, end = end, origin = origin, spacing = spacing) w.openPiece( start = start, end = end) # Cell data #zeroScalar = np.zeros([nx, ny, nz], dtype="float64", order='C') w.openData("Cell", vectors = fileName) w.addData(fileName, (uuvtk, vvvtk, uvvtk)) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data = (uuvtk,vvvtk,uvvtk)) w.save() return 0
def save2DcellVecVTK(self, resPath, fileName, U, V): '''Function to save single frame data for 2D vector field in VTK format ''' nx, ny, nz = self.cols, self.lins, 1 origin, spacing = (0.0,0.0,0.0), (self.xscale,self.yscale,0.0001) start, end = (0,0,0), (nx, ny, nz) Uvtk = np.ascontiguousarray(np.rot90(U,k=1, axes=(1,0))) Vvtk = np.ascontiguousarray(np.rot90(V,k=1, axes=(1,0))) w = VtkFile(resPath + '/' + fileName, VtkImageData) w.openGrid(start = start, end = end, origin = origin, spacing = spacing) w.openPiece( start = start, end = end) # Cell data zeroScalar = np.zeros([nx, ny, nz], dtype="float64", order='C') w.openData("Cell", vectors = "Velocities") w.addData("Velocities", (Uvtk, Vvtk, zeroScalar)) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data = (Uvtk,Vvtk,zeroScalar)) w.save() return 0
def rainfluxDiffToVTK(self, i, altPrefix): """ Get Candis filenames based on the prefix and a given integer""" file1 = self.prefix + "/" + self.prefix + "." + self.ipad(i) file2 = altPrefix + "/" + altPrefix + "." + self.ipad(i) """Get Candis file objects based on the prefix and a given integer""" cfile1 = ReadCandis(file1) cfile2 = ReadCandis(file2) rainflux1 = cfile1.getField('rainflux').data rainflux2 = cfile2.getField('rainflux').data nx, ny = rainflux1.shape nz = 1 ncells = nx * ny * nz start = (0, 0, 0) end = (nx, ny, nz) origin = (0.0, 0.0, 0.0) spacing = (1.0, 1.0, 1.0) rainflux1 = rainflux1.reshape(rainflux1.shape + (1, )) rainflux2 = rainflux2.reshape(rainflux2.shape + (1, )) rain_diff = rainflux2 - rainflux1 print "Maximum diff for", i, "is", rain_diff.max() w = VtkFile("rainflux_diff." + self.ipad(i), VtkImageData) w.openGrid(start, end, origin, spacing) w.openPiece(start, end) w.openData("Cell", scalars="rainflux_diff") w.addData("rainflux_diff", rain_diff) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data=rain_diff) w.save()
def __init__(self, filename, path='', timestep=0, npx=1, npy=1, npz=1, init_pvd=False): self.timestep = timestep prefix = '_{0}_{1}'.format(timestep, mpi.COMM_WORLD.Get_rank()) if not os.path.exists(path) and mpi.COMM_WORLD.Get_rank() == 0: os.mkdir(path) # All the processes wait for the creation of the output directory mpi.COMM_WORLD.Barrier() self.path = path self.filename = filename self.vtkfile = VtkFile(path + '/' + filename + prefix, VtkRectilinearGrid) self.end = np.zeros(3, dtype=np.int) self.x = None self.y = None self.z = None self.scalars = {} self.vectors = {} self._init_grid = True self._init_pvd = init_pvd self.npx = npx self.npy = npy self.npz = npz self.log = setLogger(__name__)
def save2DcellVecTransientVTK(self, resPath, fileName, U, V): '''function to save transient data for 2D vector field in VTK format ''' nx, ny, nz = self.cols, self.lins, 1 origin, spacing = (0.0,0.0,0.0), (self.xscale,self.yscale,0.0001) start, end = (0,0,0), (nx, ny, nz) print('Saving transient data into paraview format') for time,name in enumerate(self.fRes): Ut = U[:,:,time] Vt = V[:,:,time] Uvtk = np.ascontiguousarray(np.rot90(Ut,k=1, axes=(1,0))) Vvtk = np.ascontiguousarray(np.rot90(Vt,k=1, axes=(1,0))) w = VtkFile(resPath + '/' + fileName + str(time), VtkImageData) w.openGrid(start = start, end = end, origin = origin, spacing = spacing) w.openPiece( start = start, end = end) # Cell data zeroScalar = np.zeros([nx, ny, nz], dtype="float64", order='C') w.openData("Cell", vectors = "Velocities") w.addData("Velocities", (Uvtk, Vvtk, zeroScalar)) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data = (Uvtk,Vvtk,zeroScalar)) w.save() return 0
def _write_vtu_series(grid, coordinates, connectivity, data, filename_base, last_step, is_cell_data): steps = last_step + 1 if last_step is not None else len(data) fn_tpl = "{}_{:08d}" npoints = len(coordinates[0]) ncells = len(connectivity) ref = grid.reference_element if ref is ref is referenceelements.triangle: points_per_cell = 3 vtk_el_type = VtkTriangle.tid elif ref is referenceelements.square: points_per_cell = 4 vtk_el_type = VtkQuad.tid else: raise NotImplementedError("vtk output only available for grids with triangle or rectangle reference elments") connectivity = connectivity.reshape(-1) cell_types = np.empty(ncells, dtype='uint8') cell_types[:] = vtk_el_type offsets = np.arange(start=points_per_cell, stop=ncells*points_per_cell+1, step=points_per_cell, dtype='int32') group = VtkGroup(filename_base) for i in range(steps): fn = fn_tpl.format(filename_base, i) vtk_data = data[i, :] w = VtkFile(fn, VtkUnstructuredGrid) w.openGrid() w.openPiece(ncells=ncells, npoints=npoints) w.openElement("Points") w.addData("Coordinates", coordinates) w.closeElement("Points") w.openElement("Cells") w.addData("connectivity", connectivity) w.addData("offsets", offsets) w.addData("types", cell_types) w.closeElement("Cells") if is_cell_data: _addDataToFile(w, cellData={"Data": vtk_data}, pointData=None) else: _addDataToFile(w, cellData=None, pointData={"Data": vtk_data}) w.closePiece() w.closeGrid() w.appendData(coordinates) w.appendData(connectivity).appendData(offsets).appendData(cell_types) if is_cell_data: _appendDataToFile(w, cellData={"Data": vtk_data}, pointData=None) else: _appendDataToFile(w, cellData=None, pointData={"Data": vtk_data}) w.save() group.addFile(filepath=fn + '.vtu', sim_time=i) group.save()
def writeVTK(filename,xdim, ydim, pointData=None, cellData=None): """ Writes data values as a rectilinear or rectangular grid. PARAMETERS: path: name of the file without extension where data should be saved. cellData: dictionary containing arrays with cell centered data. Keys should be the names of the data arrays. Arrays must have the same dimensions in all directions and must contain only scalar data. nodeData: dictionary containing arrays with node centered data. Keys should be the names of the data arrays. Arrays must have same dimension in each direction and they should be equal to the dimensions of the cell data plus one and must contain only scalar data. RETURNS: Full path to saved file. """ nx, ny, nz = xdim, ydim, 0 lx, ly, lz = xdim/10.0, ydim/10.0, 0 dx, dy, dz = lx/nx, ly/ny, 0 ncells = nx * ny npoints = (nx + 1) * (ny + 1) * (nz + 1) x = np.arange(0, lx + 0.1*dx, dx, dtype='float64') y = np.arange(0, ly + 0.1*dy, dy, dtype='float64') z = np.arange(0,0, dtype='float64') start, end = (0,0,0), (nx, ny, nz) # Set up object w = VtkFile(filename, VtkRectilinearGrid) #Open XML tags w.openGrid(start = start, end = end) w.openPiece( start = start, end = end) # Coordinates of cell vertices w.openElement("Coordinates") w.addData("x_coordinates", x); w.addData("y_coordinates", y); w.addData("z_coordinates", z); w.closeElement("Coordinates"); # Add data from the dictionary #temp = np.random.rand(npoints) __addDataToFile(w, cellData, pointData) #Close XML tags w.closePiece() w.closeGrid() #Append Coordinate Data to file in binary form w.appendData(x).appendData(y).appendData(z) #Append Cell and Point Data to file in binary form __appendDataToFile(w, cellData, pointData) w.save() return w.getFileName()
def run(): print("Running lowlevel...") nx, ny, nz = 6, 6, 2 lx, ly, lz = 1.0, 1.0, 1.0 dx, dy, dz = lx / nx, ly / ny, lz / nz ncells = nx * ny * nz npoints = (nx + 1) * (ny + 1) * (nz + 1) x = np.arange(0, lx + 0.1 * dx, dx, dtype='float64') y = np.arange(0, ly + 0.1 * dy, dy, dtype='float64') z = np.arange(0, lz + 0.1 * dz, dz, dtype='float64') start, end = (0, 0, 0), (nx, ny, nz) w = VtkFile(FILE_PATH, VtkRectilinearGrid) w.openGrid(start=start, end=end) w.openPiece(start=start, end=end) # Point data temp = np.random.rand(npoints) vx = vy = vz = np.zeros([nx + 1, ny + 1, nz + 1], dtype="float64", order='F') w.openData("Point", scalars="Temperature", vectors="Velocity") w.addData("Temperature", temp) w.addData("Velocity", (vx, vy, vz)) w.closeData("Point") # Cell data pressure = np.ones([nx, ny, nz], dtype="float64", order='F') w.openData("Cell", scalars="Pressure") w.addData("Pressure", pressure) w.closeData("Cell") # Coordinates of cell vertices w.openElement("Coordinates") w.addData("x_coordinates", x) w.addData("y_coordinates", y) w.addData("z_coordinates", z) w.closeElement("Coordinates") w.closePiece() w.closeGrid() w.appendData(data=temp) w.appendData(data=(vx, vy, vz)) w.appendData(data=pressure) w.appendData(x).appendData(y).appendData(z) w.save()
def convertRainMixingToVTK(self, i, cfile): rr = cfile.getField('rr').data nx, ny, nz = rr.shape ncells = nx * ny * nz start = (0, 0, 0) end = (nx, ny, nz) origin = (0.0, 0.0, 0.0) spacing = (1.0, 1.0, 1.0) w = VtkFile("rr." + self.filename(i), VtkImageData) w.openGrid(start, end, origin, spacing) w.openPiece(start, end) w.openData("Cell", scalars="rr") w.addData("rr", rr) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data=rr) w.save()
def triangle_faces_to_VTK(filename, x, y, z, faces, point_data, cell_data): vertices = (x, y, z) x2 = x * 1. y2 = y * 1. z2 = z * 1. vert2 = (x2, y2, z2) w = VtkFile(filename, VtkUnstructuredGrid) w.openGrid() w.openPiece(npoints=len(x), ncells=len(faces)) w.openElement("Points") w.addData("Points", vertices) w.closeElement("Points") # Create some temporary arrays to write grid topology. ncells = len(faces) # Index of last node in each cell. offsets = np.arange(start=3, stop=3 * (ncells + 1), step=3, dtype='uint32') # Connectivity as unrolled array. connectivity = faces.reshape(ncells * 3).astype('int32') cell_types = np.ones(ncells, dtype='uint8') * VtkTriangle.tid w.openElement("Cells") w.addData("connectivity", connectivity) w.addData("offsets", offsets) w.addData("types", cell_types) w.closeElement("Cells") _addDataToFile(w, cellData=cell_data, pointData=point_data) w.closePiece() w.closeGrid() w.appendData(vert2) w.appendData(connectivity).appendData(offsets).appendData(cell_types) _appendDataToFile(w, cellData=cell_data, pointData=point_data) w.save() return w.getFileName()
def convertRainfluxToVTK(self, i, cfile): rainflux = cfile.getField('rainflux').data rainflux = rainflux.reshape(rainflux.shape + (1, )) (nx, ny, nz) = rainflux.shape print nx, ny, nz ncells = nx * ny * nz start = (0, 0, 0) end = (nx, ny, nz) origin = (0.0, 0.0, 0.0) spacing = (1.0, 1.0, 1.0) w = VtkFile("rainflux." + self.filename(i), VtkImageData) w.openGrid(start, end, origin, spacing) w.openPiece(start, end) w.openData("Cell", scalars="rainflux") w.addData("rainflux", rainflux) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data=rainflux) w.save()
def convertVelocitiesToVTK(self, i, cfile): vx = cfile.getField('vx').data vy = cfile.getField('vy').data vz = cfile.getField('vz').data nx, ny, nz = vx.shape ncells = nx * ny * nz start = (0, 0, 0) end = (nx, ny, nz) origin = (0.0, 0.0, 0.0) spacing = (1.0, 1.0, 1.0) w = VtkFile("v." + self.filename(i), VtkImageData) w.openGrid(start, end, origin, spacing) w.openPiece(start, end) w.openData("Cell", vectors="velocity") w.addData("velocity", (vx, vy, vz)) w.closeData("Cell") w.closePiece() w.closeGrid() w.appendData(data=(vx, vy, vz)) w.save()
def write_vtp_header(path, prefix, active_var_index, var_indices, variable_list, all_dim_vals, vertices, connectivity, offsets, nPoints, nPolygons, outType, cellData=True, pointData=False, xtime=None): # {{{ vtkFile = VtkFile("{}/{}".format(path, prefix), VtkPolyData) if xtime is not None: vtkFile.openElement(str("metadata")) vtkFile.openElement(str("xtime")) vtkFile.xml.addText(str(xtime)) vtkFile.closeElement(str("xtime")) vtkFile.closeElement(str("metadata")) vtkFile.openElement(vtkFile.ftype.name) vtkFile.openPiece(npoints=nPoints, npolys=nPolygons) vtkFile.openElement(str("Points")) vtkFile.addData(str("points"), vertices) vtkFile.closeElement(str("Points")) vtkFile.openElement(str("Polys")) vtkFile.addData(str("connectivity"), connectivity) vtkFile.addData(str("offsets"), offsets) vtkFile.closeElement(str("Polys")) if (cellData): vtkFile.openData( str("Cell"), scalars=[str(var) for var in variable_list[active_var_index]]) for iVar in var_indices: var_name = variable_list[iVar] (out_var_names, dim_list) = \ get_hyperslab_name_and_dims(var_name, all_dim_vals[var_name]) for out_var_name in out_var_names: vtkFile.addHeader(str(out_var_name), outType, nPolygons, 1) vtkFile.closeData(str("Cell")) if (pointData): vtkFile.openData( str("Point"), scalars=[str(var) for var in variable_list[active_var_index]]) for iVar in var_indices: var_name = variable_list[iVar] (out_var_names, dim_list) = \ get_hyperslab_name_and_dims(var_name, all_dim_vals[var_name]) for out_var_name in out_var_names: vtkFile.addHeader(str(out_var_name), outType, nPoints, 1) vtkFile.closeData(str("Point")) vtkFile.closePiece() vtkFile.closeElement(vtkFile.ftype.name) vtkFile.appendData(vertices) vtkFile.appendData(connectivity) vtkFile.appendData(offsets) return vtkFile # }}}
connections[2 * pair], connections[2 * pair + 1] = ids.index( id1_masked[pair]), ids.index(id2_masked[pair]) # The offset array is simply generated from 2*(1..ncells) offset = (np.arange(nconnex, dtype=int) + 1) * 2 # The type array is simply ncells x 3 (i.e. a VTKLine type) celltype = np.ones(nconnex, dtype=int) * 3 # ****************************************** # Write DATA to FILE (binary) # ****************************************** # create a VTK unstructured grid (.vtu) file vtufile = fileprefix + '_' + str(timestep) vtufile = os.path.join(outputdir, vtufile) w = VtkFile(vtufile, VtkUnstructuredGrid) vtufile += '.vtu' w.openGrid() w.openPiece(npoints=npoints, ncells=nconnex) # Set up Points (x,y,z) data XML w.openElement("Points") w.addData("points", (x, y, z)) w.closeElement("Points") # Set up Cell data w.openElement("Cells") w.addData("connectivity", connections) w.addData("offsets", offset) w.addData("types", celltype)
def pc2vtkxml(varfile = 'var.dat', datadir = 'data/', proc = -1, variables = ['rho','uu','bb'], magic = [], destination = 'work', quiet = True): """ Convert data from PencilCode format to XML vtk. Write .vts Structured Grid, not Rectilinear Grid as VisIt screws up reading Rectilinear Grid. However, this is set to write large grids in VTK XML, which is not yet suported by VisIt anyways. Use ParaView. call signature:: pc2xmlvtk(varfile = 'var.dat', datadir = 'data/', proc = -1, variables = ['rho','uu','bb'], magic = [], destination = 'work.vtk') Read *varfile* and convert its content into vtk format. Write the result in *destination*. Keyword arguments: *varfile*: The original varfile. *datadir*: Directory where the data is stored. *proc*: Processor which should be read. Set to -1 for all processors. *variables* = [ 'rho' , 'lnrho' , 'uu' , 'bb', 'b_mag', 'jj', 'j_mag', 'aa', 'tt', 'lnTT', 'cc', 'lncc', 'ss', 'vort', 'eth' ] Variables which should be written. *magic*: [ 'vort' , 'bb' ] Additional variables which should be written. *destination*: Destination file. """ # this should correct for the case the user type only one variable if (len(magic) > 0): if (len(magic[0]) == 1): magic = [magic] # make sure magic is set when writing 'vort' or 'bb' try: index = variables.index('vort') magic.append('vort') except: pass try: index = variables.index('bb') magic.append('bb') except: pass try: index = variables.index('b_mag') magic.append('bb') except: pass try: index = variables.index('tt') magic.append('tt') except: pass # get endian format of the data format = pc.get_format(datadir = datadir) # reading pc variables and setting dimensions var = pc.read_var(varfile = varfile, datadir = datadir, proc = proc, magic = magic, trimall = True, quiet = quiet, format = format) grid = pc.read_grid(datadir = datadir, proc = proc, trim = True, quiet = True, format = format) dimx = len(grid.x) dimy = len(grid.y) dimz = len(grid.z) dim = dimx * dimy * dimz scalardata = {} if ('rho' in variables) : rho = np.transpose(var.rho.copy()) scalardata['rho'] = rho if ('lnrho' in variables) : lnrho = np.transpose(var.lnrho.copy()) scalardata['lnrho'] = lnrho if ('tt' in variables) : tt = np.transpose(var.tt.copy()) scalardata['tt'] = tt if ('lntt' in variables) : lntt = np.transpose(var.lntt.copy()) scalardata['lntt'] = lntt if ('cc' in variables) : cc = np.transpose(var.cc.copy()) scalardata['cc'] = cc if ('lncc' in variables) : lncc = np.transpose(var.lncc.copy()) scalardata['lncc'] = lncc if ('ss' in variables) : ss = np.transpose(var.ss.copy()) scalardata['ss'] = ss if ('eth' in variables) : eth = np.transpose(var.eth.copy()) scalardata['eth'] = eth vectordata = {} if ('uu' in variables) : uu1 = np.transpose(var.uu[0,:,:,:].copy()) uu2 = np.transpose(var.uu[1,:,:,:].copy()) uu3 = np.transpose(var.uu[2,:,:,:].copy()) vectordata['uu'] = (uu1,uu2,uu3) if ('bb' in variables) : bb1 = np.transpose(var.bb[0,:,:,:].copy()) bb2 = np.transpose(var.bb[1,:,:,:].copy()) bb3 = np.transpose(var.bb[2,:,:,:].copy()) vectordata['bb'] = (bb1,bb2,bb3) if ('jj' in variables) : jj1 = np.transpose(var.jj[0,:,:,:].copy()) jj2 = np.transpose(var.jj[1,:,:,:].copy()) jj3 = np.transpose(var.jj[2,:,:,:].copy()) vectordata['jj'] = (jj1,jj2,jj3) if ('aa' in variables) : aa1 = np.transpose(var.aa[0,:,:,:].copy()) aa2 = np.transpose(var.aa[1,:,:,:].copy()) aa3 = np.transpose(var.aa[2,:,:,:].copy()) vectordata['aa'] = (aa1,aa2,aa3) if ('vort' in variables) : vort1 = np.transpose(var.vort[0,:,:,:].copy()) vort2 = np.transpose(var.vort[1,:,:,:].copy()) vort3 = np.transpose(var.vort[2,:,:,:].copy()) vectordata['vort'] = (vort1,vort2,vort3) X = np.zeros([dimx,dimy,dimz]) Y = np.zeros([dimx,dimy,dimz]) Z = np.zeros([dimx,dimy,dimz]) for k in range(dimz): for j in range(dimy): for i in range(dimx): X[i,j,k] = grid.x[i] Y[i,j,k] = grid.y[j] Z[i,j,k] = grid.z[k] start = (0,0,0) end = (dimx-1, dimy-1, dimz-1) time = np.array([var.t]) w = VtkFile(destination, VtkStructuredGrid,largeFile=True) w.openGrid(start = start, end = end) #this s for wirting Time in VisIt files. However, when usign large grid Visit does not work anyways. #w.openFieldData() #w.addTuple('TIME', time.dtype.name,len(time)) #w.closeFieldData() w.openPiece(start = start, end = end) w.openElement("Points") w.addData("points", (X,Y,Z)) w.closeElement("Points") w.openData("Point", scalars = scalardata.keys(), vectors = vectordata.keys()) for key in scalardata: w.addData(key,scalardata[key]) for key in vectordata: w.addData(key,vectordata[key]) w.closeData("Point") w.closePiece() w.closeGrid() #w.appendData( time ) w.appendData( (X,Y,Z) ) for key in scalardata: w.appendData(data = scalardata[key]) for key in vectordata: w.appendData(data = vectordata[key]) w.save()
# ************************************************************** from evtk.vtk import VtkFile, VtkRectilinearGrid import numpy as np nx, ny, nz = 6, 6, 2 lx, ly, lz = 1.0, 1.0, 1.0 dx, dy, dz = lx / nx, ly / ny, lz / nz ncells = nx * ny * nz npoints = (nx + 1) * (ny + 1) * (nz + 1) x = np.arange(0, lx + 0.1 * dx, dx, dtype='float64') y = np.arange(0, ly + 0.1 * dy, dy, dtype='float64') z = np.arange(0, lz + 0.1 * dz, dz, dtype='float64') start, end = (0, 0, 0), (nx, ny, nz) w = VtkFile("./evtk_test", VtkRectilinearGrid) w.openGrid(start=start, end=end) w.openPiece(start=start, end=end) # Point data temp = np.random.rand(npoints) vx = vy = vz = np.zeros([nx + 1, ny + 1, nz + 1], dtype="float64", order='F') w.openData("Point", scalars="Temperature", vectors="Velocity") w.addData("Temperature", temp) w.addData("Velocity", (vx, vy, vz)) w.closeData("Point") # Cell data pressure = np.zeros([nx, ny, nz], dtype="float64", order='F') w.openData("Cell", scalars="Pressure") w.addData("Pressure", pressure)
data4 = file['/Fields/Ex'][...] data5 = file['/Fields/Ey'][...] data6 = file['/Fields/Ez'][...] data7 = file['/Fields/Rho_0'][...] data8 = file['/Fields/Rho_1'][...] data9 = file['/Fields/Jx_0'][...] data10 = file['/Fields/Jy_0'][...] data11 = file['/Fields/Jz_0'][...] data12 = file['/Fields/Jx_1'][...] data13 = file['/Fields/Jy_1'][...] data14 = file['/Fields/Jz_1'][...] # Write the VTK file start, end = (0, 0, 0), (nx, ny, nz) w = VtkFile(vtkfilename + "_" + cycle, VtkRectilinearGrid) w.openGrid(start=start, end=end) w.openPiece(start=start, end=end) # Cell data w.openData("Cell", scalars="Rho_0, Rho_1", vectors="B, E, J_0, J_1") w.addData("Rho_0", data7) w.addData("Rho_1", data8) w.addData("B", (data1, data2, data3)) w.addData("E", (data4, data5, data6)) w.addData("J_0", (data9, data10, data11)) w.addData("J_1", (data12, data13, data14)) w.closeData("Cell") # Coordinates of cell vertices w.openElement("Coordinates")