def generate_temporal_vtk(output_path):
for dtype in ("mesh", "particles"):
group = VtkGroup("{}/pseudo_temporal_{}".format(output_path, dtype))
dfiles = sorted(glob.glob("{}/{}*".format(output_path, dtype)))
for t, df in enumerate(dfiles):
group.addFile(filepath = df, sim_time = t)
group.save()
def generate_temporal_vtk(output_path):
for dtype in ("mesh", "particles"):
group = VtkGroup("{}/pseudo_temporal_{}".format(output_path, dtype))
dfiles = sorted(glob.glob("{}/{}*".format(output_path, dtype)))
for t, df in enumerate(dfiles):
group.addFile(filepath=df, sim_time=t)
group.save()
y = numpy.zeros((radius_number + 1, angle_number + 1, node_number))
z = numpy.zeros((radius_number + 1, angle_number + 1, node_number))
# Group
vtk_group = VtkGroup("cylinder/RiserGroup")
# cnt=0
for time_index in range(time.size):
for k in range(node_number):
# Nodal displacement
x_deviation = displacement_x[time_index][k]
y_deviation = displacement_y[time_index][k]
z_deviation = k/float(node_number) * length
#
# Trans
for j in range(angle_number + 1):
for i in range(radius_number + 1):
rad = numpy.radians(angle_axis[j])
x[i, j, k] = radius_axis[i] * numpy.cos(rad) + x_deviation
y[i, j, k] = radius_axis[i] * numpy.sin(rad) + y_deviation
z[i, j, k] = z_deviation
# Variables
#
# Output
str1 = str(time_index)
filename = 'cylinder/' + 'cylinder' + str1.zfill(4)
filename_extension = filename + '.vts'
gridToVTK(filename, x, y, z)
vtk_group.addFile(filepath=filename_extension, sim_time=time[time_index])
vtk_group.save()
