I will present here an example code that produces something I want to see (it is not my personal resolution of the problem). Still not perfect, but I think this could be the way to it. I appreciate any further comments/solutions that can improve it.

Using datafile with a sample data:

```
1 -0.491412 -0.483779 -0.483779 4 0.00121829
2 -0.483779 -0.491412 -0.391221 7 0.000570934
3 -0.483779 -0.391221 -0.491412 7 0.00106746
4 -0.483779 -0.391221 -0.391221 4 0.000223109
5 -0.391221 -0.483779 -0.483779 7 0.000710743
6 -0.391221 -0.483779 -0.383588 4 -7.20294e-06
7 -0.391221 -0.383588 -0.483779 4 0.000269441
8 -0.383588 -0.391221 -0.391221 7 4.84198e-06
9 -0.451336 -0.423664 -0.423664 4 0.000522623
10 -0.423664 -0.451336 -0.451336 7 0.00239021
```

If someone needs the full data to play with it, just let me know, but I guess one can also just produce 4D spherical data for this purpose.

Of course, my data is much much longer (~100k datapoints), here first column is just an index from 1 --> N, then x,y,z,t, coordinates, then color (value of the charge). The code takes an argument of the filename and t, and plots sections for all "t" , so for all 3-dim hypersurfaces. And from that, I can make a "video" by gluing the pictures and presenting them after each other.

```
from sys import argv
import numpy as np
from mayavi import mlab
from tvtk.api import tvtk
if len(argv)<3:
print(f"usage: python {argv[0]} <filename> <t_select>")
exit(0)
data=np.loadtxt(argv[1])
data[:,4]-=4 # shift since code starts from 1 not 0
# center max topcharge dens
idx_max = np.argmax(data[:,5])
xyz_new_center=data[idx_max,1:4]
xyz_min=np.min(data[:,1:4],axis=0)
xyz_max=np.max(data[:,1:4],axis=0)
#xyz_shift=xyz_max-0.5*(xyz_max+xyz_min)
xyz_sizes=(xyz_max-xyz_min)
xyz_new_min=xyz_new_center-xyz_sizes/2.
xyz_new_max=xyz_new_center+xyz_sizes/2.
print("center:",xyz_new_center)
print("min coords:",xyz_min)
print("max coords:",xyz_max)
# set x in range [a,b]:
# x' = (x-0.5*(b+a)+b-a)%(b-a)+0.5*(b+a)
for i in range(3):
data[:,1+i]=(data[:,1+i]-xyz_new_min[i]+xyz_sizes[i])%(xyz_sizes[i])+xyz_new_min[i] #+xyz_new_center[i]
def plot_contour3d_spatial_slice(data,t_select):
# dat=data[np.abs(data[:,4]-t_select)<1e-8]
dat=data[np.abs(data[:,4]-t_select)<1e-8]
# x, y, z = dat[:,1], dat[:,2], dat[:,3]
topcharge_density = dat[:,5]
points = dat[:,1:4] # x,y,z
ug = tvtk.UnstructuredGrid(points=points)
ug.point_data.scalars = topcharge_density
ug.point_data.scalars.name = "topcharge density"
ds = mlab.pipeline.add_dataset(ug)
delaunay = mlab.pipeline.delaunay3d(ds)
iso = mlab.pipeline.iso_surface(delaunay)
iso.actor.property.opacity = 0.15
iso.contour.number_of_contours = 20
mlab.colorbar()
t_select=int(argv[2])
plot_contour3d_spatial_slice(data,t_select)
mlab.show()
```

In my current configuration, I have only one blob that I want to visualize, and the above code does that, relative nicely.

`voxel.dem`

and`gen-random.inc`

from the gnuplot/demo directory and set`nsamp = 100000`

.