As part of my work, I often have to visualize complex 3 dimensional densities. One program suite that I work with outputs the radial component of the densities as a set of 781 points on a logarithmic grid, `ri = (Rmax/Rstep)^((i-1)/(pts-1)`

, times a spherical harmonic. For low symmetry systems, the number of spherical harmonics can be fairly large to ensure accuracy, e.g. one system requires 49 harmonics corresponding to `lmax = 6`

. So, to use this data within Mathematica, I would have a sum of up to 49 interpolated functions with each multiplied by a different spherical harmonic. While using v.6 and constructing the interpolated radial functions using `Interpolation`

and setting `r = Sqrt(x^2 + y^2 + z^2)`

, I would stop `ContourPlot3D`

after well over an hour without anything displayed. This included reducing both the `InterpolationOrder`

and `MaxRecursion`

to 1.

Several alternatives presented themselves:

- Evaluate the density function on a fixed grid, and use
`ListContourPlot`

instead. - Or, linearly spline the radial function and use
`Piecewise`

to stitch them together. (This presented itself, as I could use simplify to help reduce the complexity of the resulting function.)

I ended up using both, as `InterpolatingFunction`

gives a noticeable delay in its evaluation, and with up to 49 interpolated functions to evaluate, any delay can become noticeable. Also, `ContourPlot3D`

was faster with the spline, but it didn't give me the speed up I desired.

I'll freely admit that I haven't tried `Interpolation`

on v.7, nor I have tried this on my upgraded hardware (G4 v. Intel Core i5). However, I'm looking for alternatives to my current scheme; preferably, one where I can use `ContourPlot3D`

directly. I could try some other form of spline, such as a B-spline, and possibly combine that with `UnitBox`

instead of using `Piecewise`

.

**Edit:** Just to clarify, my current implementation involves creating a first order spline for each radial part, multiplying each one by their respective spherical harmonic, summing and `Simplify`

ing the equations on each radial interval, and then using `Piecewise`

to bind them into one function. So, my implementation is semi-analytical in that the spherical harmonics are exact, and only the radial part is numerical. This is part of the reason why I would like to be able to use `ContourPlot3D`

, so that I can take advantage of the semi-analytical nature of the data. As a point of note, the radial grid is fine enough that a good representation of the radial part is generated and can be smoothly interpolated. While this gave me a significant speed-up, when I wrote the code, it was still to slow for the hardware I was using at the time.

So, instead of using `ContourPlot3D`

, I would first generate the function, as above, then I would evaluate it on an 80^{3} Cartesian grid. It is the data from this step that I used in `ListContourPlot3D`

. Since this is not an adaptive grid, in some places this was too course, and I was missing features.

`DataRange`

and data only for`ListContourPlot`

-- otherwise it looks like there is an internal layer of interpolation, see stackoverflow.com/questions/2497517/… – Janus Oct 26 '10 at 7:26`{x,y,z,f}`

form when using`ListContourPlot3D`

before, but here I've generated a 3D array and specified the`DataRange`

. Additionally, while slow, the internal layer of interpolation in`ListContourPlot3D`

is still faster than`ContourPlot3D`

. – rcollyer Oct 26 '10 at 13:21