I have a set of 3D points defining a 3D contour. What I want to do is to obtain the minimal surface representation corresponding to this contour (see Minimal Surfaces in Wikipedia). Basically this requires to solve a nonlinear partial differential equation.

In Matlab this is almost straightforward using the `pdenonlin`

function (see Matlab's documentation). An example of its usage for solving a minimal surface problem can be found here: Minimal Surface Problem on the Unit Disk.

I need to make such an implementation in Python, but up to know I haven't found any web resources on how to to this.

Can anyone point me any resources/examples of such implementation?

Thanks, Miguel.

**UPDATE**

The 3D surface (ideally a triangular mesh representation) I want to find is bounded by this set of 3D points (as seen in this figure, the points lie in the best-fit plane):

Ok, so doing some research I found that this minimal surface problem is related with the solution of the Biharmonic Equation, and I also found that the Thin-plate spline is the fundamental solution to this equation.

So I think the approach would be to try to fit this sparse representation of the surface (given by the 3D contour of points) using thin-plate splines. I found this example in scipy.interpolate where scattered data (x,y,z format) is interpolated using thin-plate splines to obtain the ZI coordinates on a uniform grid (XI,YI).

Two questions arise: (1) Would thin-plate spline interpolation be the correct approach for the problem of computing the surface from the set of 3D contour points? (2) If so, how to perform thin-plate interpolation on scipy with a NON-UNIFORM grid?

Thanks again! Miguel

**UPDATE: IMPLEMENTATION IN MATLAB (BUT IT DOESN'T WORK ON SCIPY PYTHON)**

I followed this example using Matlab's `tpaps`

function and obtained the minimal surface fitted to my contour on a uniform grid. This is the result in Matlab (looks great!):

However I need to implement this in Python, so I'm using the package scipy.interpolate.Rbf and the `thin-plate`

function. Here's the code in python (`XYZ`

contains the 3D coordinates of each point in the contour):

```
GRID_POINTS = 25
x_min = XYZ[:,0].min()
x_max = XYZ[:,0].max()
y_min = XYZ[:,1].min()
y_max = XYZ[:,1].max()
xi = np.linspace(x_min, x_max, GRID_POINTS)
yi = np.linspace(y_min, y_max, GRID_POINTS)
XI, YI = np.meshgrid(xi, yi)
from scipy.interpolate import Rbf
rbf = Rbf(XYZ[:,0],XYZ[:,1],XYZ[:,2],function='thin-plate',smooth=0.0)
ZI = rbf(XI,YI)
```

However this is the result (quite different from that obtained in Matlab):

It's evident that scipy's result does not correspond to a minimal surface.

Is scipy.interpolate.Rbf + thin-plate doing as expected, why does it differ from Matlab's result?

discrete minimal surfaces. Instead of approximating a continuous minimal surface using a triangle mesh, discrete minimal surfaces come from a discretized version of mimimal surface theory. Wikipedia mentions page.mi.fu-berlin.de/polthier/articles/diri/diri_jem.pdf as a reference, which looks reasonable. Google scholar hasa lotmore references. Might be that for these you don't need to solve PDEs but only iteratively integrate stuff instead. – MvG May 19 '13 at 13:24