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 pdenonlinfunction (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.


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):

enter image description here

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


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!): enter image description here

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):

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):

enter image description here

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?

  • What exactly is the relation between your 3d points and your desired output? Do you have points which lie approximately on the minimal surface, and you are looking for an algebraic description of that surface? Or do the points describe some kind of boundary, and you are looking for the minimal surface defined by that boundary? What form should your output have? It might help to see the whole matlab code, so that one could look for ways to translate that even without understanding the interpretation as minimal surfaces. Does launchpad.net/cbcpdesys look useful? – MvG May 18 '13 at 21:22
  • @MvG: see more details in my updated question. (1) The points lie approximately on the minimal surface; (2) The points describe the boundary of the, not-yet-obtained, surface (3) Ideally the kind of surface I want to obtain is a triangular mesh representation. – CodificandoBits May 19 '13 at 12:23
  • Try also asking in scicomp.stackexchange.com. – lhf May 19 '13 at 12:42
  • If your aim is a triangle mesh, then I suggest you look into 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 has a lot more 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
  • This question has also been posted at scicomp.stackexchange.com/q/7268 and a similar one at math.stackexchange.com/q/396336/35416. – MvG May 19 '13 at 21:33

The question states that we need to solve a nonlinear partial differential equation. However Wikipedia states that 'They are difficult to study: there are almost no general techniques that work for all such equations, and usually each individual equation has to be studied as a separate problem.' However, you didn't give the equation! And does Matlab sometimes use genetic algorithms to arrive at its surfaces? That is, does it use a rule of thumb to make a best guess and then tries out small variations in the component squares until no smaller surface can be found. Implementing that kind of solution would be laborious but not conceptually difficult (assuming you like that sort of thing). Also remember that the calculus of continuous functions is just a special case of the calculus of all the linear approximations of functions (the increment is set to zero instead of some finite value). This was made clear to me by reading the books of J L Bell on smooth infinitesimal analysis - just use that algebra with finite increments and leave the resulting factors in the derivations instead of 'neglecting' them.


Obviously Matlab and SciPy understand TPS in different ways. The Matlab implementation looks correct. SciPy treats TPS the same way as others RBFs, so you could implement it correctly in Python yourself - it would be enough to form a matrix of the related linear equation system and solve it to receive TPS' coefficients.

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