If you only have plots but need the data: automeris.io/WebPlotDigitizer

Does anyone have experience with "conformal interpolation"?

Basically I have a set of points: for each point: (x, y) I have a transformed point f(x,y), but I don't know the transformation f

now I'd like to "approximate" f with a conformal map (=locally angle preserving)

I just realized I should have called it regression instead of interpolation

@flawr sounds like something really difficult. Perhaps image processing with warping/morphing knows about good methods.

@flawr You should try thin plate splines. Because of the local rigidity, I'd expect the mapping to be conformal, though I haven't seen anybody refer to this property. But it certainly looks like that to me, seeing how it transforms images.

@AndrasDeak thanks for the suggestions!

@CrisLuengo so I really just know thin plate splines in the context of 1d interpolation, so I just want to clarify: Since the "input" is 2d would this mean that you'd do a thin-plate-RBF interpolation (for each of the output coordinates)?

Here's a C++ implementation: github.com/DIPlib/diplib/blob/… (header) github.com/DIPlib/diplib/blob/master/src/support/… (code).

Thin plates can be defined in any number of dimensions.

Indeed you use a RBF.

Thanks for the links!

@CrisLuengo Ok I see, thanks!

(right, I mean the derivation using the "thin plates" only makes sense in 1d:)

I thought the term "thin plate" implied a 2D domain. Would a 1D version not be called "thin rod"? :)

Huh you're right!

I did some internet-rabbit-holing:)

I only had a faint idea in mind about the motivation of (C2-) splines coming from the drafting tool with the same name, and I confused the two.

So the thin-plate-splines are indeed motivated by the idea of a piece of sheet metal

nice

so the cubic (C2) splines have the minimum bending energy (integral (second derivative)^2) property in an 1D domain, while the thinplate spline minimizes the minimum bending energy in 2d (integral 2(df/dxdy)^2 + (df/dx^2)^2 + (df/dy^2)^2)

but it is so interesting that the outcomes of the corresponding RBFs are so different!

I've yet to read about how RBFs work

I wonder what we can find a similar explicit expression for the 3D case, or the ND case:)

@AndrasDeak I thought you are the RBF expert here?

trump_wrong.gif

I'm positive it was you who sent me a introduction to RBFs a few years ago!

impossible

the one thing I and RBFs have in common is my use of them in my python 2d interpolation canonical, and it's used as a black box (since they are a black box to me)

unless we discovered together and you read what we found and I didn't :P

then I need to update the database in my brain of the "top 5 rbf experts in chatlab"

but at least you motivated me to read about it then

you can try looking at hits in chat.stackoverflow.com/search?room=81987&q=rbf

@AndrasDeak someone must have changed the chat history!

and I just asked a question regarding the generalization: math.stackexchange.com/questions/3778881/…

@CrisLuengo ^ in case you want to take responsibility for the rabbit hole you sent me into :D

The implementation that I linked works for arbitrary number of dimensions.