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I'm not really sure if this fits in here or better in a scientific computer science or math forum but since I'm searching for a concrete algorithm...

I have a 3d model which is somehow defined either by a mesh or as an algebraic variety and i want to remesh/approximate this thing just using a fixed chosen type of congruent tiles, e.g. isoscele triangles with certain ratio of sides length to the base length. Is there a algorithm for that or does anyone know the right name for the problem? I found some algorithms that come close to what I need, but they all mesh via some tolerance in the length and different sizes of the tiles.

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You can't approximate the sphere arbitrarily well with equilateral triangles. The same applies to any other tiles. Reason: angle defect around each vertex. – Jan Dvorak Nov 27 '12 at 4:51
I'm pretty sure I can, when i let the shrink the triangles arbitrarily. – javra Nov 27 '12 at 4:55
Then we're not talking about congruence, and it's still impossible. – Jan Dvorak Nov 27 '12 at 4:56
Care for a proof in the more general case where only similarity needs to be preserved for triangular tiles of any class? – Jan Dvorak Nov 27 '12 at 4:57

1 Answer 1

In freeform shapes tiling is achieved via a very complicated algorithm. In real world architecture there is this method of tiling with as many identical tiles as possible and still get the shape, but there are angle tolerances and all sort of tolerances that you can manipulate. check paneling of freeform shapes.

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Do you have any useful source for that? I always get search results that do not really fit my needs... – javra Mar 27 '13 at 1:37
I always get search results that do not really fit my needs... I have nearly no freedom in the triangle shape and i want to minimize difference in the normals and the number of "torsion points" (as they are called in the papers i found so far) – javra Mar 27 '13 at 1:56

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