I want to triangulate a polygon (without selfintersection, but with holes and the polygon can also be concav). In this question (e.g.): Delaunay triangulating the 2d polygon with holes a Constrained Delaunay Triangulation is proposed. What I was wondering about: is this the best way to do so or is it like "using a sledge-hammer to crack a nut"? An alternativ would be to use an algorithm for creating a "normal" triangulation (eg splitting the polygon in y-monoton parts and triangulate these parts) and flipping the edges afterwards. But it seams that (nearly) nobody takes this solution. Is there a reason? What are the pros and cons for one of these solutions? (the polygons can have an arbitrary size)
There are a few reasons to prefer (constrained) Delaunay triangulations to other approaches:
R^2it can be proven that such a triangulation is the "best" way to triangulate a given geometry -- resulting in a triangulation that maximises the minimum angle. This is equivalent to producing triangles of optimal quality, without any "skinny" elements.
Forming the Delaunay triangulation is efficient (i.e.
Delaunay triangulations generalise to higher-dimensional problems (i.e. tetrahedrons in
R^3and general simplexes in
Delaunay triangulations induce an orthogonal dual complex (i.e. the Voronoi diagram). This can be important for certain classes of numerical methods.
Depending on what exactly you're looking to achieve, you might find one or more of these criteria persuasive. Other options, such as ear-clipping or monotone slab triangulation, can be competitive in some areas, but don't, IMO, exhibit the same kind of overall performance.
You can try alpha shapes. It is defined as a delaunay triangulation without edges exceeding alpha.
All you need is EarClipping, please check this link.