I am trying to implement the following Bowyer-Watson algorithm to implement Delaunay Triangulation.
function BowyerWatson (pointList) // pointList is a set of coordinates defining the points to be triangulated triangulation := empty triangle mesh data structure add super-triangle to triangulation // must be large enough to completely contain all the points in pointList for each point in pointList do // add all the points one at a time to the triangulation badTriangles := empty set for each triangle in triangulation do // first find all the triangles that are no longer valid due to the insertion if point is inside circumcircle of triangle add triangle to badTriangles polygon := empty set for each triangle in badTriangles do // find the boundary of the polygonal hole for each edge in triangle do if edge is not shared by any other triangles in badTriangles add edge to polygon for each triangle in badTriangles do // remove them from the data structure remove triangle from triangulation for each edge in polygon do // re-triangulate the polygonal hole newTri := form a triangle from edge to point add newTri to triangulation for each triangle in triangulation // done inserting points, now clean up if triangle contains a vertex from original super-triangle remove triangle from triangulation return triangulation
The algorithm takes O(N log N) operations to triangulate N points as claimed. But is there any way to calculate it from the above algorithm? I mean which part of the above algorithm takes log N times, which results in (N log N) for n points? special degenerate cases exist where this goes up to O(N2) as written in wikipedia. What is the meaning of this degenerate case?