I'll apologize in advance in case this is obvious; I've been unable to find the right terms to put into Google.
What I want to do is to find a bounding volume (AABB is good enough) for an arbitrary parametric range over a trimmed NURBS surface. For instance, (u,v) between (0.1,0.2) and (0.4,0.6).
EDIT: If it helps, it would be fine for me if the method confined the parametric region entirely within a bounding region as defined in the paragraph below. I am interested in sub-dividing those regions.
I got started thinking about this after reading this paragraph from this paper ( http://www.cs.utah.edu/~shirley/papers/raynurbs.pdf ), which explains how to create a tree of bounding volumes with a depth relative to the degree of the surface:
The convex hull property of B-spline surfaces guarantees that the surface is contained in the convex hull of its control mesh. As a result, any convex objects which bound the mesh will bound the underlying surface. We can actually make a stronger claim; because we closed the knot intervals in the last section [made the multiplicity of the internal knots k − 1], each nonempty interval [ui; ui+1) [vj; vj+1) corresponds to a surface patch which is completely contained in the convex hull of its corresponding mesh points. Thus, if we produce bounding volumes for each of these intervals, we will have completely enclosed the surface. We form the tree by sorting the volumes according tothe axis direction which has greatest extent across the bounding volumes, splitting the data in half, and repeating the process.