Abstract

In this paper we develop a method to parameterize tubular surfaces onto the cylinder. The cylinder can be seen\nas the natural parameterization domain for tubular surfaces since they share the same topology. Most present\nalgorithms are designed to parameterize disc-like surfaces onto the plane. Surfaces with a different topology are cut\ninto disc-like patches and the patches are parameterized separately. This introduces discontinuities and constrains\nthe parameterization. Also the semantics of the surface are lost. We avoid this by parameterizing tubular surfaces\non, their natural domain, the cylinder. Since the cylinder is locally isometric to the plane we can do calculations\non the cylinder without loosing efficiency. For speeding up the calculation we use a progressive parameterization\ntechnique, as suggested in recent literature. Together, this results in a robust, efficient, continuous, and semantics\npreserving parameterization method for arbitrary tubular surfaces.