Discrete & Computational Geometry
31(1):37-59, 2004.
(Special issue of invited papers from the 18th Annual ACM Symposium on Computational Geometry)
Discrete & Computational Geometry
31(1):37-59, 2004.
(Special issue of invited papers from the
18th Annual ACM Symposium on Computational Geometry)
Proceedings of the 18th Annual ACM Symposium on Computational Geometry, 244-253, 2002.
![[PS]](pix/ps.gif){kind=small}
![[PDF]](pix/pdf.gif){kind=small}
Abstract:
We consider the problem of cutting a subset of edges of a triangulated oriented manifold surface, possibly with boundary, to obtain a single topological disk, minimizing either the total number of cut edges or their total length. We show that this problem is NP-hard, even for manifolds without boundary and for punctured spheres. We also describe an algorithm with running time nO(g+k), where n is the number of vertices, g is the genus, and k is the number of boundary components of the input surface. Finally, we describe a greedy algorithm that outputs an O(log2 g)-approximation of the minimum cut graph in O(g2n log n) time.
Publications -
Jeff Erickson
(jeffe@cs.uiuc.edu)
18 Feb 2004