Abstract
We consider the problem of cutting a subset of the edges of a polyhedral 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 in general, even for manifolds without boundary and for punctured spheres. We also describe an algorithm with running time no(g+k), where n is the combinatorial complexity, g is the genus, and k is the number of boundary components of the input surface. Finally, we describe a greedy algorithm that outputs a O(log2 g)-approximation of the minimum cut graph in O (g2n log n) time.
Cite
CITATION STYLE
Erickson, J., & Har-Peled, S. (2004). Optimally Cutting a Surface into a Disk. In Discrete and Computational Geometry (Vol. 31, pp. 37–59). Springer New York. https://doi.org/10.1007/s00454-003-2948-z
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