Degree Bounded Network Design with Metric Costs
Chan, Y.H.
Fung, W.S.
Lau, L.C.
Yung, C.K.
Dept. of Comput. Sci. & Eng., Chinese Univ. of Hong Kong, Hong Kong;
This paper appears in: Foundations of Computer Science, 2008. FOCS '08. IEEE 49th Annual IEEE Symposium on
Publication Date: 25-28 Oct. 2008
On page(s): 125-134
Location: Philadelphia, PA,
ISSN: 0272-5428
ISBN: 978-0-7695-3436-7
INSPEC Accession Number: 10408708
Digital Object Identifier: 10.1109/FOCS.2008.28
Current Version Published: 2008-12-02
Abstract
Given a complete undirected graph, a cost function on edges and a degree bound B, the degree bounded network design problem is to find a minimum cost simple subgraph with maximum degree B satisfying given connectivity requirements. Even for simple connectivity requirement such as finding a spanning tree, computing a feasible solution for the degree bounded network design problem is already NP-hard, and thus there is no polynomial factor approximation algorithm for this problem. In this paper, we show that when the cost function satisfies triangle inequalities, there are constant factor approximation algorithms for various degree bounded network design problems.Global edge-connectivity: There is a (2+1/k)-approximation algorithm for the minimum bounded degree k-edge-connected subgraph problem. Local edge-connectivity: There is a 6-approximation algorithm for the minimum bounded degree Steiner network problem. Global vertex-connectivity: there is a (2+(k-1)/n+1/k)-approximation algorithm for the minimum bounded degree k-vertex-connected subgraph problem. Spanning tree: there is an (1+1/(d-1))-approximation algorithm for the minimum bounded degree spanning tree problem. These approximation algorithms return solutions with smallest possible maximum degree, and the cost guarantee is obtained by comparing to the optimal cost when there are no degree constraints. This demonstrates that degree constraints can be incorporated into network design problems with metric costs.Our algorithms can be seen as a generalization of Christofides' algorithm for metric TSP. The main technical tool is a simplicity-preserving edge splitting-off operation, which is used to "short-cut" vertices with high degree while maintaining connectivity requirements and preserving simplicity of the solutions.
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