Abstract
The polynomial-time solvable k-hurdle problem is a natural generalization of the classical s-t minimum cut problem where we must select a minimum-cost subset S of the edges of a graph such that |p∩S|≥k for every s-t path p. In this paper, we describe a set of approximation algorithms for “k-hurdle” variants of the NP-hard multiway cut and multicut problems. For the k-hurdle multiway cut problem with r terminals, we give two results, the first being a pseudo-approximation algorithm that outputs a (k−1)-hurdle solution whose cost is at most that of an optimal solution for k hurdles. Secondly, we provide a \(2(1-\frac{1}{r})\)-approximation algorithm based on rounding the solution of a linear program, for which we give a simple randomized half-integrality proof that works for both edge and vertex k-hurdle multiway cuts that generalizes the half-integrality results of Garg et al. for the vertex multiway cut problem. We also describe an approximation-preserving reduction from vertex cover as evidence that it may be difficult to achieve a better approximation ratio than \(2(1-\frac{1}{r})\). For the k-hurdle multicut problem in an n-vertex graph, we provide an algorithm that, for any constant ε>0, outputs a ⌈(1−ε)k⌉-hurdle solution of cost at most O(log n) times that of an optimal k-hurdle solution, and we obtain a 2-approximation algorithm for trees.
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References
Avidor, A., Langberg, M.: The multi-multiway cut problem. In: Proceedings of the 9th Scandinavian Workshop on Algorithm Theory (SWAT), pp. 273–284 (2004)
Barany, I., Edmonds, J., Wolsey, L.A.: Packing and covering a tree by subtrees. Combinatorica 6(3), 221–233 (1986)
Burch, C., Carr, R., Krumke, S., Marathe, M., Phillips, C.A.: A decomposition-based pseudoapproximation algorithm for network flow inhibition. In: Woodruff, D.L. (ed.) Network Interdiction and Stochastic Integer Programming, pp. 51–68. Kluwer Academic, Dordrecht (2003)
Burch, C., Krumke, S., Marathe, M., Phillips, C.A., Sundberg, E.: Multicriteria approximation through decomposition. Technical Report (1997)
Călinescu, G., Karloff, H.J., Rabani, Y.: An improved approximation algorithm for MULTIWAY CUT. J. Comput. Syst. Sci. 60(3), 564–574 (2000)
Carr, R., Fujito, T., Konjevod, G., Parekh, O.: A 2 1/10-approximation algorithm for a generalization of the weighted edge-dominating set problem. J. Comb. Optim. 5, 317–326 (2001)
Cheung, K., Cunningham, W.H., Tang, L.: Optimal 3-terminal cuts and linear programming. Math. Program. 106(1), 1–23 (2006)
Cunningham, W.H.: Optimal attack and reinforcement of a network. J. ACM 32(3), 549–561 (1985)
Dahlhaus, E., Johnson, D.S., Papadimitriou, C.H., Seymour, P.D., Yannakakis, M.: The complexity of multiterminal cuts. SIAM J. Comput. 23, 864–894 (1994)
Ford, L.R., Fulkerson, D.R.: Flows in Networks. Princeton University Press, Princeton (1962)
Fulkerson, D.R., Harding, G.C.: Maximizing the minimum source-sink path subject to a budget constraint. Math. Program. 13, 116–118 (1977)
Garg, N., Vazirani, V.V., Yannakakis, M.: Approximate max-flow min-(multi)cut theorems and their applications. SIAM J. Comput. 25(2), 235–251 (1996)
Garg, N., Vazirani, V.V., Yannakakis, M.: Primal-dual approximation algorithms for integral flow and multicut in trees. Algorithmica 18(1), 3–20 (1997)
Garg, N., Vazirani, V.V., Yannakakis, M.: Multiway cuts in node weighted graphs. J. Algorithms 50(1), 49–61 (2004)
Gaur, D., Ibaraki, T., Krishnamurti, R.: Constant ratio approximation algorithms for the rectangle stabbing problem and the rectilinear partioning problem. J. Algorithms 43, 138–152 (2002)
Goldberg, A., Tarjan, R.: Finding minimum-cost circulations by successive approximation. Math. Oper. Res. 15, 430–466 (1990)
Golovin, D., Nagarajan, V., Singh, M.: Approximation the k-multicut problem. In: Proceedings of the 17th Annual ACM-SIAM Symposium on Discrete Algorithms (SODA), pp. 621–630 (2006)
Israeli, E., Wood, R.K.: Shortest path network interdiction. Networks 40(2), 97–111 (2002)
Karger, D.R., Klein, P.N., Stein, C., Thorup, M., Young, N.E.: Rounding algorithms for a geometric embedding of minimum multiway cut. Math. Oper. Res. 29(3), 436–461 (2004)
Krumke, S., Noltemeier, H., Ravi, R., Schwarz, S., Wirth, H.-C.: Flow improvement and flows with fixed costs. In: Proceedings of the International Conference on Operations Research (OR), pp. 158–167 (1998)
Levin, A., Segev, D.: Partial multicuts in trees. In: Proceedings of the 3rd International Workshop on Approximation and Online Algorithms (WAOA), pp. 320–333 (2005)
Schwarz, S., Krumke, S.O.: On budget-constrained flow improvement. Inf. Process. Lett. 66(3), 291–297 (1998)
Nishihara, O., Inoue, K.: An algorithm for a multiple disconnecting set problem. Unpublished manuscript, Department of Aeronautical Engineering, Kyoto University (1988)
Nishihara, O., Kumamoto, H., Inoue, K.: An algorithm for a multiple cut problem and its application. In: 13th International Symposium on Mathematical Programming (1988)
Phillips, C.A., Swiler, L.P.: A graph-based system for network-vulnerability analysis. In: Proceedings of the DARPA Information Survivability Conference and Exposition, pp. 71–79 (2000)
Phillips, C.A.: The network inhibition problem. In: Proceedings of the 25th Annual ACM Symposium on Theory of Computing (STOC), pp. 776–785 (1993)
Wagner, D.K.: Disjoint (s,t)-cuts in a network. Networks 20, 361–371 (1990)
Wagner, D.K., Wan, H.: A polynomial-time simplex method for the maximum k-flow problem. Math. Program. 30, 115–123 (1993)
Wood, R.K.: Deterministic network interdiction. Math. Comput. Model. 17(2), 1–18 (1993)
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Dean, B.C., Griffis, A., Parekh, O. et al. Approximation Algorithms for k-hurdle Problems. Algorithmica 59, 81–93 (2011). https://doi.org/10.1007/s00453-010-9408-y
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DOI: https://doi.org/10.1007/s00453-010-9408-y