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The Directed Disjoint Shortest Paths Problem

Authors Kristof Berczi, Yusuke Kobayashi



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LIPIcs.ESA.2017.13.pdf
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Kristof Berczi
Yusuke Kobayashi

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Kristof Berczi and Yusuke Kobayashi. The Directed Disjoint Shortest Paths Problem. In 25th Annual European Symposium on Algorithms (ESA 2017). Leibniz International Proceedings in Informatics (LIPIcs), Volume 87, pp. 13:1-13:13, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2017) https://doi.org/10.4230/LIPIcs.ESA.2017.13

Abstract

In the k disjoint shortest paths problem (k-DSPP), we are given a graph and its vertex pairs (s_1, t_1), ... , (s_k, t_k), and the objective is to find k pairwise disjoint paths P_1, ... , P_k such that each path P_i is a shortest path from s_i to t_i, if they exist. If the length of each edge is equal to zero, then this problem amounts to the disjoint paths problem, which is one of the well-studied problems in algorithmic graph theory and combinatorial optimization. Eilam-Tzoreff (1998) focused on the case when the length of each edge is positive, and showed that the undirected version of 2-DSPP can be solved in polynomial time. Polynomial solvability of the directed version was posed as an open problem by Eilam-Tzoreff (1998). In this paper, we solve this problem affirmatively, that is, we give a first polynomial time algorithm for the directed version of 2-DSPP when the length of each edge is positive. Note that the 2 disjoint paths problem in digraphs is NP-hard, which implies that the directed 2-DSPP is NP-hard if the length of each edge can be zero. We extend our result to the case when the instance has two terminal pairs and the number of paths is a fixed constant greater than two. We also show that the undirected k-DSPP and the vertex-disjoint version of the directed k-DSPP can be solved in polynomial time if the input graph is planar and k is a fixed constant.

Subject Classification

Keywords
  • Disjoint paths
  • shortest path
  • polynomial time algorithm

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References

  1. Andreas Björklund and Thore Husfeldt. Shortest two disjoint paths in polynomial time. In ICALP, pages 211-222, 2014. Google Scholar
  2. Glencora Borradaile, Amir Nayyeri, and Farzad Zafarani. Towards single face shortest vertex-disjoint paths in undirected planar graphs. In ESA, pages 227-238, 2015. Google Scholar
  3. Marek Cygan, Dániel Marx, Marcin Pilipczuk, and Michał Pilipczuk. The planar directed k-vertex-disjoint paths problem is fixed-parameter tractable. In FOCS, pages 197-206, 2013. Google Scholar
  4. Éric Colin de Verdière and Alexander Schrijver. Shortest vertex-disjoint two-face paths in planar graphs. In STACS, pages 181-192, 2008. Google Scholar
  5. Tali Eilam-Tzoreff. The disjoint shortest paths problem. Discrete Applied Mathematics, 85(2):113-138, 1998. Google Scholar
  6. Steven Fortune, John E. Hopcroft, and James Wyllie. The directed subgraph homeomorphism problem. Theoretical Computer Science, 10:111-121, 1980. Google Scholar
  7. András Frank. Paths, Flows, and VLSI-Layout, chapter Packing paths, cuts and circuits - a survey, pages 49-100. Springer-Verlag, 1990. Google Scholar
  8. Hiroshi Hirai and Hiroyuki Namba. Shortest (A+B)-path packing via hafnian. arXiv:1603.08073, 2016. Google Scholar
  9. Richard M. Karp. On the computational complexity of combinatorial problems. Networks, 5:45-68, 1975. Google Scholar
  10. Ken-ichi Kawarabayashi, Yusuke Kobayashi, and Bruce Reed. The disjoint paths problem in quadratic time. Journal of Combinatorial Theory, Series B, 102(2):424-435, 2012. Google Scholar
  11. Yusuke Kobayashi and Christian Sommer. On shortest disjoint paths in planar graphs. Discrete Optimization, 7(4):234-245, 2010. Google Scholar
  12. James F. Lynch. The equivalence of theorem proving and the interconnection problem. SIGDA Newsletter, 5(3):31-36, 1975. Google Scholar
  13. Richard G. Ogier, Vladislav Rutenburg, and Nachum Shacham. Distributed algorithms for computing shortest pairs of disjoint paths. IEEE Transactions on Information Theory, 39(2):443-455, 1993. Google Scholar
  14. Neil Robertson and Paul D. Seymour. Paths, Flows, and VLSI-Layout, chapter An outline of a disjoint paths algorithm, pages 267-292. Springer-Verlag, 1990. Google Scholar
  15. Neil Robertson and Paul D. Seymour. Graph minors. XIII. The disjoint paths problem. Journal of Combinatorial Theory, Series B, 63(1):65-110, 1995. URL: http://dx.doi.org/10.1006/jctb.1995.1006.
  16. Alexander Schrijver. Finding k disjoint paths in a directed planar graph. SIAM Journal on Computing, 23(4):780-788, 1994. Google Scholar
  17. Paul D. Seymour. Disjoint paths in graphs. Discrete Mathematics, 29:293-309, 1980. Google Scholar
  18. Y. Shiloach and Y. Perl. Finding two disjoint paths between two pairs of vertices in a graph. J. ACM, 25(1):1-9, 1978. Google Scholar
  19. Yossi Shiloach. A polynomial solution to the undirected two paths problem. Journal of the ACM, 27(3):445-456, 1980. URL: http://dx.doi.org/10.1145/322203.322207.
  20. Anand Srinivas and Eytan Modiano. Finding minimum energy disjoint paths in wireless ad-hoc networks. Wireless Networks, 11(4):401-417, 2005. URL: http://dx.doi.org/10.1007/s11276-005-1765-0.
  21. Torsten Tholey. Finding disjoint paths on directed acyclic graphs. In WG, pages 319-330, 2005. Google Scholar
  22. Carsten Thomassen. 2-linked graphs. European Journal of Combinatorics, 1:371-378, 1980. Google Scholar
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