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The Complexity of Temporal Vertex Cover in Small-Degree Graphs (2204.04832v2)

Published 11 Apr 2022 in cs.DS and cs.DM

Abstract: Temporal graphs naturally model graphs whose underlying topology changes over time. Recently, the problems TEMPORAL VERTEX COVER (or TVC) and SLIDING-WINDOW TEMPORAL VERTEX COVER(or $\Delta$-TVC for time-windows of a fixed-length $\Delta$) have been established as natural extensions of the classic problem VERTEX COVER on static graphs with connections to areas such as surveillance in sensor networks. In this paper we initiate a systematic study of the complexity of TVC and $\Delta$-TVC on sparse graphs. Our main result shows that for every $\Delta\geq 2$, $\Delta$-TVC is NP-hard even when the underlying topology is described by a path or a cycle. This resolves an open problem from literature and shows a surprising contrast between $\Delta$-TVC and TVC for which we provide a polynomial-time algorithm in the same setting. To circumvent this hardness, we present a number of exact and approximation algorithms for temporal graphs whose underlying topologies are given by a path, that have bounded vertex degree in every time step, or that admit a small-sized temporal vertex cover.

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References (42)
  1. DMVP: foremost waypoint coverage of time-varying graphs. In Proceedings of the 40th International Workshop on Graph-Theoretic Concepts in Computer Science (WG), pages 29–41, 2014.
  2. Ephemeral networks with random availability of links: The case of fast networks. Journal of Parallel and Distributed Computing, 87:109–120, 2016.
  3. The complexity of optimal design of temporally connected graphs. Theory of Computing Systems, 61(3):907–944, 2017.
  4. Temporal vertex cover with a sliding time window. Journal of Computer and System Sciences, 107:108–123, 2020.
  5. Listing all maximal k𝑘kitalic_k-plexes in temporal graphs. In Proceedings of the 2018 IEEE/ACM International Conference on Advances in Social Networks Analysis and Mining (ASONAM), pages 41–46, 2018.
  6. Computing shortest, fastest, and foremost journeys in dynamic networks. International Journal of Foundations of Computer Science, 14(2):267–285, 2003.
  7. A. Casteigts and P. Flocchini. Deterministic algorithms in dynamic networks: Formal models and metrics. Technical report, Defence R&D Canada, 2013.
  8. A. Casteigts and P. Flocchini. Deterministic algorithms in dynamic networks: Problems, analysis, and algorithmic tools. Technical report, Defence R&D Canada, 2013.
  9. Time-varying graphs and dynamic networks. International Journal of Parallel, Emergent and Distributed Systems, 27(5):387–408, 2012.
  10. Finding temporal paths under waiting time constraints. Algorithmica, 83(9):2754–2802, 2021.
  11. Cluster editing in multi-layer and temporal graphs. In W. Hsu, D. Lee, and C. Liao, editors, Proceedings of the 29th International Symposium on Algorithms and Computation (ISAAC), volume 123, pages 24:1–24:13, 2018.
  12. Flooding time of edge-markovian evolving graphs. SIAM Journal on Discrete Mathematics, 24(4):1694–1712, 2010.
  13. Parameterized Algorithms. Springer, 2015.
  14. M. de Berg and A. Khosravi. Optimal binary space partitions in the plane. In Computing and combinatorics, volume 6196 of Lecture Notes in Computer Science, pages 216–225. Springer, Berlin, 2010.
  15. Fundamentals of Parameterized Complexity. Texts in Computer Science. Springer, London, 2013.
  16. Deleting edges to restrict the size of an epidemic in temporal networks. Journal of Computer and System Sciences, 119:60–77, 2021.
  17. On temporal graph exploration. Journal of Computer and System Sciences, 119:1–18, 2021.
  18. A. Ferreira. Building a reference combinatorial model for MANETs. IEEE Network, 18(5):24–29, 2004.
  19. Exploration of periodically varying graphs. In Proceedings of the 20th International Symposium on Algorithms and Computation (ISAAC), pages 534–543, 2009.
  20. S. Ghosal and S. C. Ghosh. Channel assignment in mobile networks based on geometric prediction and random coloring. In Proceedings of the 40th IEEE Conference on Local Computer Networks (LCN), pages 237–240, 2015.
  21. Randomized rumor spreading in dynamic graphs. In Proceedings of the 41st International Colloquium on Automata, Languages and Programming (ICALP), pages 495–507, 2014.
  22. P. Hall. On representatives of subsets. Journal of the London Mathematical Society, s1-10(1):26–30, 1935.
  23. Equitable scheduling on a single machine. In Proceedings of the 35th AAAI Conference on Artificial Intelligence (AAAI), pages 11818–11825. AAAI Press, 2021.
  24. Adapting the bron-kerbosch algorithm for enumerating maximal cliques in temporal graphs. Social Network Analysis and Mining, 7(1):35:1–35:16, 2017.
  25. P. Holme and J. Saramäki, editors. Temporal networks. Springer, 2013.
  26. On vertex cover problems in distributed systems. In Advanced Methods for Complex Network Analysis, pages 1–29. IGI Global, 2016.
  27. Distributed vertex cover algorithms for wireless sensor networks. International Journal of Computer Networks & Communications, 6(1):95–110, 2014.
  28. Connectivity and inference problems for temporal networks. Journal of Computer and System Sciences, 64(4):820–842, 2002.
  29. Interference-free walks in time: Temporally disjoint paths. In Z. Zhou, editor, Proceedings of the 30th International Joint Conference on Artificial Intelligence (IJCAI), pages 4090–4096, 2021.
  30. Graph evolution: Densification and shrinking diameters. ACM Transactions on Knowledge Discovery from Data, 1(1), 2007.
  31. Temporal network optimization subject to connectivity constraints. Algorithmica, 81(4):1416–1449, 2019.
  32. The complexity of transitively orienting temporal graphs. In Proceedings of the 46th International Symposium on Mathematical Foundations of Computer Science (MFCS), pages 75:1–75:18, 2021.
  33. Sliding window temporal graph coloring. Journal of Computer and System Sciences, 120:97–115, 2021.
  34. O. Michail and P. G. Spirakis. Traveling salesman problems in temporal graphs. Theoretical Computer Science, 634:1–23, 2016.
  35. O. Michail and P. G. Spirakis. Elements of the theory of dynamic networks. Communications of the ACM, 61(2):72–72, 2018.
  36. N. H. Mustafa and S. Ray. Improved results on geometric hitting set problems. Discrete and Computational Geometry, 44(4):883–895, 2010.
  37. R. Niedermeier. Invitation to Fixed-Parameter Algorithms. Oxford Lecture Series in Mathematics and its Applications. Oxford University Press, Oxford, 2006.
  38. A stochastic local search approach to vertex cover. In Proceedings of the 30th Annual German Conference on Artificial Intelligence (KI), pages 412–426, 2007.
  39. Characterising temporal distance and reachability in mobile and online social networks. Computer Communication Review, 40(1):118–124, 2010.
  40. Computing maximal cliques in link streams. Theoretical Computer Science, 609:245–252, 2016.
  41. Algorithms for channel assignment in mobile wireless networks using temporal coloring. In Proceedings of the 16th ACM international conference on Modeling, analysis & simulation of wireless and mobile systems (MSWiM), pages 49–58, 2013.
  42. The complexity of finding small separators in temporal graphs. Journal of Computer and System Sciences, 107:72–92, 2020.
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