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Algorithms for covering multiple submodular constraints and applications

Author

Listed:
  • Chandra Chekuri

    (University of Illinois)

  • Tanmay Inamdar

    (University of Bergen)

  • Kent Quanrud

    (Purdue University)

  • Kasturi Varadarajan

    (University of Iowa)

  • Zhao Zhang

    (Zhejiang Normal University)

Abstract

We consider the problem of covering multiple submodular constraints. Given a finite ground set N, a weight function $$w: N \rightarrow \mathbb {R}_+$$ w : N → R + , r monotone submodular functions $$f_1,f_2,\ldots ,f_r$$ f 1 , f 2 , … , f r over N and requirements $$k_1,k_2,\ldots ,k_r$$ k 1 , k 2 , … , k r the goal is to find a minimum weight subset $$S \subseteq N$$ S ⊆ N such that $$f_i(S) \ge k_i$$ f i ( S ) ≥ k i for $$1 \le i \le r$$ 1 ≤ i ≤ r . We refer to this problem as Multi-Submod-Cover and it was recently considered by Har-Peled and Jones (Few cuts meet many point sets. CoRR. arxiv:abs1808.03260 Har-Peled and Jones 2018) who were motivated by an application in geometry. Even with $$r=1$$ r = 1 Multi-Submod-Cover generalizes the well-known Submodular Set Cover problem (Submod-SC), and it can also be easily reduced to Submod-SC. A simple greedy algorithm gives an $$O(\log (kr))$$ O ( log ( k r ) ) approximation where $$k = \sum _i k_i$$ k = ∑ i k i and this ratio cannot be improved in the general case. In this paper, motivated by several concrete applications, we consider two ways to improve upon the approximation given by the greedy algorithm. First, we give a bicriteria approximation algorithm for Multi-Submod-Cover that covers each constraint to within a factor of $$(1-1/e-\varepsilon )$$ ( 1 - 1 / e - ε ) while incurring an approximation of $$O(\frac{1}{\epsilon }\log r)$$ O ( 1 ϵ log r ) in the cost. Second, we consider the special case when each $$f_i$$ f i is a obtained from a truncated coverage function and obtain an algorithm that generalizes previous work on partial set cover (Partial-SC), covering integer programs (CIPs) and multiple vertex cover constraints Bera et al. (Theoret Comput Sci 555:2–8 Bera et al. 2014). Both these algorithms are based on mathematical programming relaxations that avoid the limitations of the greedy algorithm. We demonstrate the implications of our algorithms and related ideas to several applications ranging from geometric covering problems to clustering with outliers. Our work highlights the utility of the high-level model and the lens of submodularity in addressing this class of covering problems.

Suggested Citation

  • Chandra Chekuri & Tanmay Inamdar & Kent Quanrud & Kasturi Varadarajan & Zhao Zhang, 2022. "Algorithms for covering multiple submodular constraints and applications," Journal of Combinatorial Optimization, Springer, vol. 44(2), pages 979-1010, September.
    • Handle: RePEc:spr:jcomop:v:44:y:2022:i:2:d:10.1007_s10878-022-00874-x
    DOI: 10.1007/s10878-022-00874-x
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    References listed on IDEAS

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    1. Fisher, M.L. & Nemhauser, G.L. & Wolsey, L.A., 1978. "An analysis of approximations for maximizing submodular set functions," LIDAM Reprints CORE 341, Université catholique de Louvain, Center for Operations Research and Econometrics (CORE).
    2. Fisher, M.L. & Nemhauser, G.L. & Wolsey, L.A., 1978. "An analysis of approximations for maximizing submodular set functions - 1," LIDAM Reprints CORE 334, Université catholique de Louvain, Center for Operations Research and Econometrics (CORE).
    3. A.A. Ageev & M.I. Sviridenko, 2004. "Pipage Rounding: A New Method of Constructing Algorithms with Proven Performance Guarantee," Journal of Combinatorial Optimization, Springer, vol. 8(3), pages 307-328, September.
    4. Gregory Dobson, 1982. "Worst-Case Analysis of Greedy Heuristics for Integer Programming with Nonnegative Data," Mathematics of Operations Research, INFORMS, vol. 7(4), pages 515-531, November.
    5. Wolsey, L.A., 1982. "An analysis of the greedy algorithm for the submodular set covering problem," LIDAM Reprints CORE 519, Université catholique de Louvain, Center for Operations Research and Econometrics (CORE).
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