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Bannach, Max [Author]; Skambath, Malte [Author]; Tantau, Till [Author] ; Max Bannach and Malte Skambath and Till Tantau [Contributor]

Kernelizing the Hitting Set Problem in Linear Sequential and Constant Parallel Time

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  • Media type: Text; E-Article; Electronic Conference Proceeding
  • Title: Kernelizing the Hitting Set Problem in Linear Sequential and Constant Parallel Time
  • Contributor: Bannach, Max [Author]; Skambath, Malte [Author]; Tantau, Till [Author]
  • Published: Schloss Dagstuhl – Leibniz-Zentrum für Informatik, 2020
  • Language: English
  • DOI: https://doi.org/10.4230/LIPIcs.SWAT.2020.9
  • Keywords: Constant-Depth Circuits ; Approximation ; Kernelization ; Hitting Set
  • Origination:
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  • Description: We analyze a reduction rule for computing kernels for the hitting set problem: In a hypergraph, the link of a set c of vertices consists of all edges that are supersets of c. We call such a set critical if its link has certain easy-to-check size properties. The rule states that the link of a critical c can be replaced by c. It is known that a simple linear-time algorithm for computing hitting set kernels (number of edges) at most k^d (k is the hitting set size, d is the maximum edge size) can be derived from this rule. We parallelize this algorithm and obtain the first AC⁰ kernel algorithm that outputs polynomial-size kernels. Previously, such algorithms were not even known for artificial problems. An interesting application of our methods lies in traditional, non-parameterized approximation theory: Our results imply that uniform AC⁰-circuits can compute a hitting set whose size is polynomial in the size of an optimal hitting set.
  • Access State: Open Access