Parameterized Approximation for Capacitated d-Hitting Set with Hard Capacities
Abstract
The Capacitated d-Hitting Set problem involves a universe U with a capacity function cap: U → N and a collection A of subsets of U, each of size at most d. The goal is to find a minimum subset S ⊂eq U and an assignment φ : A → S such that for every A ∈ A, φ(A) ∈ A, and for each x ∈ U, |φ-1(x)| ≤ cap(x). For d=2, this is known as Capacitated Vertex Cover. In the weighted variant, each element of U has a positive integer weight, with the objective of finding a minimum-weight capacitated hitting set. Chuzhoy and Naor [SICOMP 2006] provided a factor-3 approximation for Capacitated Vertex Cover and showed that the weighted case lacks an o( n)-approximation unless P=NP. Kao and Wong [SODA 2017] later independently achieved a d-approximation for Capacitated d-Hitting Set, with no d - ε improvements possible under the Unique Games Conjecture. Our main result is a parameterized approximation algorithm with runtime (kε)k 2kO(kd)(|U|+|A|)O(1) that either concludes no solution of size ≤ k exists or finds S of size ≤ 4/3 · k and weight at most 2+ε times the minimum weight for solutions of size ≤ k. We further show that no FPT-approximation with factor c > 1 exists for unweighted Capacitated d-Hitting Set with d ≥ 3, nor with factor 2 - ε for the weighted version, assuming the Exponential Time Hypothesis. These results extend to Capacitated Vertex Cover in multigraphs. Additionally, a variant of multi-dimensional Knapsack is shown hard to FPT-approximate within 2 - ε.
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