Abstract (EN)

We consider a natural generalization of the classical minimum hitting set problem, the minimum hitting set of bundles problem (mhsb) which is defined as follows. We are given a set TeX of n elements. Each element e i (i = 1, ...,n) has a non negative cost c i . A bundle b is a subset of TeX . We are also given a collection TeX of m sets of bundles. More precisely, each set S j (j = 1, ..., m) is composed of g(j) distinct bundles TeX . A solution to mhsb is a subset TeX such that for every TeX at least one bundle is covered, i.e. TeX for some l ∈ {1,2, ⋯ ,g(j)}. The total cost of the solution, denoted by TeX , is TeX . The goal is to find a solution with minimum total cost. We give a deterministic TeX -approximation algorithm, where N is the maximum number of bundles per set and M is the maximum number of sets an element can appear in. This is roughly speaking the best approximation ratio that we can obtain since, by reducing mhsb to the vertex cover problem, it implies that mhsb cannot be approximated within 1.36 when N = 2 and N − 1 − ε when N ≥ 3. It has to be noticed that the application of our algorithm in the case of the min k −sat problem matches the best known approximation ratio.