Abstract
For a set Q of points in the plane and a real number δ ≥ 0, let Gδ(Q) be the graph defined on Q by connecting each pair of points at distance at most δ.We consider the connectivity of Gδ(Q) in the best scenario when the location of a few of the points is uncertain, but we know for each uncertain point a line segment that contains it. More precisely, we consider the following optimization problem: given a set P of n - k points in the plane and a set S of k line segments in the plane, find the minimum δ ≥ 0 with the property that we can select one point ps ∈ s for each segment s ∈ S and the corresponding graph Gδ(P ∪ {ps∣s ∈ S}) is connected. It is known that the problem is NP-hard. We provide an algorithm to exactly compute an optimal solution in O (f(k)nlogn) time, for a computable function f( · ). This implies that the problem is FPT when parameterized by k. The best previous algorithm uses O ((k!)kkk+1 · n2k) time and computes the solution up to fixed precision.