Fixed-parameter tractability and hardness for Steiner rooted and locally connected orientations

Abstract

Finding a Steiner strongly k-arc-connected orientation is particularly relevant in network design and reliability, as it guarantees robust communication between a designated set of critical nodes. Kir\'aly and Lau (FOCS 2006) introduced a rooted variant, called the Steiner Rooted Orientation problem, where one is given an undirected graph on n vertices, a root vertex, and a set of t terminals. The goal is to find an orientation of the graph such that the resulting directed graph is Steiner rooted k-arc-connected. This problem generalizes several classical connectivity results in graph theory, such as those on edge-disjoint paths and spanning-tree packings. While the maximum k for which a Steiner strongly k-arc-connected orientation exists can be determined in polynomial time via Nash-Williams' orientation theorem, its rooted counterpart is significantly harder: the problem is NP-hard when both k and t are part of the input. In this work, we provide a complete understanding of the problem with respect to these two parameters. In particular, we give an algorithm that solves the problem in time f(k,t)· nO(1), establishing fixed-parameter tractability with respect to the number of terminals t and the target connectivity k. We further show that the problem remains NP-hard if either k or t is treated as part of the input, meaning that our algorithm is essentially optimal from a parameterized perspective. Importantly, our results extend far beyond the Steiner setting: the same framework applies to the more general orientation problem with local connectivity requirements, establishing fixed-parameter tractability when parameterized by the total demand and thereby covering a wide range of arc-connectivity orientation problems.

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