@online{Galby2208.06015,
TITLE = {Subexponential Parameterized Directed Steiner Network Problems on Planar Graphs: A Complete Classification},
AUTHOR = {Galby, Esther and Kisfaludi-Bak, S{\'a}ndor and Marx, D{\'a}niel and Sharma, Roohani},
LANGUAGE = {eng},
URL = {https://arxiv.org/abs/2208.06015},
EPRINT = {2208.06015},
EPRINTTYPE = {arXiv},
YEAR = {2022},
ABSTRACT = {In the Directed Steiner Network problem, the input is a directed graph G, a<br>subset T of k vertices of G called the terminals, and a demand graph D on T.<br>The task is to find a subgraph H of G with the minimum number of edges such<br>that for every edge (s,t) in D, the solution H contains a directed s to t path.<br>In this paper we investigate how the complexity of the problem depends on the<br>demand pattern when G is planar. Formally, if \mathcal{D} is a class of<br>directed graphs closed under identification of vertices, then the<br>\mathcal{D}-Steiner Network (\mathcal{D}-SN) problem is the special case where<br>the demand graph D is restricted to be from \mathcal{D}. For general graphs,<br>Feldmann and Marx [ICALP 2016] characterized those families of demand graphs<br>where the problem is fixed-parameter tractable (FPT) parameterized by the<br>number k of terminals. They showed that if \mathcal{D} is a superset of one of<br>the five hard families, then \mathcal{D}-SN is W[1]-hard parameterized by k,<br>otherwise it can be solved in time f(k)n^{O(1)}.<br> For planar graphs an interesting question is whether the W[1]-hard cases can<br>be solved by subexponential parameterized algorithms. Chitnis et al. [SICOMP<br>2020] showed that, assuming the ETH, there is no f(k)n^{o(k)} time algorithm<br>for the general \mathcal{D}-SN problem on planar graphs, but the special case<br>called Strongly Connected Steiner Subgraph can be solved in time f(k)<br>n^{O(\sqrt{k})} on planar graphs. We present a far-reaching generalization and<br>unification of these two results: we give a complete characterization of the<br>behavior of every $\mathcal{D}$-SN problem on planar graphs. We show that<br>assuming ETH, either the problem is (1) solvable in time 2^{O(k)}n^{O(1)}, and<br>not in time 2^{o(k)}n^{O(1)}, or (2) solvable in time f(k)n^{O(\sqrt{k})}, but<br>not in time f(k)n^{o(\sqrt{k})}, or (3) solvable in time f(k)n^{O(k)}, but not<br>in time f(k)n^{o({k})}.<br>},
}