The paper presents novel techniques to obtain double-exponential lower bounds in the treewidth (tw) or vertex cover number (vc) for three natural and well-studied NP-complete graph problems: Metric Dimension, Strong Metric Dimension, and Geodetic Set. These are the first problems in NP known to admit such lower bounds.
The key insights are:
The authors develop a reduction from the 3-Partitioned-3-SAT problem, which is known to require double-exponential time under the Exponential Time Hypothesis (ETH). The reduction encodes the relationships between clause and literal vertices using "small" separators, rather than the typical incidence graph representation.
For Metric Dimension and Geodetic Set, the authors prove that these problems do not admit algorithms running in time 2^(f(diam)^o(tw)) * n^O(1), for any computable function f, unless the ETH fails. This implies that these problems on graphs of bounded diameter cannot admit 2^(2^o(tw)) * n^O(1)-time algorithms, unless the ETH fails.
For Strong Metric Dimension, the authors show that the problem does not admit an algorithm running in time 2^(2^o(vc)) * n^O(1), unless the ETH fails. This also implies that Strong Metric Dimension does not admit a kernelization algorithm that outputs an instance with 2^o(vc) vertices, unless the ETH fails.
The authors complement their lower bounds with matching (and sometimes non-trivial) upper bounds, demonstrating the tightness of their results.
The authors believe that their novel technique based on Sperner families of sets will lead to obtaining similar double-exponential lower bounds for many other problems in NP.
Till ett annat språk
från källinnehåll
arxiv.org
Djupare frågor