Maximizing Phylogenetic Diversity under Ecological Constraints: A Parameterized Complexity Study
Abstract
In the NP-hard Optimizing PD with Dependencies (PDD) problem, the input consists of a phylogenetic tree over a set of taxa , a food-web that describes the prey-predator relationships in , and integers and . The task is to find a set of species that is viable in the food-web such that the subtree of obtained by retaining only the vertices of has total edge weight at least . Herein, viable means that for every predator taxon of , the set contains at least one prey taxon. We provide the first systematic analysis of PDD and its special case s-PDD from a parameterized complexity perspective. For solution-size related parameters, we show that PDD is FPT with respect to and with respect to plus the height of the phylogenetic tree. Moreover, we consider structural parameterizations of the food-web. For example, we show an FPT-algorithm for the parameter that measures the vertex deletion distance to graphs where every connected component is a complete graph. Finally, we show that s-PDD admits an FPT-algorithm for the treewidth of the food-web. This disproves a conjecture of Faller et al. [Annals of Combinatorics, 2011] who conjectured that s-PDD is NP-hard even when the food-web is a tree.
Cite
@article{arxiv.2405.17314,
title = {Maximizing Phylogenetic Diversity under Ecological Constraints: A Parameterized Complexity Study},
author = {Christian Komusiewicz and Jannik Schestag},
journal= {arXiv preprint arXiv:2405.17314},
year = {2024}
}