Covering Tree-Based Phylogenetic Networks

09/25/2020

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Tree-based phylogenetic networks, which may be roughly defined as leaf-labeled networks built by adding arcs only between the original tree edges, have elegant properties for modeling evolutionary histories. We answer an open question of Francis, Semple, and Steel about the complexity of determining how far a phylogenetic network is from being tree-based, including non-binary phylogenetic networks. We show that finding a phylogenetic tree covering the maximum number of nodes in a phylogenetic network can be be computed in polynomial time via an encoding into a minimum-cost maximum flow problem.

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Covering Tree-Based Phylogenetic Networks

Rooted Almost-binary Phylogenetic Networks for which the Maximum Covering Subtree Problem is Solvable in Linear Time

Drawing Tree-Based Phylogenetic Networks with Minimum Number of Crossings

A Cost-Scaling Algorithm for Minimum-Cost Node-Capacitated Multiflow Problem

A QUBO formulation for the Tree Containment problem

Orienting undirected phylogenetic networks to tree-child network

Robust capacitated trees and networks with uniform demands

An algorithm for reconstructing level-2 phylogenetic networks from trinets

Covering Tree-Based Phylogenetic Networks

Related Research

Rooted Almost-binary Phylogenetic Networks for which the Maximum Covering Subtree Problem is Solvable in Linear Time

Drawing Tree-Based Phylogenetic Networks with Minimum Number of Crossings

A Cost-Scaling Algorithm for Minimum-Cost Node-Capacitated Multiflow Problem

A QUBO formulation for the Tree Containment problem

Orienting undirected phylogenetic networks to tree-child network

Robust capacitated trees and networks with uniform demands

An algorithm for reconstructing level-2 phylogenetic networks from trinets