Fitting Distances by Tree Metrics Minimizing the Total Error within a Constant Factor
Abstract
We consider the numerical taxonomy problem of fitting a positive distance function by a tree metric. We want a tree with positive edge weights and including among the vertices so that their distances in match those in . A nice application is in evolutionary biology where the tree aims to approximate the branching process leading to the observed distances in [Cavalli-Sforza and Edwards 1967]. We consider the total error, that is the sum of distance errors over all pairs of points. We present a deterministic polynomial time algorithm minimizing the total error within a constant factor. We can do this both for general trees, and for the special case of ultrametrics with a root having the same distance to all vertices in . The problems are APX-hard, so a constant factor is the best we can hope for in polynomial time. The best previous approximation factor was by Ailon and Charikar [2005] who wrote "Determining whether an approximation can be obtained is a fascinating question".
Cite
@article{arxiv.2110.02807,
title = {Fitting Distances by Tree Metrics Minimizing the Total Error within a Constant Factor},
author = {Vincent Cohen-Addad and Debarati Das and Evangelos Kipouridis and Nikos Parotsidis and Mikkel Thorup},
journal= {arXiv preprint arXiv:2110.02807},
year = {2022}
}
Comments
46 pages, Accepted to FOCS 2021 (Full version)