Improved Approximations for Ultrametric Violation Distance

We study the Ultrametric Violation Distance problem introduced by Cohen-Addad, Fan, Lee, and Mesmay [FOCS, 2022]. Given pairwise distances $x\in \mathbb{R}{>0}^{{\binom{[n]}{2}}$} as input, the goal is to modify the minimum number of distances so as to make it a valid ultrametric. In other words, this is the problem of fitting an ultrametric to given data, where the quality of the fit is measured by the $\ell0$ norm of the error; variants of the problem for the $\ell\infty$ and $\ell1$ norms are well-studied in the literature. Our main result is a 5-approximation algorithm for Ultrametric Violation Distance, improving the previous best large constant factor ($\geq 1000$) approximation algorithm. We give an $O(\min{L,\log n})$-approximation for weighted Ultrametric Violation Distance where the weights satisfy triangle inequality and $L$ is the number of distinct values in the input. We also give a $16$-approximation for the problem on $k$-partite graphs, where the input is specified on pairs of vertices that form a complete $k$-partite graph. All our results use a unified algorithmic framework with small modifications for the three cases.