Quasi-Polynomial Algorithms for Submodular Tree Orienteering and Other Directed Network Design Problems
Abstract
We consider the following general network design problem on directed graphs. The input is an asymmetric metric , root , monotone submodular function and budget . The goal is to find an -rooted arborescence of cost at most that maximizes . Our main result is a simple quasi-polynomial time -approximation algorithm for this problem, where is the number of vertices in an optimal solution. To the best of our knowledge, this is the first non-trivial approximation ratio for this problem. As a consequence we obtain an -approximation algorithm for directed (polymatroid) Steiner tree in quasi-polynomial time. We also extend our main result to a setting with additional length bounds at vertices, which leads to improved -approximation algorithms for the single-source buy-at-bulk and priority Steiner tree problems. For the usual directed Steiner tree problem, our result matches the best previous approximation ratio [GLL19]. Our algorithm has the advantage of being deterministic and faster: the runtime is . For polymatroid Steiner tree and single-source buy-at-bulk, our result improves prior approximation ratios by a logarithmic factor. For directed priority Steiner tree, our result seems to be the first non-trivial approximation ratio. All our approximation ratios are tight (up to constant factors) for quasi-polynomial algorithms.
Cite
@article{arxiv.1812.01768,
title = {Quasi-Polynomial Algorithms for Submodular Tree Orienteering and Other Directed Network Design Problems},
author = {Rohan Ghuge and Viswanath Nagarajan},
journal= {arXiv preprint arXiv:1812.01768},
year = {2019}
}