English

On Routing Disjoint Paths in Bounded Treewidth Graphs

Data Structures and Algorithms 2015-12-08 v1

Abstract

We study the problem of routing on disjoint paths in bounded treewidth graphs with both edge and node capacities. The input consists of a capacitated graph GG and a collection of kk source-destination pairs M={(s1,t1),,(sk,tk)}\mathcal{M} = \{(s_1, t_1), \dots, (s_k, t_k)\}. The goal is to maximize the number of pairs that can be routed subject to the capacities in the graph. A routing of a subset M\mathcal{M}' of the pairs is a collection P\mathcal{P} of paths such that, for each pair (si,ti)M(s_i, t_i) \in \mathcal{M}', there is a path in P\mathcal{P} connecting sis_i to tit_i. In the Maximum Edge Disjoint Paths (MaxEDP) problem, the graph GG has capacities cap(e)\mathrm{cap}(e) on the edges and a routing P\mathcal{P} is feasible if each edge ee is in at most cap(e)\mathrm{cap}(e) of the paths of P\mathcal{P}. The Maximum Node Disjoint Paths (MaxNDP) problem is the node-capacitated counterpart of MaxEDP. In this paper we obtain an O(r3)O(r^3) approximation for MaxEDP on graphs of treewidth at most rr and a matching approximation for MaxNDP on graphs of pathwidth at most rr. Our results build on and significantly improve the work by Chekuri et al. [ICALP 2013] who obtained an O(r3r)O(r \cdot 3^r) approximation for MaxEDP.

Keywords

Cite

@article{arxiv.1512.01829,
  title  = {On Routing Disjoint Paths in Bounded Treewidth Graphs},
  author = {Alina Ene and Matthias Mnich and Marcin Pilipczuk and Andrej Risteski},
  journal= {arXiv preprint arXiv:1512.01829},
  year   = {2015}
}
R2 v1 2026-06-22T12:02:38.851Z