Improved Approximation for Node-Disjoint Paths in Grids with Sources on the Boundary

Abstract

We study the classical Node-Disjoint Paths (NDP) problem: given an undirected n-vertex graph G, together with a set (s1,t1),...,(sk,tk) of pairs of its vertices, called source-destination, or demand pairs, find a maximum-cardinality set of mutually node-disjoint paths that connect the demand pairs. The best current approximation for the problem is achieved by a simple greedy O(n)-approximation algorithm. A special case of the problem called NDP-Grid, where the underlying graph is a grid, has been studied extensively. The best current approximation algorithm for NDP-Grid achieves an O(n1/4)-approximation factor. On the negative side, a recent result by the authors shows that NDP is hard to approximate to within factor 2( n), even if the underlying graph is a sub-graph of a grid, and all source vertices lie on the grid boundary. In a follow-up work, the authors further show that NDP-Grid is hard to approximate to within factor (2^1-εn) for any constant ε under standard complexity assumptions, and to within factor n(1/( n)2) under randomized ETH. In this paper we study NDP-Grid, where all source vertices s1,...,sk appear on the grid boundary. Our main result is an efficient randomized 2O( n · n)-approximation algorithm for this problem. We generalize this result to instances where the source vertices lie within a prescribed distance from the grid boundary. Much of the work on approximation algorithms for NDP relies on the multicommodity flow relaxation of the problem, which is known to have an ( n) integrality gap, even in grid graphs. Our work departs from this paradigm, and uses a (completely different) linear program only to select the pairs to be routed, while the routing itself is computed by other methods.