Cluster Before You Hallucinate: Approximating Node-Capacitated Network Design and Energy Efficient Routing

Abstract

We consider the following node-capacitated network design problem. The input is an undirected graph, set of demands, uniform node capacity and arbitrary node costs. The goal is to find a minimum node-cost subgraph that supports all demands concurrently subject to the node capacities. We consider both single and multi-commodity demands, and provide the first poly-logarithmic approximation guarantees. For single-commodity demands (i.e., all request pairs have the same sink node), we obtain an O(2 n) approximation to the cost with an O(3 n) factor violation in node capacities. For multi-commodity demands, we obtain an O(4 n) approximation to the cost with an O(10 n) factor violation in node capacities. We use a variety of techniques, including single-sink confluent flows, low-load set cover, random sampling and cut-sparsification. We also develop new techniques for clustering multicommodity demands into (nearly) node-disjoint clusters, which may be of independent interest. Moreover, this network design problem has applications to energy-efficient virtual circuit routing. In this setting, there is a network of routers that are speed scalable, and that may be shutdown when idle. We assume the standard model for power: the power consumed by a router with load (speed) s is σ + sα where σ is the static power and the exponent α > 1. We obtain the first poly-logarithmic approximation algorithms for this problem when speed-scaling occurs on nodes of a network.