A logarithmic approximation algorithm for the activation edge multicover problem

Abstract

In the Activation Edge-Multicover problem we are given a multigraph G=(V,E) with activation costs \ceu,cev\ for every edge e=uv ∈ E, and degree requirements r=\rv:v ∈ V\. The goal is to find an edge subset J ⊂eq E of minimum activation cost Σv ∈ V\cuvv:uv ∈ J\,such that every v ∈ V has at least rv neighbors in the graph (V,J). Let k= v ∈ V rv be the maximum requirement and let θ=e=uv ∈ E \ceu,cev\\ceu,cev\ be the maximum quotient between the two costs of an edge. For θ=1 the problem admits approximation ratio O( k). For k=1 it generalizes the Set Cover problem (when θ=∞), and admits a tight approximation ratio O( n). This implies approximation ratio O(k n) for general k and θ, and no better approximation ratio was known. We obtain the first logarithmic approximation ratio O( k +\θ,n\), that bridges between the two known ratios -- O( k) for θ=1 and O( n) for k=1. This implies approximation ratio O( k +\θ,n\) +β · (θ+1) for the Activation k-Connected Subgraph problem, where β is the best known approximation ratio for the ordinary min-cost version of the problem.