Tight Guarantees for Cut-Relative Survivable Network Design via a Decomposition Technique

Abstract

In the classical survivable-network-design problem (SNDP), we are given an undirected graph G = (V, E), non-negative edge costs, and some (si,ti,ri) tuples, where si,ti∈ V and ri∈Z+. We seek a minimum-cost subset H ⊂eq E such that each si-ti pair remains connected even if any ri-1 edges fail. It is well-known that SNDP can be equivalently modeled using a weakly-supermodular cut-requirement function f, where we seek a minimum-cost edge-set containing at least f(S) edges across every cut S ⊂eq V. Recently, Dinitz et al. proposed a variant of SNDP that enforces a relative level of fault tolerance with respect to G, where the goal is to find a solution H that is at least as fault-tolerant as G itself. They formalize this in terms of paths and fault-sets, which gives rise to path-relative SNDP. Along these lines, we introduce a new model of relative network design, called cut-relative SNDP (CR-SNDP), where the goal is to select a minimum-cost subset of edges that satisfies the given (weakly-supermodular) cut-requirement function to the maximum extent possible, i.e., by picking \f(S),|δG(S)|\ edges across every cut S⊂eq V. Unlike SNDP, the cut-relative and path-relative versions of SNDP are not equivalent. The resulting cut-requirement function for CR-SNDP (as also path-relative SNDP) is not weakly supermodular, and extreme-point solutions to the natural LP-relaxation need not correspond to a laminar family of tight cut constraints. Consequently, standard techniques cannot be used directly to design approximation algorithms for this problem. We develop a novel decomposition technique to circumvent this difficulty and use it to give a tight 2-approximation algorithm for CR-SNDP. We also show new hardness results for these relative-SNDP problems.