English

Semi-Streaming Set Cover

Data Structures and Algorithms 2014-05-09 v2

Abstract

This paper studies the set cover problem under the semi-streaming model. The underlying set system is formalized in terms of a hypergraph G=(V,E)G = (V, E) whose edges arrive one-by-one and the goal is to construct an edge cover FEF \subseteq E with the objective of minimizing the cardinality (or cost in the weighted case) of FF. We consider a parameterized relaxation of this problem, where given some 0ϵ<10 \leq \epsilon < 1, the goal is to construct an edge (1ϵ)(1 - \epsilon)-cover, namely, a subset of edges incident to all but an ϵ\epsilon-fraction of the vertices (or their benefit in the weighted case). The key limitation imposed on the algorithm is that its space is limited to (poly)logarithmically many bits per vertex. Our main result is an asymptotically tight trade-off between ϵ\epsilon and the approximation ratio: We design a semi-streaming algorithm that on input graph GG, constructs a succinct data structure D\mathcal{D} such that for every 0ϵ<10 \leq \epsilon < 1, an edge (1ϵ)(1 - \epsilon)-cover that approximates the optimal edge \mbox{(11-)cover} within a factor of f(ϵ,n)f(\epsilon, n) can be extracted from D\mathcal{D} (efficiently and with no additional space requirements), where f(ϵ,n)={O(1/ϵ),if ϵ>1/nO(n),otherwise. f(\epsilon, n) = \left\{ \begin{array}{ll} O (1 / \epsilon), & \text{if } \epsilon > 1 / \sqrt{n} \\ O (\sqrt{n}), & \text{otherwise} \end{array} \right. \, . In particular for the traditional set cover problem we obtain an O(n)O(\sqrt{n})-approximation. This algorithm is proved to be best possible by establishing a family (parameterized by ϵ\epsilon) of matching lower bounds.

Keywords

Cite

@article{arxiv.1404.6763,
  title  = {Semi-Streaming Set Cover},
  author = {Yuval Emek and Adi Rosen},
  journal= {arXiv preprint arXiv:1404.6763},
  year   = {2014}
}

Comments

Full version of the extended abstract that will appear in Proceedings of ICALP 2014 track A

R2 v1 2026-06-22T03:59:40.666Z