English

Temporal Network Optimization Subject to Connectivity Constraints

Discrete Mathematics 2018-07-02 v2

Abstract

In this work we consider \emph{temporal networks}, i.e. networks defined by a \emph{labeling} λ\lambda assigning to each edge of an \emph{underlying graph} GG a set of \emph{discrete} time-labels. The labels of an edge, which are natural numbers, indicate the discrete time moments at which the edge is available. We focus on \emph{path problems} of temporal networks. In particular, we consider \emph{time-respecting} paths, i.e. paths whose edges are assigned by λ\lambda a strictly increasing sequence of labels. We begin by giving two efficient algorithms for computing shortest time-respecting paths on a temporal network. We then prove that there is a \emph{natural analogue of Menger's theorem} holding for arbitrary temporal networks. Finally, we propose two \emph{cost minimization parameters} for temporal network design. One is the \emph{temporality} of GG, in which the goal is to minimize the maximum number of labels of an edge, and the other is the \emph{temporal cost} of GG, in which the goal is to minimize the total number of labels used. Optimization of these parameters is performed subject to some \emph{connectivity constraint}. We prove several lower and upper bounds for the temporality and the temporal cost of some very basic graph families such as rings, directed acyclic graphs, and trees.

Keywords

Cite

@article{arxiv.1502.04382,
  title  = {Temporal Network Optimization Subject to Connectivity Constraints},
  author = {George B. Mertzios and Othon Michail and Paul G. Spirakis},
  journal= {arXiv preprint arXiv:1502.04382},
  year   = {2018}
}
R2 v1 2026-06-22T08:30:04.554Z