Constructing Near Spanning Trees with Few Local Inspections

Abstract

Constructing a spanning tree of a graph is one of the most basic tasks in graph theory. Motivated by several recent studies of local graph algorithms, we consider the following variant of this problem. Let G be a connected bounded-degree graph. Given an edge e in G we would like to decide whether e belongs to a connected subgraph G' consisting of (1+ε)n edges (for a prespecified constant ε >0), where the decision for different edges should be consistent with the same subgraph G'. Can this task be performed by inspecting only a constant number of edges in G? Our main results are: (1) We show that if every t-vertex subgraph of G has expansion 1/( t)1+o(1) then one can (deterministically) construct a sparse spanning subgraph G' of G using few inspections. To this end we analyze a "local" version of a famous minimum-weight spanning tree algorithm. (2) We show that the above expansion requirement is sharp even when allowing randomization. To this end we construct a family of 3-regular graphs of high girth, in which every t-vertex subgraph has expansion 1/( t)1-o(1).