Vacant sets and vacant nets: Component structures induced by a random walk

Abstract

Given a discrete random walk on a finite graph G, the vacant set and vacant net are, respectively, the sets of vertices and edges which remain unvisited by the walk at a given step t.%These sets induce subgraphs of the underlying graph. Let (t) be the subgraph of G induced by the vacant set of the walk at step t. Similarly, let (t) be the subgraph of G induced by the edges of the vacant net. For random r-regular graphs Gr, it was previously established that for a simple random walk, the graph (t) of the vacant set undergoes a phase transition in the sense of the phase transition on Erdos-Renyi graphs Gn,p. Thus, for r 3 there is an explicit value t*=t*(r) of the walk, such that for t≤ (1-ε)t*, (t) has a unique giant component, plus components of size O( n), whereas for t≥ (1+ε)t* all the components of (t) are of size O( n). We establish the threshold value t for a phase transition in the graph (t) of the vacant net of a simple random walk on a random r-regular graph. We obtain the corresponding threshold results for the vacant set and vacant net of two modified random walks. These are a non-backtracking random walk, and, for r even, a random walk which chooses unvisited edges whenever available. This allows a direct comparison of thresholds between simple and modified walks on random r-regular graphs. The main findings are the following: As r increases the threshold for the vacant set converges to n r in all three walks. For the vacant net, the threshold converges to rn/2 \; n for both the simple random walk and non-backtracking random walk. When r 4 is even, the threshold for the vacant net of the unvisited edge process converges to rn/2, which is also the vertex cover time of the process.