English

Pebbling on Directed Graphs with Fixed Diameter

Combinatorics 2018-09-10 v1

Abstract

Pebbling is a game played on a graph. The single player is given a graph and a configuration of pebbles and may make pebbling moves by removing 2 pebbles from one vertex and placing one at an adjacent vertex to eventually have one pebble reach a predetermined vertex. The pebbling number, π(G)\pi(G), is the minimum number of pebbles such that regardless of their exact configuration, the player can use pebbling moves to have a pebble reach any predetermined vertex. Previous work has related π(G)\pi(G) to the diameter of GG. Clarke, Hochberg, and Hurlbert demonstrated that every connected undirected graph on nn vertices with diameter 2 has π(G)=n\pi(G) = n unless it belongs to an exceptional family of graphs, consisting of those that can be constructed in a specific manner; in which case π(G)=n+1\pi(G) = n +1. By generalizing a result of Chan and Godbole, Postle showed that for a graph with diameter dd, π(G)n2d2(1+on(1))\pi(G) \le n 2^{\lceil \frac{d}{2} \rceil} (1+o_n(1)). In this article, we continue this study relating pebbling and diameter with a focus on directed graphs. This leads to some surprising results. First, we show that in an oriented directed graph GG (in the sense that if iji \to j then we cannot have jij \to i), it is indeed the case that if GG has diameter 2, π(G)=n\pi(G) = n or n+1n + 1, and if π(G)=n+1\pi(G) = n+1, the directed graph has a very particular structure. In the case of general directed graphs (that is, if iji \to j, we may or may not have an arc jij \to i) with diameter 2, we show that π(G)\pi(G) can be as large as 32n+1\frac32 n + 1, and further, this bound is sharp. More generally, we show that for general directed graphs, π(G)2dn/d+f(d)\pi(G) \le 2^d n / d + f(d) where f(d)f(d) is some function of only dd.

Keywords

Cite

@article{arxiv.1809.02582,
  title  = {Pebbling on Directed Graphs with Fixed Diameter},
  author = {John Asplund and Franklin Kenter},
  journal= {arXiv preprint arXiv:1809.02582},
  year   = {2018}
}

Comments

15 pages, 3 figures

R2 v1 2026-06-23T03:58:17.208Z