English

Computing Bounds on Product-Graph Pebbling Numbers

Combinatorics 2019-05-22 v1

Abstract

Given a distribution of pebbles to the vertices of a graph, a pebbling move removes two pebbles from a single vertex and places a single pebble on an adjacent vertex. The pebbling number π(G)\pi(G) is the smallest number such that, for any distribution of π(G)\pi(G) pebbles to the vertices of GG and choice of root vertex rr of GG, there exists a sequence of pebbling moves that places a pebble on rr. Computing π(G)\pi(G) is provably difficult, and recent methods for bounding π(G)\pi(G) have proved computationally intractable, even for moderately sized graphs. Graham conjectured that π(G  H)π(G)π(H)\pi(G ~\square~ H) \leq \pi(G) \pi(H), where G  HG ~\square~ H is the Cartesian product of GG and HH (1989). While the conjecture has been verified for specific families of graphs, in general it remains open. This study combines the focus of developing a computationally tractable, IP-based method for generating good bounds on π(G  H)\pi(G ~\square~ H), with the goal of shedding light on Graham's conjecture.We provide computational results for a variety of Cartesian-product graphs, including some that are known to satisfy Graham's conjecture and some that are not. Our approach leads to a sizable improvement on the best known bound for π(L  L)\pi(L ~\square~ L), where LL is the Lemke graph, and L  LL ~\square~ L is among the smallest known potential counterexamples to Graham's conjecture.

Keywords

Cite

@article{arxiv.1905.08683,
  title  = {Computing Bounds on Product-Graph Pebbling Numbers},
  author = {Franklin Kenter and Daphne Skipper and Dan Wilson},
  journal= {arXiv preprint arXiv:1905.08683},
  year   = {2019}
}

Comments

27 pages, 2 figures, 8 tables

R2 v1 2026-06-23T09:15:38.769Z