English

Counting Path Configurations in Parallel Diffusion

Combinatorics 2020-10-13 v1

Abstract

Parallel Diffusion is a variant of Chip-Firing introduced in 2018 by Duffy et al. In Parallel Diffusion, chips move from places of high concentration to places of low concentration through a discrete-time process. At each time step, every vertex sends a chip to each of its poorer neighbours, allowing for some vertices to perhaps fall into debt (represented by negative stack sizes). In their recent paper, Long and Narayanan proved a conjecture from the original paper by Duffy et al. that every Parallel Diffusion process eventually, after some pre-period, exhibits periodic behaviour. With this result, we are now able to count the number of these periods that exist up to a definition of isomorphism. We determine a recurrence relation for calculating this number for a path of any length. If TnT_n is the number of configurations with period length 2 that can exist on PnP_n up to isomorphism and nn is an integer greater than 4, we conclude that Tn=3Tn1+2Tn2+Tn3Tn4T_n = 3T_{n-1} + 2T_{n-2} + T_{n-3} - T_{n-4}.

Keywords

Cite

@article{arxiv.2010.04750,
  title  = {Counting Path Configurations in Parallel Diffusion},
  author = {Todd Mullen and Richard Nowakowski and Danielle Cox},
  journal= {arXiv preprint arXiv:2010.04750},
  year   = {2020}
}
R2 v1 2026-06-23T19:13:12.944Z