Saved in:
Bibliographic Details
Main Authors: Amir, Gideon, Nazarov, Fedor, Peres, Yuval
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.19411
Tags: Add Tag
No Tags, Be the first to tag this record!
Table of Contents:
  • We consider the following dynamics on a connected graph $(V,E)$ with $n$ vertices. Given $p>1$ and an initial opinion profile $f_0:V \to [0,1]$, at each integer step $t \ge 1$ a uniformly random vertex $v=v_t$ is selected, and the opinion there is updated to the value $f_{t}(v)$ that minimizes the sum $\sum_{w \sim v} |f_t(v)-f_{t-1}(w)|^p$ over neighbours $w$ of $v$. The case $p=2$ yields linear averaging dynamics, but for all $p \ne 2$ the dynamics are nonlinear. In the limiting case $p=\infty$ (known as Lipschitz learning), $f_t(v)$ is the average of the largest and smallest values of $f_{t-1}(w)$ among the neighbours $w$ of $v$. We show that the number of steps needed to reduce the oscillation of $f_t$ below $ε$ is at most $n^{β_p}$ (up to logarithmic factors in $n$ and $ε$), where $β_p:=max(\frac{2p}{p-1},3)$; we prove that the exponent $β_p$ is optimal. The phase transition at $p=3$ is a new phenomenon. We also derive matching upper and lower bounds for convergence time as a function of $n$ and the average degree; these are the most challenging to prove.