Convergence rate of p-energy minimization on graphs: sharp polynomial bounds and a phase transition at p=3

Abstract

We consider the following dynamics on a connected graph (V,E) with n vertices. Given p>1 and an initial opinion profile f0:V [0,1], at each integer step t 1 a uniformly random vertex v=vt is selected, and the opinion there is updated to the value ft(v) that minimizes the sum Σw v |ft(v)-ft-1(w)|p over neighbours w of v. The case p=2 yields linear averaging dynamics, but for all p 2 the dynamics are nonlinear. In the limiting case p=∞ (known as Lipschitz learning), ft(v) is the average of the largest and smallest values of ft-1(w) among the neighbours w of v. We show that the number of steps needed to reduce the oscillation of ft below ε is at most nβp (up to logarithmic factors in n and ε), where βp:=max(2pp-1,3); we prove that the exponent βp 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.