Convergence rate of p-relaxation on a graph to a p-harmonic function with given boundary values
Abstract
We analyze the following dynamics on a connected graph (V,E) with n vertices. Let V = I B, where the set of interior vertices I is disjoint from the set of boundary vertices B ≠ . Given p > 1 and an initial opinion profile f0: V [0,1], at each integer step t 1 a uniformly random vertex vt ∈ I is selected, and the opinion there is updated to the value ft(vt) that minimizes the sum Σw vt ft(vt)-ft-1(w) p over neighbours w of vt. The case p=2 yields linear averaging dynamics, but for all p 2 the dynamics are nonlinear. It is well known that almost surely, ft converges to the p-harmonic extension h of f0 B. Denote the number of steps needed to obtain ft - h ∞ ε by τp(ε). Recently, Amir, Nazarov, and Peres~noboundarycase analyzed the same dynamics without boundary. For individual graphs, adding boundary values can slow down the convergence considerably; indeed, when p = 2 the approximation time is controlled by the hitting time of the boundary by random walk, and hitting times can be much larger than mixing times, which control the convergence when B=. Nevertheless, we show that for all graphs with n vertices, the mean approximation time [τp(ε)] is at most nβp (up to logarithmic factors in nε for p ∈ [2, ∞), and polynomial factors in ε-1 for p ∈ (1, 2)), where βp=(2pp-1,3). This matches the definition of βp given in noboundarycase and answers Question 6.2 in that paper. The exponent βp is optimal in both settings. We also prove sharp bounds for n-vertex graphs with given average degree, that are technically more challenging.
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