Percolation-like Scaling Exponents for Minimal Paths and Trees in the Stochastic Mean Field Model
Abstract
In the mean field (or random link) model there are n points and inter-point distances are independent random variables. For 0 < < ∞ and in the n ∞ limit, let δ() = 1/n × (maximum number of steps in a path whose average step-length is ≤ ). The function δ() is analogous to the percolation function in percolation theory: there is a critical value * = e-1 at which δ(·) becomes non-zero, and (presumably) a scaling exponent β in the sense δ() ( - *)β. Recently developed probabilistic methodology (in some sense a rephrasing of the cavity method of Mezard-Parisi) provides a simple albeit non-rigorous way of writing down such functions in terms of solutions of fixed-point equations for probability distributions. Solving numerically gives convincing evidence that β = 3. A parallel study with trees instead of paths gives scaling exponent β = 2. The new exponents coincide with those found in a different context (comparing optimal and near-optimal solutions of mean-field TSP and MST) and reinforce the suggestion that these scaling exponents determine universality classes for optimization problems on random points.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.