Rapid mixing in unimodal landscapes and efficient simulatedannealing for multimodal distributions
Abstract
We consider nearest neighbor weighted random walks on the d-dimensional box [n]d that are governed by some function g:[0,1] [0,), by which we mean that standing at x, a neighbor y of x is picked at random and the walk then moves there with probability (1/2)g(n-1y)/(g(n-1y)+g(n-1x)). We do this for g of the form fmn for some function f which assumed to be analytically well-behaved and where mn as n . This class of walks covers an abundance of interesting special cases, e.g., the mean-field Potts model, posterior collapsed Gibbs sampling for Latent Dirichlet allocation and certain Bayesian posteriors for models in nuclear physics. The following are among the results of this paper: itemize If f is unimodal with negative definite Hessian at its global maximum, then the mixing time of the random walk is O(n n). If f is multimodal, then the mixing time is exponential in n, but we show that there is a simulated annealing scheme governed by fK for an increasing sequence of K that mixes in time O(n2). Using a varying step size that decreases with K, this can be taken down to O(n n). If the process is studied on a general graph rather than the d-dimensional box, a simulated annealing scheme expressed in terms of conductances of the underlying network, works similarly. itemize Several examples are given, including the ones mentioned above.
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.