Simulated annealing from continuum to discretization: a convergence analysis via the Eyring--Kramers law

Abstract

We study the convergence rate of continuous-time simulated annealing (Xt; \, t 0) and its discretization (xk; \, k =0,1, …) for approximating the global optimum of a given function f. We prove that the tail probability P(f(Xt) > f +δ) (resp. P(f(xk) > f +δ)) decays polynomial in time (resp. in cumulative step size), and provide an explicit rate as a function of the model parameters. Our argument applies the recent development on functional inequalities for the Gibbs measure at low temperatures -- the Eyring-Kramers law. In the discrete setting, we obtain a condition on the step size to ensure the convergence.