Convergence of Langevin-Simulated Annealing algorithms with multiplicative noise II: Total Variation
Abstract
We study the convergence of Langevin-Simulated Annealing type algorithms with multiplicative noise, i.e. for V : Rd R a potential function to minimize, we consider the stochastic differential equation dYt = - σ σ ∇ V(Yt) dt + a(t)σ(Yt)dWt + a(t)2(Yt)dt, where (Wt) is a Brownian motion, where σ : Rd Md(R) is an adaptive (multiplicative) noise, where a : R+ R+ is a function decreasing to 0 and where is a correction term. Allowing σ to depend on the position brings faster convergence in comparison with the classical Langevin equation dYt = -∇ V(Yt)dt + σ dWt. In a previous paper we established the convergence in L1-Wasserstein distance of Yt and of its associated Euler scheme Yt to argmin(V) with the classical schedule a(t) = A-1/2(t). In the present paper we prove the convergence in total variation distance. The total variation case appears more demanding to deal with and requires regularization lemmas.
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