Thinned Mean Field Langevin Dynamics

Abstract

Several important learning tasks can be formulated as minimizing an entropy-regularized objective over an appropriate space of probability distributions. Mean-field Langevin dynamics (MFLD) facilitate computation in this general context, casting the minimizer as the invariant distribution of a McKean--Vlasov process, which can be numerically discretized using N particles and thus simulated. However, simulating this interacting particle system has computational complexity of order N2. Motivated by recent research into kernel thinning, we propose KT-MFLD, in which each particle interacts only with a thinned particle coreset of size O(N12). KT-MFLD thus reduces the computational complexity to order N32 while, under mild regularity conditions, achieving the same convergence guarantees (up to logarithmic factors) as MFLD. Our theoretical analysis is empirically confirmed on tasks including the training of student-teacher neural networks, quantization with maximum mean discrepancy, and computation of predictively-oriented posteriors in a post-Bayesian framework.