Regime-Switching Langevin Monte Carlo Algorithms
This work addresses sampling efficiency for MCMC methods in machine learning applications, but appears incremental as it builds on existing Langevin dynamics with modifications.
The authors tackled the problem of sampling from target probability distributions in machine learning by proposing regime-switching Langevin Monte Carlo algorithms, which introduce random stepsizes or frictional coefficients, and provided non-asymptotic convergence guarantees with iteration complexity analyses, supported by numerical experiments on synthetic and real data.
Langevin Monte Carlo (LMC) algorithms are popular Markov Chain Monte Carlo (MCMC) methods to sample a target probability distribution, which arises in many applications in machine learning. Inspired by regime-switching stochastic differential equations in the probability literature, we propose and study regime-switching Langevin dynamics (RS-LD) and regime-switching kinetic Langevin dynamics (RS-KLD). Based on their discretizations, we introduce regime-switching Langevin Monte Carlo (RS-LMC) and regime-switching kinetic Langevin Monte Carlo (RS-KLMC) algorithms, which can also be viewed as LMC and KLMC algorithms with random stepsizes. We also propose frictional-regime-switching kinetic Langevin dynamics (FRS-KLD) and its associated algorithm frictional-regime-switching kinetic Langevin Monte Carlo (FRS-KLMC), which can also be viewed as the KLMC algorithm with random frictional coefficients. We provide their 2-Wasserstein non-asymptotic convergence guarantees to the target distribution, and analyze the iteration complexities. Numerical experiments using both synthetic and real data are provided to illustrate the efficiency of our proposed algorithms.