Estimating Convergence of Markov chains with L-Lag Couplings

Niloy Biswas; Pierre E Jacob; Paul Vanetti

2019 NIPS NeurIPS 2019

Estimating Convergence of Markov chains with L-Lag Couplings

Abstract

Markov chain Monte Carlo (MCMC) methods generate samples that are asymptotically distributed from a target distribution of interest as the number of iterations goes to infinity. Various theoretical results provide upper bounds on the distance between the target and marginal distribution after a fixed number of iterations. These upper bounds are on a case by case basis and typically involve intractable quantities, which limits their use for practitioners. We introduce L-lag couplings to generate computable, non-asymptotic upper bound estimates for the total variation or the Wasserstein distance of general Markov chains. We apply L-lag couplings to the tasks of (i) determining MCMC burn-in, (ii) comparing different MCMC algorithms with the same target, and (iii) comparing exact and approximate MCMC. Lastly, we (iv) assess the bias of sequential Monte Carlo and self-normalized importance samplers.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Machine Learning and Mathematics & Optimization

📈 Trend Setter — Stochastic Processes

🧭 Keyword Pioneer — coupling method

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Niloy Biswas , Pierre E Jacob , Paul Vanetti

Topics

Artificial Intelligence > Bayesian & Probabilistic > Probabilistic Modeling Machine Learning > Optimization & Theory > Bayesian Inference Machine Learning > Optimization & Theory > Stochastic Processes Mathematics & Optimization > Mathematics > Probability Mathematics & Optimization > Mathematics > Statistics Mathematics & Optimization > Mathematics > Stochastic Processes Machine Learning > Bayesian & Probabilistic > Bayesian Inference Mathematics & Optimization > Probability > Stochastic Processes Machine Learning > Bayesian & Probabilistic > Markov Chain Monte Carlo

Keywords

wasserstein distance convergence analysis markov chain monte carlo sequential monte carlo total variation total variation distance coupling method

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