Abstract
Quantitative long-time entropic convergence and short-time regularization are established for an idealized Hamiltonian Monte Carlo chain which alternatively follows an Hamiltonian dynamics for a fixed time and then partially or totally refreshes its velocity with an auto-regressive Gaussian step. These results, in discrete time, are the analogues of similar results for the continuous-time kinetic Langevin diffusion, and the latter can be obtained from our bounds in a suitable limit regime. The dependency in the log-Sobolev constant of the target measure is sharp and is illustrated on a mean-field case and on a low-temperature regime, with an application to the simulated annealing algorithm. The practical unadjusted algorithm is briefly discussed.
Funding Statement
This work has been partially funded by the French ANR grants EFI (ANR-17-CE40-0030) and SWIDIMS (ANR-20-CE40-0022) and by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No 810367), project EMC2.
Acknowledgments
P. Monmarché thanks Alain Durmus for fruitful discussions.
Citation
Pierre Monmarché. "An entropic approach for Hamiltonian Monte Carlo: The idealized case." Ann. Appl. Probab. 34 (2) 2243 - 2293, April 2024. https://doi.org/10.1214/23-AAP2021
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