Lagrangian manifold Monte Carlo on Monge patches

Marcelo Hartmann; Mark Girolami; Arto Klami

Lagrangian manifold Monte Carlo on Monge patches

Marcelo Hartmann, Mark Girolami, Arto Klami

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Scientific › peer-review

Abstract

The efficiency of Markov Chain Monte Carlo (MCMC) depends on how the underlying geometry of the problem is taken into account. For distributions with strongly varying curvature, Riemannian metrics help in efficient exploration of the target distribution. Unfortunately, they have significant computational overhead due to e.g. repeated inversion of the metric tensor, and current geometric MCMC methods using the Fisher information matrix to induce the manifold are in practice slow. We propose a new alternative Riemannian metric for MCMC, by embedding the target distribution into a higher-dimensional Euclidean space as a Monge patch and using the induced metric determined by direct geometric reasoning. Our metric only requires first-order gradient information and has fast inverse and determinants, and allows reducing the computational complexity of individual iterations from cubic to quadratic in the problem dimensionality. We demonstrate how Lagrangian Monte Carlo in this metric efficiently explores the target distributions.

Original language	English
Title of host publication	Proceedings of The 25th International Conference on Artificial Intelligence and Statistics
Editors	Gustau Camps-Vall, Francisco J. R. Ruiz, Isabel Valera
Number of pages	18
Publisher	Journal of Machine Learning Research
Publication date	29 Jan 2022
Pages	4764-4781
Publication status	Published - 29 Jan 2022
MoE publication type	A4 Article in conference proceedings
Event	International Conference on Artificial Intelligence and Statistic - Duration: 28 Mar 2022 → 30 Mar 2022 Conference number: 25

Publication series

Name	Proceedings of Machine Learning Research, PMLR
Publisher	Journal of Machine Learning Research
Volume	151
ISSN (Electronic)	2640-3498

Fields of Science

113 Computer and information sciences
LANGEVIN

Access to Document

Lagrangian Manifold Monte Carlo on Monge PatchesAccepted author manuscript, 3.01 MBLicence: CC BY-NC

https://proceedings.mlr.press/v151/hartmann22a.htmlLicence: CC BY-NC

Laskennallisesti tehokas päättely Riemannin pinnoilla
Hartmann, M. (Project manager), Williams Moreno Sanchez, B. (Participant) & Yu, H. (Participant)
Academy of Finland
01/09/2022 → 31/08/2025
Project: Research Council of Finland: Postdoctoral Researcher

Cite this

Hartmann, M., Girolami, M., & Klami, A. (2022). Lagrangian manifold Monte Carlo on Monge patches. In G. Camps-Vall, F. J. R. Ruiz, & I. Valera (Eds.), Proceedings of The 25th International Conference on Artificial Intelligence and Statistics (pp. 4764-4781). (Proceedings of Machine Learning Research, PMLR; Vol. 151). Journal of Machine Learning Research. https://proceedings.mlr.press/v151/hartmann22a.html

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title = "Lagrangian manifold Monte Carlo on Monge patches",

abstract = "The efficiency of Markov Chain Monte Carlo (MCMC) depends on how the underlying geometry of the problem is taken into account. For distributions with strongly varying curvature, Riemannian metrics help in efficient exploration of the target distribution. Unfortunately, they have significant computational overhead due to e.g. repeated inversion of the metric tensor, and current geometric MCMC methods using the Fisher information matrix to induce the manifold are in practice slow. We propose a new alternative Riemannian metric for MCMC, by embedding the target distribution into a higher-dimensional Euclidean space as a Monge patch and using the induced metric determined by direct geometric reasoning. Our metric only requires first-order gradient information and has fast inverse and determinants, and allows reducing the computational complexity of individual iterations from cubic to quadratic in the problem dimensionality. We demonstrate how Lagrangian Monte Carlo in this metric efficiently explores the target distributions. ",

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booktitle = "Proceedings of The 25th International Conference on Artificial Intelligence and Statistics",

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Hartmann, M, Girolami, M & Klami, A 2022, Lagrangian manifold Monte Carlo on Monge patches. in G Camps-Vall, FJR Ruiz & I Valera (eds), Proceedings of The 25th International Conference on Artificial Intelligence and Statistics. Proceedings of Machine Learning Research, PMLR, vol. 151, Journal of Machine Learning Research, pp. 4764-4781, International Conference on Artificial Intelligence and Statistic, 28/03/2022. <https://proceedings.mlr.press/v151/hartmann22a.html>

Lagrangian manifold Monte Carlo on Monge patches. / Hartmann, Marcelo; Girolami, Mark; Klami, Arto.
Proceedings of The 25th International Conference on Artificial Intelligence and Statistics. ed. / Gustau Camps-Vall; Francisco J. R. Ruiz; Isabel Valera. Journal of Machine Learning Research, 2022. p. 4764-4781 (Proceedings of Machine Learning Research, PMLR; Vol. 151).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Lagrangian manifold Monte Carlo on Monge patches

AU - Hartmann, Marcelo

AU - Girolami, Mark

AU - Klami, Arto

N1 - Conference code: 25

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Y1 - 2022/1/29

N2 - The efficiency of Markov Chain Monte Carlo (MCMC) depends on how the underlying geometry of the problem is taken into account. For distributions with strongly varying curvature, Riemannian metrics help in efficient exploration of the target distribution. Unfortunately, they have significant computational overhead due to e.g. repeated inversion of the metric tensor, and current geometric MCMC methods using the Fisher information matrix to induce the manifold are in practice slow. We propose a new alternative Riemannian metric for MCMC, by embedding the target distribution into a higher-dimensional Euclidean space as a Monge patch and using the induced metric determined by direct geometric reasoning. Our metric only requires first-order gradient information and has fast inverse and determinants, and allows reducing the computational complexity of individual iterations from cubic to quadratic in the problem dimensionality. We demonstrate how Lagrangian Monte Carlo in this metric efficiently explores the target distributions.

AB - The efficiency of Markov Chain Monte Carlo (MCMC) depends on how the underlying geometry of the problem is taken into account. For distributions with strongly varying curvature, Riemannian metrics help in efficient exploration of the target distribution. Unfortunately, they have significant computational overhead due to e.g. repeated inversion of the metric tensor, and current geometric MCMC methods using the Fisher information matrix to induce the manifold are in practice slow. We propose a new alternative Riemannian metric for MCMC, by embedding the target distribution into a higher-dimensional Euclidean space as a Monge patch and using the induced metric determined by direct geometric reasoning. Our metric only requires first-order gradient information and has fast inverse and determinants, and allows reducing the computational complexity of individual iterations from cubic to quadratic in the problem dimensionality. We demonstrate how Lagrangian Monte Carlo in this metric efficiently explores the target distributions.

KW - 113 Computer and information sciences

KW - LANGEVIN

M3 - Conference contribution

T3 - Proceedings of Machine Learning Research, PMLR

SP - 4764

EP - 4781

BT - Proceedings of The 25th International Conference on Artificial Intelligence and Statistics

A2 - Camps-Vall, Gustau

A2 - Ruiz, Francisco J. R.

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PB - Journal of Machine Learning Research

T2 - International Conference on Artificial Intelligence and Statistic

Y2 - 28 March 2022 through 30 March 2022

ER -

Lagrangian manifold Monte Carlo on Monge patches

Abstract

Publication series

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Projects

Laskennallisesti tehokas päättely Riemannin pinnoilla

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