Momentum Particle Maximum Likelihood

Jen Ning Lim; Juan Kuntz; Sam Power; Adam Johansen

Momentum Particle Maximum Likelihood

Jen Ning Lim^*, Juan Kuntz, Sam Power, Adam Johansen

^*Corresponding author for this work

School of Mathematics

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

2 Citations (Scopus)

Abstract

Maximum likelihood estimation (MLE) of latent variable models is often recast as the minimization of a free energy functional over an extended space of parameters and probability distributions. This perspective was recently combined with insights from optimal transport to obtain novel particle-based algorithms for fitting latent variable models to data. Drawing inspiration from prior works which interpret ‘momentum-enriched’ optimization algorithms as discretizations of ordinary differential equations, we propose an analogous dynamical-systems-inspired approach to minimizing the free energy functional. The result is a dynamical system that blends elements of Nesterov’s Accelerated Gradient method, the underdamped Langevin diffusion, and particle methods. Under suitable assumptions, we prove that the continuous-time system minimizes the functional. By discretizing the system, we obtain a practical algorithm for MLE in latent variable models. The algorithm outperforms existing particle methods in numerical experiments and compares favourably with other MLE algorithms.

Original language	English
Title of host publication	Proceedings of the 41st International Conference on Machine Learning
Editors	Ruslan Salakhutdinov, Zico Kolter, Katherine Heller, Adrian Weller, Nuria Oliver, Jonathan Scarlett, Felix Berkenkamp
Pages	29816-29871
Number of pages	56
Volume	235
Publication status	Published - 27 Jul 2024
Event	The 41st International Conference on Machine Learning - Messe Wien Exhibition Congress Center, Vienna, Austria Duration: 21 Jul 2024 → 27 Jul 2024 https://icml.cc/Conferences/2024

Publication series

Name	Proceedings of Machine Learning Research
ISSN (Print)	2640-3498

Conference

Conference	The 41st International Conference on Machine Learning
Abbreviated title	ICML 2024
Country/Territory	Austria
City	Vienna
Period	21/07/24 → 27/07/24
Internet address	https://icml.cc/Conferences/2024

Bibliographical note

Publisher Copyright:
2024 by the author(s).

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Accepted author manuscript, 3.15 MBLicence: CC BY

https://arxiv.org/abs/2312.07335Licence: CC BY
https://proceedings.mlr.press/v235/lim24b.htmlLicence: Unspecified

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Lim, J. N., Kuntz, J., Power, S., & Johansen, A. (2024). Momentum Particle Maximum Likelihood. In R. Salakhutdinov, Z. Kolter, K. Heller, A. Weller, N. Oliver, J. Scarlett, & F. Berkenkamp (Eds.), Proceedings of the 41st International Conference on Machine Learning (Vol. 235, pp. 29816-29871). (Proceedings of Machine Learning Research). https://arxiv.org/abs/2312.07335

@inproceedings{f80e3d22c0be446a8d9d2db0f3b93721,

title = "Momentum Particle Maximum Likelihood",

abstract = "Maximum likelihood estimation (MLE) of latent variable models is often recast as the minimization of a free energy functional over an extended space of parameters and probability distributions. This perspective was recently combined with insights from optimal transport to obtain novel particle-based algorithms for fitting latent variable models to data. Drawing inspiration from prior works which interpret {\textquoteleft}momentum-enriched{\textquoteright} optimization algorithms as discretizations of ordinary differential equations, we propose an analogous dynamical-systems-inspired approach to minimizing the free energy functional. The result is a dynamical system that blends elements of Nesterov{\textquoteright}s Accelerated Gradient method, the underdamped Langevin diffusion, and particle methods. Under suitable assumptions, we prove that the continuous-time system minimizes the functional. By discretizing the system, we obtain a practical algorithm for MLE in latent variable models. The algorithm outperforms existing particle methods in numerical experiments and compares favourably with other MLE algorithms.",

author = "Lim, \{Jen Ning\} and Juan Kuntz and Sam Power and Adam Johansen",

note = "Publisher Copyright: 2024 by the author(s).; The 41st International Conference on Machine Learning , ICML 2024 ; Conference date: 21-07-2024 Through 27-07-2024",

year = "2024",

month = jul,

day = "27",

language = "English",

volume = "235",

series = "Proceedings of Machine Learning Research",

pages = "29816--29871",

editor = "Ruslan Salakhutdinov and Zico Kolter and Katherine Heller and Adrian Weller and Nuria Oliver and Jonathan Scarlett and Felix Berkenkamp",

booktitle = "Proceedings of the 41st International Conference on Machine Learning",

url = "https://icml.cc/Conferences/2024",

}

Lim, JN, Kuntz, J, Power, S & Johansen, A 2024, Momentum Particle Maximum Likelihood. in R Salakhutdinov, Z Kolter, K Heller, A Weller, N Oliver, J Scarlett & F Berkenkamp (eds), Proceedings of the 41st International Conference on Machine Learning. vol. 235, Proceedings of Machine Learning Research, pp. 29816-29871, The 41st International Conference on Machine Learning , Vienna, Austria, 21/07/24. <https://arxiv.org/abs/2312.07335>

Momentum Particle Maximum Likelihood. / Lim, Jen Ning; Kuntz, Juan; Power, Sam et al.
Proceedings of the 41st International Conference on Machine Learning. ed. / Ruslan Salakhutdinov; Zico Kolter; Katherine Heller; Adrian Weller; Nuria Oliver; Jonathan Scarlett; Felix Berkenkamp. Vol. 235 2024. p. 29816-29871 (Proceedings of Machine Learning Research).

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

TY - GEN

T1 - Momentum Particle Maximum Likelihood

AU - Lim, Jen Ning

AU - Kuntz, Juan

AU - Power, Sam

AU - Johansen, Adam

PY - 2024/7/27

Y1 - 2024/7/27

N2 - Maximum likelihood estimation (MLE) of latent variable models is often recast as the minimization of a free energy functional over an extended space of parameters and probability distributions. This perspective was recently combined with insights from optimal transport to obtain novel particle-based algorithms for fitting latent variable models to data. Drawing inspiration from prior works which interpret ‘momentum-enriched’ optimization algorithms as discretizations of ordinary differential equations, we propose an analogous dynamical-systems-inspired approach to minimizing the free energy functional. The result is a dynamical system that blends elements of Nesterov’s Accelerated Gradient method, the underdamped Langevin diffusion, and particle methods. Under suitable assumptions, we prove that the continuous-time system minimizes the functional. By discretizing the system, we obtain a practical algorithm for MLE in latent variable models. The algorithm outperforms existing particle methods in numerical experiments and compares favourably with other MLE algorithms.

AB - Maximum likelihood estimation (MLE) of latent variable models is often recast as the minimization of a free energy functional over an extended space of parameters and probability distributions. This perspective was recently combined with insights from optimal transport to obtain novel particle-based algorithms for fitting latent variable models to data. Drawing inspiration from prior works which interpret ‘momentum-enriched’ optimization algorithms as discretizations of ordinary differential equations, we propose an analogous dynamical-systems-inspired approach to minimizing the free energy functional. The result is a dynamical system that blends elements of Nesterov’s Accelerated Gradient method, the underdamped Langevin diffusion, and particle methods. Under suitable assumptions, we prove that the continuous-time system minimizes the functional. By discretizing the system, we obtain a practical algorithm for MLE in latent variable models. The algorithm outperforms existing particle methods in numerical experiments and compares favourably with other MLE algorithms.

UR - https://icml.cc/Conferences/2024

M3 - Conference Contribution (Conference Proceeding)

VL - 235

T3 - Proceedings of Machine Learning Research

SP - 29816

EP - 29871

BT - Proceedings of the 41st International Conference on Machine Learning

A2 - Salakhutdinov, Ruslan

A2 - Kolter, Zico

A2 - Heller, Katherine

A2 - Weller, Adrian

A2 - Oliver, Nuria

A2 - Scarlett, Jonathan

A2 - Berkenkamp, Felix

T2 - The 41st International Conference on Machine Learning

Y2 - 21 July 2024 through 27 July 2024

ER -

Momentum Particle Maximum Likelihood

Abstract

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