Physics-Informed Variational State-Space Gaussian Processes

Oliver Hamelijnck; Arno Solin; Theodoros Damoulas

Physics-Informed Variational State-Space Gaussian Processes

Oliver Hamelijnck, Arno Solin, Theodoros Damoulas

University of Warwick

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

Abstract

Differential equations are important mechanistic models that are integral to many scientific and engineering applications. With the abundance of available data there has been a growing interest in data-driven physics-informed models. Gaussian processes (GPs) are particularly suited to this task as they can model complex, non-linear phenomena whilst incorporating prior knowledge and quantifying uncertainty. Current approaches have found some success but are limited as they either achieve poor computational scalings or focus only on the temporal setting. This work addresses these issues by introducing a variational spatio-temporal state-space GP that handles linear and non-linear physical constraints while achieving efficient linear-in-time computation costs. We demonstrate our methods in a range of synthetic and real-world settings and outperform the current state-of-the-art in both predictive and computational performance.

Original language	English
Title of host publication	Advances in Neural Information Processing Systems 37 (NeurIPS 2024)
Editors	A. Globerson, L. Mackey, D. Belgrave, A. Fan, U. Paquet, J. Tomczak, C. Zhang
Publisher	Curran Associates Inc.
ISBN (Print)	9798331314385
Publication status	Published - 2025
MoE publication type	A4 Conference publication
Event	Conference on Neural Information Processing Systems - Vancouver, Canada, Vancouver , Canada Duration: 10 Dec 2024 → 15 Dec 2024 Conference number: 38 https://neurips.cc/Conferences/2024

Publication series

Name	Advances in Neural Information Processing Systems
Publisher	Curran Associates, Inc.
Volume	37
ISSN (Print)	1049-5258

Conference

Conference	Conference on Neural Information Processing Systems
Abbreviated title	NeurIPS
Country/Territory	Canada
City	Vancouver
Period	10/12/2024 → 15/12/2024
Internet address	https://neurips.cc/Conferences/2024

Access to Document

Solin Arno /AoF Fellow Salary: Probabilistic principles for latent space exploration in deep learning
Solin, A. (Principal investigator)
01/09/2021 → 31/08/2026
Project: RCF Academy Research Fellow (new)

Cite this

Hamelijnck, O., Solin, A., & Damoulas, T. (2025). Physics-Informed Variational State-Space Gaussian Processes. In A. Globerson, L. Mackey, D. Belgrave, A. Fan, U. Paquet, J. Tomczak, & C. Zhang (Eds.), Advances in Neural Information Processing Systems 37 (NeurIPS 2024) (Advances in Neural Information Processing Systems; Vol. 37). Curran Associates Inc.. https://arxiv.org/abs/2409.13876

@inproceedings{5fbd5510bb80499cb5f12c052db6a85e,

title = "Physics-Informed Variational State-Space Gaussian Processes",

abstract = "Differential equations are important mechanistic models that are integral to many scientific and engineering applications. With the abundance of available data there has been a growing interest in data-driven physics-informed models. Gaussian processes (GPs) are particularly suited to this task as they can model complex, non-linear phenomena whilst incorporating prior knowledge and quantifying uncertainty. Current approaches have found some success but are limited as they either achieve poor computational scalings or focus only on the temporal setting. This work addresses these issues by introducing a variational spatio-temporal state-space GP that handles linear and non-linear physical constraints while achieving efficient linear-in-time computation costs. We demonstrate our methods in a range of synthetic and real-world settings and outperform the current state-of-the-art in both predictive and computational performance.",

author = "Oliver Hamelijnck and Arno Solin and Theodoros Damoulas",

year = "2025",

language = "English",

isbn = "9798331314385",

series = "Advances in Neural Information Processing Systems",

publisher = "Curran Associates Inc.",

editor = "A. Globerson and L. Mackey and D. Belgrave and A. Fan and U. Paquet and J. Tomczak and C. Zhang",

booktitle = "Advances in Neural Information Processing Systems 37 (NeurIPS 2024)",

address = "United States",

note = "Conference on Neural Information Processing Systems, NeurIPS ; Conference date: 10-12-2024 Through 15-12-2024",

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

}

Hamelijnck, O, Solin, A & Damoulas, T 2025, Physics-Informed Variational State-Space Gaussian Processes. in A Globerson, L Mackey, D Belgrave, A Fan, U Paquet, J Tomczak & C Zhang (eds), Advances in Neural Information Processing Systems 37 (NeurIPS 2024). Advances in Neural Information Processing Systems, vol. 37, Curran Associates Inc., Conference on Neural Information Processing Systems, Vancouver , Canada, 10/12/2024. <https://arxiv.org/abs/2409.13876>

Physics-Informed Variational State-Space Gaussian Processes. / Hamelijnck, Oliver; Solin, Arno; Damoulas, Theodoros.
Advances in Neural Information Processing Systems 37 (NeurIPS 2024). ed. / A. Globerson; L. Mackey; D. Belgrave; A. Fan; U. Paquet; J. Tomczak; C. Zhang. Curran Associates Inc., 2025. (Advances in Neural Information Processing Systems; Vol. 37).

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

TY - GEN

T1 - Physics-Informed Variational State-Space Gaussian Processes

AU - Hamelijnck, Oliver

AU - Solin, Arno

AU - Damoulas, Theodoros

N1 - Conference code: 38

PY - 2025

Y1 - 2025

N2 - Differential equations are important mechanistic models that are integral to many scientific and engineering applications. With the abundance of available data there has been a growing interest in data-driven physics-informed models. Gaussian processes (GPs) are particularly suited to this task as they can model complex, non-linear phenomena whilst incorporating prior knowledge and quantifying uncertainty. Current approaches have found some success but are limited as they either achieve poor computational scalings or focus only on the temporal setting. This work addresses these issues by introducing a variational spatio-temporal state-space GP that handles linear and non-linear physical constraints while achieving efficient linear-in-time computation costs. We demonstrate our methods in a range of synthetic and real-world settings and outperform the current state-of-the-art in both predictive and computational performance.

AB - Differential equations are important mechanistic models that are integral to many scientific and engineering applications. With the abundance of available data there has been a growing interest in data-driven physics-informed models. Gaussian processes (GPs) are particularly suited to this task as they can model complex, non-linear phenomena whilst incorporating prior knowledge and quantifying uncertainty. Current approaches have found some success but are limited as they either achieve poor computational scalings or focus only on the temporal setting. This work addresses these issues by introducing a variational spatio-temporal state-space GP that handles linear and non-linear physical constraints while achieving efficient linear-in-time computation costs. We demonstrate our methods in a range of synthetic and real-world settings and outperform the current state-of-the-art in both predictive and computational performance.

M3 - Conference article in proceedings

SN - 9798331314385

T3 - Advances in Neural Information Processing Systems

BT - Advances in Neural Information Processing Systems 37 (NeurIPS 2024)

A2 - Globerson, A.

A2 - Mackey, L.

A2 - Belgrave, D.

A2 - Fan, A.

A2 - Paquet, U.

A2 - Tomczak, J.

A2 - Zhang, C.

PB - Curran Associates Inc.

T2 - Conference on Neural Information Processing Systems

Y2 - 10 December 2024 through 15 December 2024

ER -

Physics-Informed Variational State-Space Gaussian Processes

Abstract

Publication series

Conference

Access to Document

Fingerprint

Projects

Solin Arno /AoF Fellow Salary: Probabilistic principles for latent space exploration in deep learning

Cite this