Coherent energy and force uncertainty in deep learning force fields

Peter Bjørn Jørgensen; Jonas Busk; Ole Winther; Mikkel N. Schmidt

Coherent energy and force uncertainty in deep learning force fields

Peter Bjørn Jørgensen, Jonas Busk, Ole Winther, Mikkel N. Schmidt

Alexandra Institute

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Abstract

In machine learning energy potentials for atomic systems, forces are commonly obtained as the negative derivative of the energy function with respect to atomic positions. To quantify aleatoric uncertainty in the predicted energies, a widely
used modeling approach involves predicting both a mean and variance for each energy value. However, this model is not differentiable under the usual white noise assumption, so energy uncertainty does not naturally translate to force uncertainty. In this work we propose a machine learning potential energy model in which energy and force aleatoric uncertainty are linked through a spatially correlated noise process. We demonstrate our approach on an equivariant messages passing neural network potential trained on energies and forces on two out-of-equilibrium molecular datasets. Furthermore, we also show how to obtain epistemic uncertainties in this setting based on a Bayesian interpretation of deep ensemble models.

Original language	English
Title of host publication	Proceedings of ELLIS Advancing Molecular Machine Learning Workshop
Number of pages	13
Publication date	2023
Publication status	Published - 2023
Event	ELLIS Advancing Molecular Machine Learning Workshop - Virtual event Duration: 13 Dec 2023 → 13 Dec 2023

Conference

Conference	ELLIS Advancing Molecular Machine Learning Workshop
City	Virtual event
Period	13/12/2023 → 13/12/2023

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title = "Coherent energy and force uncertainty in deep learning force fields",

abstract = "In machine learning energy potentials for atomic systems, forces are commonly obtained as the negative derivative of the energy function with respect to atomic positions. To quantify aleatoric uncertainty in the predicted energies, a widelyused modeling approach involves predicting both a mean and variance for each energy value. However, this model is not differentiable under the usual white noise assumption, so energy uncertainty does not naturally translate to force uncertainty. In this work we propose a machine learning potential energy model in which energy and force aleatoric uncertainty are linked through a spatially correlated noise process. We demonstrate our approach on an equivariant messages passing neural network potential trained on energies and forces on two out-of-equilibrium molecular datasets. Furthermore, we also show how to obtain epistemic uncertainties in this setting based on a Bayesian interpretation of deep ensemble models.",

author = "J{\o}rgensen, {Peter Bj{\o}rn} and Jonas Busk and Ole Winther and Schmidt, {Mikkel N.}",

year = "2023",

language = "English",

booktitle = "Proceedings of ELLIS Advancing Molecular Machine Learning Workshop",

note = "ELLIS Advancing Molecular Machine Learning Workshop<br/>, ML4Molecules 2023 ; Conference date: 13-12-2023 Through 13-12-2023",

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TY - GEN

T1 - Coherent energy and force uncertainty in deep learning force fields

AU - Jørgensen, Peter Bjørn

AU - Busk, Jonas

AU - Winther, Ole

AU - Schmidt, Mikkel N.

PY - 2023

Y1 - 2023

N2 - In machine learning energy potentials for atomic systems, forces are commonly obtained as the negative derivative of the energy function with respect to atomic positions. To quantify aleatoric uncertainty in the predicted energies, a widelyused modeling approach involves predicting both a mean and variance for each energy value. However, this model is not differentiable under the usual white noise assumption, so energy uncertainty does not naturally translate to force uncertainty. In this work we propose a machine learning potential energy model in which energy and force aleatoric uncertainty are linked through a spatially correlated noise process. We demonstrate our approach on an equivariant messages passing neural network potential trained on energies and forces on two out-of-equilibrium molecular datasets. Furthermore, we also show how to obtain epistemic uncertainties in this setting based on a Bayesian interpretation of deep ensemble models.

AB - In machine learning energy potentials for atomic systems, forces are commonly obtained as the negative derivative of the energy function with respect to atomic positions. To quantify aleatoric uncertainty in the predicted energies, a widelyused modeling approach involves predicting both a mean and variance for each energy value. However, this model is not differentiable under the usual white noise assumption, so energy uncertainty does not naturally translate to force uncertainty. In this work we propose a machine learning potential energy model in which energy and force aleatoric uncertainty are linked through a spatially correlated noise process. We demonstrate our approach on an equivariant messages passing neural network potential trained on energies and forces on two out-of-equilibrium molecular datasets. Furthermore, we also show how to obtain epistemic uncertainties in this setting based on a Bayesian interpretation of deep ensemble models.

M3 - Article in proceedings

BT - Proceedings of ELLIS Advancing Molecular Machine Learning Workshop

T2 - ELLIS Advancing Molecular Machine Learning Workshop<br/>

Y2 - 13 December 2023 through 13 December 2023

ER -

Coherent energy and force uncertainty in deep learning force fields

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