Machine learning (ML) models for molecules and materials commonly rely on a decomposition of the global target quantity into local, atom-centered contributions. This approach is convenient from a computational perspective, enabling large-scale ML-driven simulations with a linear-scaling cost and also allows for the identification and posthoc interpretation of contributions from individual chemical environments and motifs to complicated macroscopic properties. However, even though practical justifications exist for the local decomposition, only the global quantity is rigorously defined. Thus, when the atom-centered contributions are used, their sensitivity to the training strategy or the model architecture should be carefully considered. To this end, we introduce a quantitative metric, which we call the local prediction rigidity (LPR), that allows one to assess how robust the locally decomposed predictions of ML models are. We investigate the dependence of the LPR on the aspects of model training, particularly the composition of training data set, for a range of different problems from simple toy models to real chemical systems. We present strategies to systematically enhance the LPR, which can be used to improve the robustness, interpretability, and transferability of atomistic ML models.

Robustness of Local Predictions in Atomistic Machine Learning Models / Chong, Sanggyu; Grasselli, Federico; Ben Mahmoud, Chiheb; Morrow Joe, D.; Deringer Volker, L.; Ceriotti, Michele. - In: JOURNAL OF CHEMICAL THEORY AND COMPUTATION. - ISSN 1549-9618. - 19:22(2023), pp. 8020-8031. [10.1021/acs.jctc.3c00704]

Robustness of Local Predictions in Atomistic Machine Learning Models

Grasselli Federico;
2023

Abstract

Machine learning (ML) models for molecules and materials commonly rely on a decomposition of the global target quantity into local, atom-centered contributions. This approach is convenient from a computational perspective, enabling large-scale ML-driven simulations with a linear-scaling cost and also allows for the identification and posthoc interpretation of contributions from individual chemical environments and motifs to complicated macroscopic properties. However, even though practical justifications exist for the local decomposition, only the global quantity is rigorously defined. Thus, when the atom-centered contributions are used, their sensitivity to the training strategy or the model architecture should be carefully considered. To this end, we introduce a quantitative metric, which we call the local prediction rigidity (LPR), that allows one to assess how robust the locally decomposed predictions of ML models are. We investigate the dependence of the LPR on the aspects of model training, particularly the composition of training data set, for a range of different problems from simple toy models to real chemical systems. We present strategies to systematically enhance the LPR, which can be used to improve the robustness, interpretability, and transferability of atomistic ML models.
2023
19
22
8020
8031
Robustness of Local Predictions in Atomistic Machine Learning Models / Chong, Sanggyu; Grasselli, Federico; Ben Mahmoud, Chiheb; Morrow Joe, D.; Deringer Volker, L.; Ceriotti, Michele. - In: JOURNAL OF CHEMICAL THEORY AND COMPUTATION. - ISSN 1549-9618. - 19:22(2023), pp. 8020-8031. [10.1021/acs.jctc.3c00704]
Chong, Sanggyu; Grasselli, Federico; Ben Mahmoud, Chiheb; Morrow Joe, D.; Deringer Volker, L.; Ceriotti, Michele
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11380/1346508
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