# Machine learning prediction errors better than DFT accuracy

**Authors:** Felix A. Faber, Luke Hutchison, Bing Huang, Justin Gilmer and, Samuel S. Schoenholz, George E. Dahl, Oriol Vinyals, Steven Kearnes, and Patrick F. Riley, O. Anatole von Lilienfeld

arXiv: 1702.05532 · 2020-06-22

## TL;DR

This study demonstrates that machine learning models can predict molecular properties with errors smaller than those of DFT calculations, potentially surpassing hybrid DFT accuracy when high-quality data is available.

## Contribution

The paper systematically compares various regressors and molecular representations, showing ML models can outperform DFT in predicting electronic properties of molecules.

## Key findings

- ML predictions deviate less than DFT from experimental data
- Prediction errors are close to chemical accuracy
- ML models could surpass DFT with better data

## Abstract

We investigate the impact of choosing regressors and molecular representations for the construction of fast machine learning (ML) models of thirteen electronic ground-state properties of organic molecules. The performance of each regressor/representation/property combination is assessed using learning curves which report out-of-sample errors as a function of training set size with up to $\sim$117k distinct molecules. Molecular structures and properties at hybrid density functional theory (DFT) level of theory used for training and testing come from the QM9 database [Ramakrishnan et al, {\em Scientific Data} {\bf 1} 140022 (2014)] and include dipole moment, polarizability, HOMO/LUMO energies and gap, electronic spatial extent, zero point vibrational energy, enthalpies and free energies of atomization, heat capacity and the highest fundamental vibrational frequency. Various representations from the literature have been studied (Coulomb matrix, bag of bonds, BAML and ECFP4, molecular graphs (MG)), as well as newly developed distribution based variants including histograms of distances (HD), and angles (HDA/MARAD), and dihedrals (HDAD). Regressors include linear models (Bayesian ridge regression (BR) and linear regression with elastic net regularization (EN)), random forest (RF), kernel ridge regression (KRR) and two types of neural net works, graph convolutions (GC) and gated graph networks (GG). We present numerical evidence that ML model predictions deviate from DFT less than DFT deviates from experiment for all properties. Furthermore, our out-of-sample prediction errors with respect to hybrid DFT reference are on par with, or close to, chemical accuracy. Our findings suggest that ML models could be more accurate than hybrid DFT if explicitly electron correlated quantum (or experimental) data was available.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1702.05532/full.md

## References

65 references — full list in the complete paper: https://tomesphere.com/paper/1702.05532/full.md

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Source: https://tomesphere.com/paper/1702.05532