2012
NIPS
NeurIPS 2012
Learning Invariant Representations of Molecules for Atomization Energy Prediction
Abstract
The accurate prediction of molecular energetics in chemical compound space is a crucial ingredient for rational compound design. The inherently graph-like, non-vectorial nature of molecular data gives rise to a unique and difficult machine learning problem. In this paper, we adopt a learning-from-scratch approach where quantum-mechanical molecular energies are predicted directly from the raw molecular geometry. The study suggests a benefit from setting flexible priors and enforcing invariance stochastically rather than structurally. Our results improve the state-of-the-art by a factor of almost three, bringing statistical methods one step closer to the holy grail of ''chemical accuracy''.
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Interdisciplinary Bridge
— Deep Learning and Healthcare & Medicine and Machine Learning
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Trend Setter
— Graph Neural Networks
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Keyword Pioneer
— molecular machine learning
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Cross-Pollinator
— Artificial Intelligence, Computer Vision, Deep Learning, Healthcare & Medicine, Machine Learning, Natural Language Processing
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Topic Pioneer
— Feature Learning
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Hot Topic Early Bird
— graph representation
Authors
Topics
Machine Learning > Core Methods > Representation Learning
Machine Learning > Learning Types > Self-Supervised Learning
Deep Learning > Architectures > Graph Neural Networks
Healthcare & Medicine > Research > Bioinformatics
Machine Learning > Learning Types > Representation Learning
Interdisciplinary > Science > Bioinformatics
Deep Learning > Learning Types > Feature Learning
Keywords
graph representation
molecular machine learning
quantum mechanical energies
graph-like molecular data
atomization energy prediction
molecular geometry
atomization energy
quantum-mechanical energies
graph-like data
molecular representation
invariant representation
molecular property prediction
graph neural network
quantum-mechanical energy