Spherical convolutions and their application in molecular modelling

Wouter Boomsma, Jes Frellsen

Research output: Conference Article in Proceeding or Book/Report chapterArticle in proceedingsResearchpeer-review

Abstract

Convolutional neural networks are increasingly used outside the domain of image analysis, in particular in various areas of the natural sciences concerned with spatial data. Such networks often work out-of-the box, and in some cases entire model architectures from image analysis can be carried over to other problem domains almost unaltered. Unfortunately, this convenience does not trivially extend to data in non-euclidean spaces, such as spherical data. In this paper, we introduce two strategies for conducting convolutions on the sphere, using either a spherical-polar grid or a grid based on the cubed-sphere representation. We investigate the challenges that arise in this setting, and extend our discussion to include scenarios of spherical volumes, with several strategies for parameterizing the radial dimension. As a proof of concept, we conclude with an assessment of the performance of spherical convolutions in the context of molecular modelling, by considering structural environments within proteins. We show that the models are capable of learning non-trivial functions in these molecular environments, and that our spherical convolutions generally outperform standard 3D convolutions in this setting. In particular, despite the lack of any domain specific feature-engineering, we demonstrate performance comparable to state-of-the-art methods in the field, which build on decades of domain-specific knowledge.
Original languageEnglish
Title of host publicationAdvances in Neural Information Processing Systems 30 : NIPS 2017
PublisherCurran Associates, Inc.
Publication date2017
Pages3436-3446
ISBN (Electronic)N/A
Publication statusPublished - 2017

Keywords

  • Convolutional Neural Networks
  • Spherical Data
  • Cubed-Sphere Representation
  • Molecular Modelling
  • Spherical Convolutions

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