English

Geometric Prediction: Moving Beyond Scalars

Machine Learning 2020-06-26 v1 Computational Physics Biomolecules Machine Learning

Abstract

Many quantities we are interested in predicting are geometric tensors; we refer to this class of problems as geometric prediction. Attempts to perform geometric prediction in real-world scenarios have been limited to approximating them through scalar predictions, leading to losses in data efficiency. In this work, we demonstrate that equivariant networks have the capability to predict real-world geometric tensors without the need for such approximations. We show the applicability of this method to the prediction of force fields and then propose a novel formulation of an important task, biomolecular structure refinement, as a geometric prediction problem, improving state-of-the-art structural candidates. In both settings, we find that our equivariant network is able to generalize to unseen systems, despite having been trained on small sets of examples. This novel and data-efficient ability to predict real-world geometric tensors opens the door to addressing many problems through the lens of geometric prediction, in areas such as 3D vision, robotics, and molecular and structural biology.

Keywords

Cite

@article{arxiv.2006.14163,
  title  = {Geometric Prediction: Moving Beyond Scalars},
  author = {Raphael J. L. Townshend and Brent Townshend and Stephan Eismann and Ron O. Dror},
  journal= {arXiv preprint arXiv:2006.14163},
  year   = {2020}
}

Comments

10 pages, 8 figures

R2 v1 2026-06-23T16:36:43.826Z