English

Powerful, transferable representations for molecules through intelligent task selection in deep multitask networks

Chemical Physics 2018-09-18 v1 Machine Learning Machine Learning

Abstract

Chemical representations derived from deep learning are emerging as a powerful tool in areas such as drug discovery and materials innovation. Currently, this methodology has three major limitations - the cost of representation generation, risk of inherited bias, and the requirement for large amounts of data. We propose the use of multi-task learning in tandem with transfer learning to address these limitations directly. In order to avoid introducing unknown bias into multi-task learning through the task selection itself, we calculate task similarity through pairwise task affinity, and use this measure to programmatically select tasks. We test this methodology on several real-world data sets to demonstrate its potential for execution in complex and low-data environments. Finally, we utilise the task similarity to further probe the expressiveness of the learned representation through a comparison to a commonly used cheminformatics fingerprint, and show that the deep representation is able to capture more expressive task-based information.

Keywords

Cite

@article{arxiv.1809.06334,
  title  = {Powerful, transferable representations for molecules through intelligent task selection in deep multitask networks},
  author = {Clyde Fare and Lukas Turcani and Edward O. Pyzer-Knapp},
  journal= {arXiv preprint arXiv:1809.06334},
  year   = {2018}
}
R2 v1 2026-06-23T04:09:03.928Z