English

Learning domain-specific causal discovery from time series

Machine Learning 2023-10-11 v3 Artificial Intelligence Methodology

Abstract

Causal discovery (CD) from time-varying data is important in neuroscience, medicine, and machine learning. Techniques for CD encompass randomized experiments, which are generally unbiased but expensive, and algorithms such as Granger causality, conditional-independence-based, structural-equation-based, and score-based methods that are only accurate under strong assumptions made by human designers. However, as demonstrated in other areas of machine learning, human expertise is often not entirely accurate and tends to be outperformed in domains with abundant data. In this study, we examine whether we can enhance domain-specific causal discovery for time series using a data-driven approach. Our findings indicate that this procedure significantly outperforms human-designed, domain-agnostic causal discovery methods, such as Mutual Information, VAR-LiNGAM, and Granger Causality on the MOS 6502 microprocessor, the NetSim fMRI dataset, and the Dream3 gene dataset. We argue that, when feasible, the causality field should consider a supervised approach in which domain-specific CD procedures are learned from extensive datasets with known causal relationships, rather than being designed by human specialists. Our findings promise a new approach toward improving CD in neural and medical data and for the broader machine learning community.

Keywords

Cite

@article{arxiv.2209.05598,
  title  = {Learning domain-specific causal discovery from time series},
  author = {Xinyue Wang and Konrad Paul Kording},
  journal= {arXiv preprint arXiv:2209.05598},
  year   = {2023}
}

Comments

16 main pages, 7 figures. Accepted by TMLR

R2 v1 2026-06-28T01:10:06.844Z