High-Dimensional Causal Discovery Under non-Gaussianity
Abstract
We consider graphical models based on a recursive system of linear structural equations. This implies that there is an ordering, , of the variables such that each observed variable is a linear function of a variable specific error term and the other observed variables with . The causal relationships, i.e., which other variables the linear functions depend on, can be described using a directed graph. It has been previously shown that when the variable specific error terms are non-Gaussian, the exact causal graph, as opposed to a Markov equivalence class, can be consistently estimated from observational data. We propose an algorithm that yields consistent estimates of the graph also in high-dimensional settings in which the number of variables may grow at a faster rate than the number of observations, but in which the underlying causal structure features suitable sparsity; specifically, the maximum in-degree of the graph is controlled. Our theoretical analysis is couched in the setting of log-concave error distributions.
Cite
@article{arxiv.1803.11273,
title = {High-Dimensional Causal Discovery Under non-Gaussianity},
author = {Y. Samuel Wang and Mathias Drton},
journal= {arXiv preprint arXiv:1803.11273},
year = {2019}
}