Random Tessellation Forests
Abstract
Space partitioning methods such as random forests and the Mondrian process are powerful machine learning methods for multi-dimensional and relational data, and are based on recursively cutting a domain. The flexibility of these methods is often limited by the requirement that the cuts be axis aligned. The Ostomachion process and the self-consistent binary space partitioning-tree process were recently introduced as generalizations of the Mondrian process for space partitioning with non-axis aligned cuts in the two dimensional plane. Motivated by the need for a multi-dimensional partitioning tree with non-axis aligned cuts, we propose the Random Tessellation Process (RTP), a framework that includes the Mondrian process and the binary space partitioning-tree process as special cases. We derive a sequential Monte Carlo algorithm for inference, and provide random forest methods. Our process is self-consistent and can relax axis-aligned constraints, allowing complex inter-dimensional dependence to be captured. We present a simulation study, and analyse gene expression data of brain tissue, showing improved accuracies over other methods.
Keywords
Cite
@article{arxiv.1906.05440,
title = {Random Tessellation Forests},
author = {Shufei Ge and Shijia Wang and Yee Whye Teh and Liangliang Wang and Lloyd T. Elliott},
journal= {arXiv preprint arXiv:1906.05440},
year = {2019}
}
Comments
11 pages, 4 figures