Branches: Efficiently Seeking Optimal Sparse Decision Trees with AO*
Abstract
Decision Tree (DT) Learning is a fundamental problem in Interpretable Machine Learning, yet it poses a formidable optimisation challenge. Practical algorithms have recently emerged, primarily leveraging Dynamic Programming and Branch & Bound. However, most of these approaches rely on a Depth-First-Search strategy, which is inefficient when searching for DTs at high depths and requires the definition of a maximum depth hyperparameter. Best-First-Search was also employed by other methods to circumvent these issues. The downside of this strategy is its higher memory consumption, as such, it has to be designed in a fully efficient manner that takes full advantage of the problem's structure. We formulate the problem within an AND/OR graph search framework and we solve it with a novel AO*-type algorithm called Branches. We prove both optimality and complexity guarantees for Branches and we show that it is more efficient than the state of the art theoretically and on a variety of experiments. Furthermore, Branches supports non-binary features unlike the other methods, we show that this property can further induce larger gains in computational efficiency.
Cite
@article{arxiv.2406.02175,
title = {Branches: Efficiently Seeking Optimal Sparse Decision Trees with AO*},
author = {Ayman Chaouki and Jesse Read and Albert Bifet},
journal= {arXiv preprint arXiv:2406.02175},
year = {2025}
}
Comments
Proceedings of the 42nd International Conference on Machine Learning, Vancouver, Canada. PMLR 267, 2025