Differentiable Multi-Target Causal Bayesian Experimental Design
Abstract
We introduce a gradient-based approach for the problem of Bayesian optimal experimental design to learn causal models in a batch setting -- a critical component for causal discovery from finite data where interventions can be costly or risky. Existing methods rely on greedy approximations to construct a batch of experiments while using black-box methods to optimize over a single target-state pair to intervene with. In this work, we completely dispose of the black-box optimization techniques and greedy heuristics and instead propose a conceptually simple end-to-end gradient-based optimization procedure to acquire a set of optimal intervention target-state pairs. Such a procedure enables parameterization of the design space to efficiently optimize over a batch of multi-target-state interventions, a setting which has hitherto not been explored due to its complexity. We demonstrate that our proposed method outperforms baselines and existing acquisition strategies in both single-target and multi-target settings across a number of synthetic datasets.
Cite
@article{arxiv.2302.10607,
title = {Differentiable Multi-Target Causal Bayesian Experimental Design},
author = {Yashas Annadani and Panagiotis Tigas and Desi R. Ivanova and Andrew Jesson and Yarin Gal and Adam Foster and Stefan Bauer},
journal= {arXiv preprint arXiv:2302.10607},
year = {2023}
}
Comments
Camera-ready version ICML 2023