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An efficient algorithm for computing interventional distributions in latent variable causal models

An efficient algorithm for computing interventional distributions in latent variable causal models
An efficient algorithm for computing interventional distributions in latent variable causal models
Probabilistic inference in graphical models is the task of computing marginal and conditional densities of interest from a factorized representation of a joint probability distribution. Inference algorithms such as variable elimination and belief propagation take advantage of constraints embedded in this factorization to compute such densities efficiently. In this paper, we propose an algorithm which computes interventional distributions in latent variable causal models represented by acyclic directed mixed graphs (ADMGs). To compute these distributions efficiently, we take advantage of a recursive factorization which generalizes the usual Markov factorization for DAGs and the more recent factorization for ADMGs. Our algorithm can be viewed as a generalization of variable elimination to the mixed graph case. We show our algorithm is exponential in the mixed graph generalization of tree width.
978-0-9749039-7-2
661-670
AUAI Press
Shpitser, Ilya
4d295b9b-39e8-417f-b38d-fbb5d7df6992
Richardson, Thomas S.
228fd45e-64e1-4470-a758-7e006734c942
Robins, James M.
0e5e9784-83a8-4c38-a533-99faf43e24e8
Cozman, Fabio Gagliardi
Pfeffer, Avi
Shpitser, Ilya
4d295b9b-39e8-417f-b38d-fbb5d7df6992
Richardson, Thomas S.
228fd45e-64e1-4470-a758-7e006734c942
Robins, James M.
0e5e9784-83a8-4c38-a533-99faf43e24e8
Cozman, Fabio Gagliardi
Pfeffer, Avi

Shpitser, Ilya, Richardson, Thomas S. and Robins, James M. (2011) An efficient algorithm for computing interventional distributions in latent variable causal models. Cozman, Fabio Gagliardi and Pfeffer, Avi (eds.) In Proceedings of the Twenty Seventh Conference on Uncertainty in Artificial Intelligence (UAI-11). AUAI Press. pp. 661-670 .

Record type: Conference or Workshop Item (Paper)

Abstract

Probabilistic inference in graphical models is the task of computing marginal and conditional densities of interest from a factorized representation of a joint probability distribution. Inference algorithms such as variable elimination and belief propagation take advantage of constraints embedded in this factorization to compute such densities efficiently. In this paper, we propose an algorithm which computes interventional distributions in latent variable causal models represented by acyclic directed mixed graphs (ADMGs). To compute these distributions efficiently, we take advantage of a recursive factorization which generalizes the usual Markov factorization for DAGs and the more recent factorization for ADMGs. Our algorithm can be viewed as a generalization of variable elimination to the mixed graph case. We show our algorithm is exponential in the mixed graph generalization of tree width.

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Published date: 2011
Organisations: Statistics

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Local EPrints ID: 350580
URI: http://eprints.soton.ac.uk/id/eprint/350580
ISBN: 978-0-9749039-7-2
PURE UUID: dc3f2430-24eb-404d-99a8-335fb7fda1e0

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Date deposited: 08 Apr 2013 10:44
Last modified: 14 Mar 2024 13:27

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Contributors

Author: Ilya Shpitser
Author: Thomas S. Richardson
Author: James M. Robins
Editor: Fabio Gagliardi Cozman
Editor: Avi Pfeffer

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