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Autore principale: Suzuki, Joe
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2601.11815
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author Suzuki, Joe
author_facet Suzuki, Joe
contents Causal discovery based on Independent Component Analysis (ICA) has achieved remarkable success through the LiNGAM framework, which exploits non-Gaussianity and independence of noise variables to identify causal order. However, classical LiNGAM methods rely on the strong assumption that there exists an ordering under which the noise terms are exactly independent, an assumption that is often violated in the presence of confounding. In this paper, we propose a general information-theoretic framework for causal order estimation that remains applicable under arbitrary confounding. Rather than imposing independence as a hard constraint, we quantify the degree of confounding by the multivariate mutual information among the noise variables. This quantity is decomposed into a sum of mutual information terms along a causal order and is estimated using Bayesian marginal likelihoods. The resulting criterion can be interpreted as Bayesian ICA for causal discovery, where causal order selection is formulated as a model selection problem over permutations. Under standard regularity conditions, we show that the proposed Bayesian mutual information estimator is consistent, with redundancy of order $O(\log n)$. To avoid non-identifiability caused by Gaussian noise, we employ non-Gaussian predictive models, including multivariate $t$ distributions, whose marginal likelihoods can be evaluated via MCMC. The proposed method recovers classical LiNGAM and DirectLiNGAM as limiting cases in the absence of confounding, while providing a principled ranking of causal orders when confounding is present. This establishes a unified, confounding-aware, and information-theoretically grounded extension of ICA-based causal discovery.
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spellingShingle Bayesian ICA for Causal Discovery
Suzuki, Joe
Information Theory
Causal discovery based on Independent Component Analysis (ICA) has achieved remarkable success through the LiNGAM framework, which exploits non-Gaussianity and independence of noise variables to identify causal order. However, classical LiNGAM methods rely on the strong assumption that there exists an ordering under which the noise terms are exactly independent, an assumption that is often violated in the presence of confounding. In this paper, we propose a general information-theoretic framework for causal order estimation that remains applicable under arbitrary confounding. Rather than imposing independence as a hard constraint, we quantify the degree of confounding by the multivariate mutual information among the noise variables. This quantity is decomposed into a sum of mutual information terms along a causal order and is estimated using Bayesian marginal likelihoods. The resulting criterion can be interpreted as Bayesian ICA for causal discovery, where causal order selection is formulated as a model selection problem over permutations. Under standard regularity conditions, we show that the proposed Bayesian mutual information estimator is consistent, with redundancy of order $O(\log n)$. To avoid non-identifiability caused by Gaussian noise, we employ non-Gaussian predictive models, including multivariate $t$ distributions, whose marginal likelihoods can be evaluated via MCMC. The proposed method recovers classical LiNGAM and DirectLiNGAM as limiting cases in the absence of confounding, while providing a principled ranking of causal orders when confounding is present. This establishes a unified, confounding-aware, and information-theoretically grounded extension of ICA-based causal discovery.
title Bayesian ICA for Causal Discovery
topic Information Theory
url https://arxiv.org/abs/2601.11815