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Auteurs principaux: Marchant, Roman, Draca, Dario, Francis, Gilad, Assadzadeh, Sahand, Varidel, Mathew, Iorfino, Frank, Cripps, Sally
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2501.05745
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author Marchant, Roman
Draca, Dario
Francis, Gilad
Assadzadeh, Sahand
Varidel, Mathew
Iorfino, Frank
Cripps, Sally
author_facet Marchant, Roman
Draca, Dario
Francis, Gilad
Assadzadeh, Sahand
Varidel, Mathew
Iorfino, Frank
Cripps, Sally
contents Learning the structure of Bayesian networks from data provides insights into underlying processes and the causal relationships that generate the data, but its usefulness depends on the homogeneity of the data population, a condition often violated in real-world applications. In such cases, using a single network structure for inference can be misleading, as it may not capture sub-population differences. To address this, we propose a novel approach of modelling a mixture of Bayesian networks where component probabilities depend on individual characteristics. Our method identifies both network structures and demographic predictors of sub-population membership, aiding personalised interventions. We evaluate our method through simulations and a youth mental health case study, demonstrating its potential to improve tailored interventions in health, education, and social policy.
format Preprint
id arxiv_https___arxiv_org_abs_2501_05745
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Covariate Dependent Mixture of Bayesian Networks
Marchant, Roman
Draca, Dario
Francis, Gilad
Assadzadeh, Sahand
Varidel, Mathew
Iorfino, Frank
Cripps, Sally
Machine Learning
Learning the structure of Bayesian networks from data provides insights into underlying processes and the causal relationships that generate the data, but its usefulness depends on the homogeneity of the data population, a condition often violated in real-world applications. In such cases, using a single network structure for inference can be misleading, as it may not capture sub-population differences. To address this, we propose a novel approach of modelling a mixture of Bayesian networks where component probabilities depend on individual characteristics. Our method identifies both network structures and demographic predictors of sub-population membership, aiding personalised interventions. We evaluate our method through simulations and a youth mental health case study, demonstrating its potential to improve tailored interventions in health, education, and social policy.
title Covariate Dependent Mixture of Bayesian Networks
topic Machine Learning
url https://arxiv.org/abs/2501.05745