Exact or approximate inference in graphical models: why the choice is dictated by the treewidth, and how variable elimination can be exploited
FRANC, Alain
Biodiversité, Gènes & Communautés [BioGeCo]
from patterns to models in computational biodiversity and biotechnology [PLEIADE]
< Réduire
Biodiversité, Gènes & Communautés [BioGeCo]
from patterns to models in computational biodiversity and biotechnology [PLEIADE]
Langue
en
Article de revue
Ce document a été publié dans
Australian and New Zealand Journal of Statistics. 2019-06-06, vol. 61, n° 2, p. 89-133
Wiley
Résumé en anglais
Probabilistic graphical models offer a powerful framework to account for the dependence structure between variables, which is represented as a graph. However, the dependence between variables may render inference tasks ...Lire la suite >
Probabilistic graphical models offer a powerful framework to account for the dependence structure between variables, which is represented as a graph. However, the dependence between variables may render inference tasks intractable. In this paper, we review techniques exploiting the graph structure for exact inference, borrowed from optimisation and computer science. They are built on the principle of variable elimination whose complexity is dictated in an intricate way by the order in which variables are eliminated. The so‐called treewidth of the graph characterises this algorithmic complexity: low‐treewidth graphs can be processed efficiently. The first point that we illustrate is therefore the idea that for inference in graphical models, the number of variables is not the limiting factor, and it is worth checking the width of several tree decompositions of the graph before resorting to the approximate method. We show how algorithms providing an upper bound of the treewidth can be exploited to derive a ‘good' elimination order enabling to realise exact inference. The second point is that when the treewidth is too large, algorithms for approximate inference linked to the principle of variable elimination, such as loopy belief propagation and variational approaches, can lead to accurate results while being much less time consuming than Monte‐Carlo approaches. We illustrate the techniques reviewed in this article on benchmarks of inference problems in genetic linkage analysis and computer vision, as well as on hidden variables restoration in coupled Hidden Markov Models.< Réduire
Mots clés en anglais
Marginalisation
Mode evaluation
Message passing
Computational inference
Variational approximations
Project ANR
Décomposition de Modèles Graphiques - ANR-16-CE40-0028
Origine
Importé de halUnités de recherche