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dc.contributor.authorPérez Martínez, Aritz
dc.contributor.authorInza Cano, Iñaki ORCID
dc.contributor.authorLozano Alonso, José Antonio
dc.date.accessioned2014-05-08T10:46:23Z
dc.date.available2014-05-08T10:46:23Z
dc.date.issued2014-05-08T10:46:23Z
dc.identifier.urihttp://hdl.handle.net/10810/12361
dc.description.abstractThe learning of probability distributions from data is a ubiquitous problem in the fields of Statistics and Artificial Intelligence. During the last decades several learning algorithms have been proposed to learn probability distributions based on decomposable models due to their advantageous theoretical properties. Some of these algorithms can be used to search for a maximum likelihood decomposable model with a given maximum clique size, k, which controls the complexity of the model. Unfortunately, the problem of learning a maximum likelihood decomposable model given a maximum clique size is NP-hard for k > 2. In this work, we propose a family of algorithms which approximates this problem with a computational complexity of O(k · n^2 log n) in the worst case, where n is the number of implied random variables. The structures of the decomposable models that solve the maximum likelihood problem are called maximal k-order decomposable graphs. Our proposals, called fractal trees, construct a sequence of maximal i-order decomposable graphs, for i = 2, ..., k, in k − 1 steps. At each step, the algorithms follow a divide-and-conquer strategy based on the particular features of this type of structures. Additionally, we propose a prune-and-graft procedure which transforms a maximal k-order decomposable graph into another one, increasing its likelihood. We have implemented two particular fractal tree algorithms called parallel fractal tree and sequential fractal tree. These algorithms can be considered a natural extension of Chow and Liu’s algorithm, from k = 2 to arbitrary values of k. Both algorithms have been compared against other efficient approaches in artificial and real domains, and they have shown a competitive behavior to deal with the maximum likelihood problem. Due to their low computational complexity they are especially recommended to deal with high dimensional domains.es
dc.language.isoenges
dc.relation.ispartofseriesEHU-KZAA-TR;2014-07
dc.rightsinfo:eu-repo/semantics/openAccesses
dc.subjectapproximating probability distributionses
dc.subjectdecomposable modelses
dc.subjectbounded clique sizees
dc.subjectmaximum likelihood problemes
dc.subjectefficient algorithmses
dc.subjectChow and Liu's algorithmes
dc.titleEfficient learning of decomposable models with a bounded clique sizees
dc.typeinfo:eu-repo/semantics/reportes
dc.departamentoesCiencia de la computación e inteligencia artificiales_ES
dc.departamentoeuKonputazio zientziak eta adimen artifizialaes_ES


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