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Learning structurally consistent undirected probabilistic graphical models

Authors:

Sushmita Roy,

Terran Lane,

Margaret Werner-WashburneAuthors Info & Claims

ICML '09: Proceedings of the 26th Annual International Conference on Machine Learning

Pages 905 - 912

https://doi.org/10.1145/1553374.1553490

Published: 14 June 2009 Publication History

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Abstract

In many real-world domains, undirected graphical models such as Markov random fields provide a more natural representation of the statistical dependency structure than directed graphical models. Unfortunately, structure learning of undirected graphs using likelihood-based scores remains difficult because of the intractability of computing the partition function. We describe a new Markov random field structure learning algorithm, motivated by canonical parameterization of Abbeel et al. We provide computational improvements on their parameterization by learning per-variable canonical factors, which makes our algorithm suitable for domains with hundreds of nodes. We compare our algorithm against several algorithms for learning undirected and directed models on simulated and real datasets from biology. Our algorithm frequently outperforms existing algorithms, producing higher-quality structures, suggesting that enforcing consistency during structure learning is beneficial for learning undirected graphs.

References

[1]

Abbeel, P., Koller, D., & Ng, A. Y. (2006). Learning factor graphs in polynomial time and sample complexity. J. Mach. Learn. Res., 7, 1743--1788.

Digital Library

Google Scholar

[2]

Aragon, A. D., Rodriguez, A. L., Meirelles, O. et al. (2008). Characterization of differentiated quiescent and nonquiescent cells in yeast stationary-phase cultures. Mol. Biol. Cell, E07-07-0666+.

Google Scholar

[3]

Besag, J. (1977). Efficiency of pseudolikelihood estimation for simple gaussian fields. Biometrika, 64, 616--618.

Crossref

Google Scholar

[4]

Cover, T. M., & Thomas, J. A. (1991). Elements of information theory. New York, NY, USA: Wiley-Interscience.

Digital Library

Google Scholar

[5]

Friedman, N., Nachman, I., & Pe'er, D. (1999). Learning bayesian network structure from massive datasets: The sparse candidate algorithm. Uncertainty in Artificial Intelligence (pp. 206--215).

Digital Library

Google Scholar

[6]

Heckerman, D., Chickering, D. M., Meek, C., Rounthwaite, R., & Kadie, C. M. (2000). Dependency networks for inference, collaborative filtering, and data visualization. J. Mach. Learn. Res., 1, 49--75.

Digital Library

Google Scholar

[7]

Hofmann, R., & Tresp, V. (1998). Nonlinear markov networks for continuous variables. Advances in Neural Information Processing Systems (pp. 521--527). MIT Press.

Digital Library

Google Scholar

[8]

Lauritzen, S. L. (1996). Graphical models. Oxford Statistical Science Series. New York, USA: Oxford University Press.

Google Scholar

[9]

Lee, S.-I., Ganapathi, V., & Koller, D. (2007). Efficient structure learning of markov networks using l ₁-regularization. Advances in Neural Information Processing Systems 19 (pp. 817--824). MIT Press.

Google Scholar

[10]

Li, F., & Yang, Y. (2005). Using modified lasso regression to learn large undirected graphs in a probabilistic framework. American Association for Artificial Intelligence (pp. 801--806).

Digital Library

Google Scholar

[11]

Margolin, A., Nemenman, I., Basso, K. et al. (2005). Aracne: An algorithm for the reconstruction of gene regulatory networks in a mammalian cellular context. BMC Bioinformatics, (Suppl 1): S7.

Google Scholar

[12]

Paget, R. D. (1999). Nonparametric markov random field models for natural texture images. Doctoral dissertation, University of Queensland.

Google Scholar

[13]

Roy, S., Werner-Washburne, M., & Lane, T. (2008). A system for generating transcription regulatory networks with combinatorial control of transcription. Bioinformatics (Oxford, England), 1318--1320.

Digital Library

Google Scholar

[14]

Schmidt, M., Niculescu-Mizil, A., & Murphy, K. (2007). Learning graphical model structure using l1-regularization paths. 22nd international conference on Artificial Intelligence (pp. 1278--1283).

Digital Library

Google Scholar

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https://dl.acm.org/doi/10.1145/3398069
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Parida PMarwala TChakraverty S(2016)An Overview of Recent Advancements in Causal StudiesArchives of Computational Methods in Engineering10.1007/s11831-016-9168-124:2(319-335)Online publication date: 14-Jan-2016
https://doi.org/10.1007/s11831-016-9168-1
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Published In

ICML '09: Proceedings of the 26th Annual International Conference on Machine Learning

June 2009

1331 pages

ISBN:9781605585161

DOI:10.1145/1553374

General Chair:
Andrea Danyluk
Williams College
,
Program Chairs:
Léon Bottou
NEC Laboratories America
,
Michael Littman
Rutgers University

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Association for Computing Machinery

New York, NY, United States

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Published: 14 June 2009

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Microsoft Research

ICML '09: The 26th Annual International Conference on Machine Learning held in conjunction with the 2007 International Conference on Inductive Logic Programming

June 14 - 18, 2009

Quebec, Montreal, Canada

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Overall Acceptance Rate 140 of 548 submissions, 26%

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Thieme ABelgrave DDoherty G(2020)Machine Learning in Mental HealthACM Transactions on Computer-Human Interaction10.1145/339806927:5(1-53)Online publication date: 17-Aug-2020
https://dl.acm.org/doi/10.1145/3398069
Li CLi YWang CDong SGao HZhao QWu W(2020)The multimedia recommendation algorithm based on probability graphical modelMultimedia Tools and Applications10.1007/s11042-020-10129-881:14(19035-19050)Online publication date: 29-Oct-2020
https://doi.org/10.1007/s11042-020-10129-8
Parida PMarwala TChakraverty S(2016)An Overview of Recent Advancements in Causal StudiesArchives of Computational Methods in Engineering10.1007/s11831-016-9168-124:2(319-335)Online publication date: 14-Jan-2016
https://doi.org/10.1007/s11831-016-9168-1
Yeh HLiu YYeh CSoo V(2010)Identifying Prostate Cancer-Related Networks from Microarray Data Based on Genotype-Phenotype Networks Using Markov Blanket SearchProceedings of the 2010 IEEE International Conference on Bioinformatics and Bioengineering10.1109/BIBE.2010.64(302-303)Online publication date: 31-May-2010
https://dl.acm.org/doi/10.1109/BIBE.2010.64

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Neural variational inference and learning in undirected graphical models

Bayesian learning in undirected graphical models: approximate MCMC algorithms

A conditional independence algorithm for learning undirected graphical models

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