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bnlearn (version 4.6.1)

structure-learning: Structure learning algorithms

Description

Overview of the structure learning algorithms implemented in bnlearn, with the respective reference publications.

Arguments

Available Constraint-Based Learning Algorithms

  • PC (pc.stable), a modern implementation of the first practical constraint-based structure learning algorithm.

    Colombo D, Maathuis MH (2014). "Order-Independent Constraint-Based Causal Structure Learning". Journal of Machine Learning Research, 15:3921--3962.

  • Grow-Shrink (gs): based on the Grow-Shrink Markov Blanket, the first (and simplest) Markov blanket detection algorithm used in a structure learning algorithm.

    Margaritis D (2003). Learning Bayesian Network Model Structure from Data. Ph.D. thesis, School of Computer Science, Carnegie-Mellon University, Pittsburgh, PA.

  • Incremental Association (iamb): based on the Markov blanket detection algorithm of the same name, which is based on a two-phase selection scheme (a forward selection followed by an attempt to remove false positives).

    Tsamardinos I, Aliferis CF, Statnikov A (2003). "Algorithms for Large Scale Markov Blanket Discovery". Proceedings of the Sixteenth International Florida Artificial Intelligence Research Society Conference, 376--381.

  • Fast Incremental Association (fast.iamb): a variant of IAMB which uses speculative stepwise forward selection to reduce the number of conditional independence tests.

  • Interleaved Incremental Association (inter.iamb): another variant of IAMB which uses forward stepwise selection to avoid false positives in the Markov blanket detection phase.

    Yaramakala S, Margaritis D (2005). "Speculative Markov Blanket Discovery for Optimal Feature Selection". Proceedings of the Fifth IEEE International Conference on Data Mining, 809--812.

  • Incremental Association with FDR (iamb.fdr): a variant of IAMB which adjusts the tests significance threshold with FDR.

    Pena JM (2008). "Learning Gaussian Graphical Models of Gene Networks with False Discovery Rate Control". Proceedings of the Sixth European Conference on Evolutionary Computation, Machine Learning and Data Mining in Bioinformatics, 165--176.

    Gasse M, Aussem A, Elghazel H (2014). "A Hybrid Algorithm for Bayesian Network Structure Learning with Application to Multi-Label Learning". Expert Systems with Applications, 41(15):6755--6772.

bnlearn includes two implementations of each algorithm: a vanilla implementation, and a parallel one that requires a running cluster set up with the makeCluster function from the parallel package.

Available Score-based Learning Algorithms

  • Hill-Climbing (hc): a hill climbing greedy search that explores the space of the directed acyclic graphs by single-arc addition, removal and reversals; with random restarts to avoid local optima. The optimized implementation uses score caching, score decomposability and score equivalence to reduce the number of duplicated tests.

  • Tabu Search (tabu): a modified hill-climbing able to escape local optima by selecting a network that minimally decreases the score function.

    Russell SJ, Norvig P (2009). Artificial Intelligence: A Modern Approach. Prentice Hall, 3rd edition.

Available Hybrid Learning Algorithms

  • Max-Min Hill-Climbing (mmhc): a hybrid algorithm which combines the Max-Min Parents and Children algorithm (to restrict the search space) and the Hill-Climbing algorithm (to find the optimal network structure in the restricted space).

    Tsamardinos I, Brown LE, Aliferis CF (2006). "The Max-Min Hill-Climbing Bayesian Network Structure Learning Algorithm". Machine Learning, 65(1):31--78.

  • Restricted Maximization (rsmax2): a general implementation of the Sparse Candidate algorithms, which can use any combination of constraint-based and score-based algorithms.

    Friedman N, Nachman I, Pe'er D (1999). "Learning Bayesian Network Structure from Massive Datasets: the Sparse Candidate Algorithm." Proceedings of the Fifteenth Conference on Uncertainty in Artificial Intelligence (UAI), 206--215.

  • Hybrid HPC (h2pc): a hybrid algorithm combining HPC and hill-climbing.

    Gasse M, Aussem A, Elghazel H (2014). "A Hybrid Algorithm for Bayesian Network Structure Learning with Application to Multi-Label Learning". Expert Systems with Applications, 41(15):6755--6772.

Other (Constraint-Based) Local Discovery Algorithms

These algorithms learn the structure of the undirected graph underlying the Bayesian network, which is known as the skeleton of the network. Therefore by default all arcs are undirected, and no attempt is made to detect their orientation. They are often used in hybrid learning algorithms.

  • Max-Min Parents and Children (mmpc): a forward selection technique for neighbourhood detection based on the maximization of the minimum association measure observed with any subset of the nodes selected in the previous iterations.

    Tsamardinos I, Aliferis CF, Statnikov A (2003). "Time and Sample Efficient Discovery of Markov Blankets and Direct Causal Relations". Proceedings of the Ninth ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, 673--678.

  • Hiton Parents and Children (si.hiton.pc): a fast forward selection technique for neighbourhood detection designed to exclude nodes early based on the marginal association. The implementation follows the Semi-Interleaved variant of the algorithm.

    Aliferis FC, Statnikov A, Tsamardinos I, Subramani M, Koutsoukos XD (2010). "Local Causal and Markov Blanket Induction for Causal Discovery and Feature Selection for Classification Part I: Algorithms and Empirical Evaluation". Journal of Machine Learning Research, 11:171--234.

  • Hybrid Parents and Children (hpc): an algorithm building on iamb.fdr to learn the parents and children of each node like mmpc and si.hiton.pc. The reference publication is the same as that for Hybrid HPC.

Pairwise Mutual Information Algorithms

These algorithms learn approximate network structures using only pairwise mutual information.

  • Chow-Liu (chow.liu): an application of the minimum-weight spanning tree and the information inequality. It learns the tree structure closest to the true one in the probability space.

    Chow CK, Liu CN (1968). "Approximating Discrete Probability Distributions with Dependence Trees", IEEE Transactions on Information Theory, IT-14 3:462--467.

  • ARACNE (aracne): an improved version of the Chow-Liu algorithm that is able to learn polytrees.

    Margolin AA, Nemenman I, Basso K, Wiggins C, Stolovitzky G, Dalla Favera R, Califano A (2006). "ARACNE: An Algorithm for the Reconstruction of Gene Regulatory Networks in a Mammalian Cellular Context". BMC Bioinformatics, 7(Suppl 1):S7.

All these algorithms have two implementations (vanilla and parallel) like other constraint-based algorithms.