Maximal ancestral graphs (MAGs) have many desirable properties; in particular they can fully describe conditional independences from directed acyclic graphs (DAGs) in the presence of latent and selection variables. However, different MAGs may encode the same conditional independences, and are said to be \emph{Markov equivalent}. Thus identifying necessary and sufficient conditions for equivalence is essential for structure learning. Several criteria for this already exist, but in this paper we give a new non-parametric characterization in terms of the heads and tails that arise in the parameterization for discrete models. We also provide a polynomial time algorithm ((2)O(ne2), where n and e are the number of vertices and edges respectively)...
Graphical models are popular statistical tools which are used to represent dependent or causal compl...
JiJi Zhang and Peter Spirtes. A Characterization of Markov Equivalence Classes for Ancestral Graphic...
In this thesis we describe subclasses of a class of graphs with three types of edges, called looples...
Ancestral graphs can encode conditional independence relations that arise in directed acyclic graph ...
Different directed acyclic graphs (DAGs) may be Markov equivalent in the sense that they entail the ...
Necessary and sufficient conditions for a maximal ancestral graph (MAnG) to be Markov equivalent to ...
Undirected graphs and acyclic digraphs (ADGs), as well as their mutual extension to chain graphs, ar...
The conditional independence structure induced on the observed marginal distribution by a hidden var...
When learning a directed acyclic graph (DAG) model via observational data, one generally cannot iden...
We present a graphical criterion for covariate adjustment that is sound and complete for four differ...
Enumerating the directed acyclic graphs (DAGs) of a Markov equivalence class (MEC) is an important p...
AbstractBayesian networks, equivalently graphical Markov models determined by acyclic digraphs or AD...
When learning a directed acyclic graph (DAG) model via observational data, one generally cannot iden...
© 2018 Elsevier B.V. DAG models are statistical models satisfying a collection of conditional indepe...
Graphical models are popular statistical tools which are used to represent dependent or causal compl...
Graphical models are popular statistical tools which are used to represent dependent or causal compl...
JiJi Zhang and Peter Spirtes. A Characterization of Markov Equivalence Classes for Ancestral Graphic...
In this thesis we describe subclasses of a class of graphs with three types of edges, called looples...
Ancestral graphs can encode conditional independence relations that arise in directed acyclic graph ...
Different directed acyclic graphs (DAGs) may be Markov equivalent in the sense that they entail the ...
Necessary and sufficient conditions for a maximal ancestral graph (MAnG) to be Markov equivalent to ...
Undirected graphs and acyclic digraphs (ADGs), as well as their mutual extension to chain graphs, ar...
The conditional independence structure induced on the observed marginal distribution by a hidden var...
When learning a directed acyclic graph (DAG) model via observational data, one generally cannot iden...
We present a graphical criterion for covariate adjustment that is sound and complete for four differ...
Enumerating the directed acyclic graphs (DAGs) of a Markov equivalence class (MEC) is an important p...
AbstractBayesian networks, equivalently graphical Markov models determined by acyclic digraphs or AD...
When learning a directed acyclic graph (DAG) model via observational data, one generally cannot iden...
© 2018 Elsevier B.V. DAG models are statistical models satisfying a collection of conditional indepe...
Graphical models are popular statistical tools which are used to represent dependent or causal compl...
Graphical models are popular statistical tools which are used to represent dependent or causal compl...
JiJi Zhang and Peter Spirtes. A Characterization of Markov Equivalence Classes for Ancestral Graphic...
In this thesis we describe subclasses of a class of graphs with three types of edges, called looples...