\u3cp\u3eThis paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bayesian networks, which is the problem of querying the most probable state configuration of some of the network variables given evidence. It is demonstrated that the problem remains hard even in networks with very simple topology, such as binary polytrees and simple trees (including the Naive Bayes structure), which extends previous complexity results. Furthermore, a Fully Polynomial Time Approximation Scheme for MAP in networks with bounded treewidth and bounded number of states per variable is developed. Approximation schemes were thought to be impossible, but here it is shown otherwise under the assumptions just mentioned, which are adopted ...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
We present completeness results for inference in Bayesian networks with respect to two different par...
AbstractThis article describes an algorithm that solves the problem of finding the K most probable c...
This paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bayesian net...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) prob-lem ...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) problem i...
MAP is the problem of finding a most probable instantiation of a set of variables given evidence. MA...
AbstractFinding maximum a posteriori (MAP) assignments, also called Most Probable Explanations, is a...
The problem of finding the most probable explanation to a designated set of variables given partial ...
We study the computational complexity of finding maximum a posteriori configurations in Bayesian net...
AbstractOne of the key computational problems in Bayesian networks is computing the maximal posterio...
The MAP (maximum a posteriori hypothesis) problem in Bayesian networks is to find the most likely st...
The problem of finding the most probable explanation to a designated set of vari-ables given partial...
AbstractProbabilistic inference and maximum a posteriori (MAP) explanation are two important and rel...
Learning optimal Bayesian networks (BN) from data is NP-hard in general. Nevertheless, certain BN cl...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
We present completeness results for inference in Bayesian networks with respect to two different par...
AbstractThis article describes an algorithm that solves the problem of finding the K most probable c...
This paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bayesian net...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) prob-lem ...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) problem i...
MAP is the problem of finding a most probable instantiation of a set of variables given evidence. MA...
AbstractFinding maximum a posteriori (MAP) assignments, also called Most Probable Explanations, is a...
The problem of finding the most probable explanation to a designated set of variables given partial ...
We study the computational complexity of finding maximum a posteriori configurations in Bayesian net...
AbstractOne of the key computational problems in Bayesian networks is computing the maximal posterio...
The MAP (maximum a posteriori hypothesis) problem in Bayesian networks is to find the most likely st...
The problem of finding the most probable explanation to a designated set of vari-ables given partial...
AbstractProbabilistic inference and maximum a posteriori (MAP) explanation are two important and rel...
Learning optimal Bayesian networks (BN) from data is NP-hard in general. Nevertheless, certain BN cl...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
We present completeness results for inference in Bayesian networks with respect to two different par...
AbstractThis article describes an algorithm that solves the problem of finding the K most probable c...