AbstractProbabilistic inference and maximum a posteriori (MAP) explanation are two important and related problems on Bayesian belief networks. Both problems are known to be NP-hard for both approximation and exact solution. In 1997, Dagum and Luby showed that efficiently approximating probabilistic inference is possible for belief networks in which all probabilities are bounded away from 0. In this paper, we show that the corresponding result for MAP explanation does not hold: finding, or approximating, MAPs for belief networks remains NP-hard for belief networks with probabilities bounded within the range [l,u] for any 0⩽l<0.5<u⩽1. Our results cover both deterministic and randomized approximation
AbstractA number of exact algorithms have been developed in recent years to perform probabilistic in...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) problem i...
AbstractProbabilistic inference and maximum a posteriori (MAP) explanation are two important and rel...
AbstractFinding maximum a posteriori (MAP) assignments, also called Most Probable Explanations, is a...
AbstractApproximating the inference probability Pr[X = x | E = e] in any sense, even for a single ev...
Approximating the inference probability Pr[X = xjE = e] in any sense, even for a single evidence nod...
MAP is the problem of finding a most probable instantiation of a set of variables given evidence. MA...
Computation of marginal probabilities in Bayesian Belief Networks is central to many probabilistic r...
\u3cp\u3eThis paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bay...
This paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bayesian net...
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...
The problem of finding the most probable explanation to a designated set of vari-ables given partial...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) prob-lem ...
AbstractA number of exact algorithms have been developed in recent years to perform probabilistic in...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) problem i...
AbstractProbabilistic inference and maximum a posteriori (MAP) explanation are two important and rel...
AbstractFinding maximum a posteriori (MAP) assignments, also called Most Probable Explanations, is a...
AbstractApproximating the inference probability Pr[X = x | E = e] in any sense, even for a single ev...
Approximating the inference probability Pr[X = xjE = e] in any sense, even for a single evidence nod...
MAP is the problem of finding a most probable instantiation of a set of variables given evidence. MA...
Computation of marginal probabilities in Bayesian Belief Networks is central to many probabilistic r...
\u3cp\u3eThis paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bay...
This paper presents new results for the (partial) maximum a posteriori (MAP) problem in Bayesian net...
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...
The problem of finding the most probable explanation to a designated set of vari-ables given partial...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) prob-lem ...
AbstractA number of exact algorithms have been developed in recent years to perform probabilistic in...
Multi-dimensional Bayesian networks (MBCs) have been recently shown to perform efficient classificat...
This paper strengthens the NP-hardness result for the (partial) maximum a posteriori (MAP) problem i...