AbstractA number of exact algorithms have been developed in recent years to perform probabilistic inference in Bayesian belief networks. The techniques used in these algorithms are closely related to network structures, and some of them are not easy to understand and implement. We consider the problem from the combinatorial optimization point of view and state that efficient probabilistic inference in a belief network is a problem of finding an optimal factoring given a set of probability distributions. From this viewpoint, previously developed algorithms can be seen as alternative factoring strategies. In this paper, we define a combinatorial optimization problem, the optimal factoring problem, and discuss application of this problem in be...
Graduation date: 1999Probabilistic inference using Bayesian networks is now a well-established\ud ap...
Most learning algorithms assume that a data set is given initially. We address the com- mon situatio...
Approximating the inference probability Pr[X = xjE = e] in any sense, even for a single evidence nod...
AbstractA number of exact algorithms have been developed in recent years to perform probabilistic in...
AbstractCutset conditioning and clique-tree propagation are two popular methods for exact probabilis...
This paper shows how an efficient and parallel algorithm for inference in Bayesian Networks (BNs) ca...
Graduation date: 1999Bayesian networks are used for building intelligent agents that act under uncer...
AbstractApproximating the inference probability Pr[X = x | E = e] in any sense, even for a single ev...
This paper presents a Bayesian method for constructing probabilistic networks from databases. In par...
Computation of marginal probabilities in Bayesian Belief Networks is central to many probabilistic r...
Probabilistic reasoning with belief (Bayesian) networks is based on conditional probability matrices...
AbstractThe method of conditioning permits probabilistic inference in multiply connected belief netw...
Abstract Most learning algorithms assume that a data set is given initially. We address the common s...
AbstractThis article describes an algorithm that solves the problem of finding the K most probable c...
This thesis explores and compares different methods of optimizing queries in Bayesian networks. Baye...
Graduation date: 1999Probabilistic inference using Bayesian networks is now a well-established\ud ap...
Most learning algorithms assume that a data set is given initially. We address the com- mon situatio...
Approximating the inference probability Pr[X = xjE = e] in any sense, even for a single evidence nod...
AbstractA number of exact algorithms have been developed in recent years to perform probabilistic in...
AbstractCutset conditioning and clique-tree propagation are two popular methods for exact probabilis...
This paper shows how an efficient and parallel algorithm for inference in Bayesian Networks (BNs) ca...
Graduation date: 1999Bayesian networks are used for building intelligent agents that act under uncer...
AbstractApproximating the inference probability Pr[X = x | E = e] in any sense, even for a single ev...
This paper presents a Bayesian method for constructing probabilistic networks from databases. In par...
Computation of marginal probabilities in Bayesian Belief Networks is central to many probabilistic r...
Probabilistic reasoning with belief (Bayesian) networks is based on conditional probability matrices...
AbstractThe method of conditioning permits probabilistic inference in multiply connected belief netw...
Abstract Most learning algorithms assume that a data set is given initially. We address the common s...
AbstractThis article describes an algorithm that solves the problem of finding the K most probable c...
This thesis explores and compares different methods of optimizing queries in Bayesian networks. Baye...
Graduation date: 1999Probabilistic inference using Bayesian networks is now a well-established\ud ap...
Most learning algorithms assume that a data set is given initially. We address the com- mon situatio...
Approximating the inference probability Pr[X = xjE = e] in any sense, even for a single evidence nod...