Abstract: Classical dynamic Bayesian networks (DBNs) are based on the homogeneous Markov assumption and cannot deal with non-homogeneous temporal processes. Various approaches to relax the homogeneity assumption have recently been proposed. The present paper presents a combination of a Bayesian network with conditional probabilities in the linear Gaussian family, and a Bayesian multiple changepoint process, where the number and location of the changepoints are sampled from the posterior distribution with MCMC. Our work improves four aspects of an earlier conference paper: it contains a comprehensive and self-contained exposition of the methodology; it discusses the problem of spurious feedback loops in network reconstruction; it contains a ...
International audienceDynamic Bayesian networks (DBN) are a popular framework for managing uncertain...
This paper considers dynamic Bayesian networks for discrete and continuous variables. We only treat ...
In statistical genomics and systems biology non-homogeneous dynamic Bayesian networks (NH-DBNs) have...
Classical dynamic Bayesian networks (DBNs) are based on the homogeneous Markov assumption and cannot...
In the topical field of systems biology there is considerable interest in learning regulatory networ...
To relax the homogeneity assumption of classical dynamic Bayesian networks (DBNs), various recent st...
Since the regulatory relationship between genes is usually non-stationary, the homogeneity assumptio...
For the purpose of the further wide application of dynamic Bayesian networks (DBNs) to many real com...
In this paper, we revisit the parameter learning problem, namely the estimation of model parameters ...
To relax the homogeneity assumption of classical dynamic Bayesian networks (DBNs), various recent st...
For many clinical problems in patients the underlying pathophysiological process changes in the cour...
Motivation: Non-homogeneous dynamic Bayesian networks (NH-DBNs) are a popular tool for learning netw...
Dynamic Bayesian networks (DBNs) provide a versatile method for predictive, whole-of-systems modelli...
Non-homogeneous dynamic Bayesian network models (NH-DBNs) have become popular statistical tools for ...
International audienceDynamic Bayesian networks (DBN) are a popular framework for managing uncertain...
This paper considers dynamic Bayesian networks for discrete and continuous variables. We only treat ...
In statistical genomics and systems biology non-homogeneous dynamic Bayesian networks (NH-DBNs) have...
Classical dynamic Bayesian networks (DBNs) are based on the homogeneous Markov assumption and cannot...
In the topical field of systems biology there is considerable interest in learning regulatory networ...
To relax the homogeneity assumption of classical dynamic Bayesian networks (DBNs), various recent st...
Since the regulatory relationship between genes is usually non-stationary, the homogeneity assumptio...
For the purpose of the further wide application of dynamic Bayesian networks (DBNs) to many real com...
In this paper, we revisit the parameter learning problem, namely the estimation of model parameters ...
To relax the homogeneity assumption of classical dynamic Bayesian networks (DBNs), various recent st...
For many clinical problems in patients the underlying pathophysiological process changes in the cour...
Motivation: Non-homogeneous dynamic Bayesian networks (NH-DBNs) are a popular tool for learning netw...
Dynamic Bayesian networks (DBNs) provide a versatile method for predictive, whole-of-systems modelli...
Non-homogeneous dynamic Bayesian network models (NH-DBNs) have become popular statistical tools for ...
International audienceDynamic Bayesian networks (DBN) are a popular framework for managing uncertain...
This paper considers dynamic Bayesian networks for discrete and continuous variables. We only treat ...
In statistical genomics and systems biology non-homogeneous dynamic Bayesian networks (NH-DBNs) have...