Add to ORKGThe sparse linear model has seen many successful applications in Statistics, Machine Learning, and Computational Biology, such as identification of gene regulatory networks from micro-array expression data. Prior work has either approximated Bayesian inference by expensive Markov chain Monte Carlo, or replaced it by point estimation. We show how to obtain a good approximation to Bayesian analysis efficiently, using the Expectation Propagation method. We also address the problems of optimal design and hyperparameter estimation. We demonstrate our framework on a gene network identification task
Expectation propagation (EP) is a novel variational method for approximate Bayesian inference, which...
Differential equations have been established to model the dynamic behavior of gene regulatory networ...
Abstract. We present a framework for efficient, accurate approximate Bayesian inference in generaliz...
The sparse linear model has seen many successful applications in Statistics, Machine Learning, and C...
The sparse linear model has seen many successful applications in Statistics, Machine Learning, and C...
The linear model with sparsity-favouring prior on the coefficients has important applications in man...
The linear model with sparsity-favouring prior on the coefficients has important applications in man...
Background: Identifying large gene regulatory networks is an important task, while the acquisition o...
<p><b>Copyright information:</b></p><p>Taken from "Experimental design for efficient identification ...
<p><b>Copyright information:</b></p><p>Taken from "Experimental design for efficient identification ...
Sparse linear models are cornerstones of applied statistics, embodying fundamental ideas such as fea...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Expectation propagation (EP) is a novel variational method for approximate Bayesian inference, which...
Differential equations have been established to model the dynamic behavior of gene regulatory networ...
Abstract. We present a framework for efficient, accurate approximate Bayesian inference in generaliz...
The sparse linear model has seen many successful applications in Statistics, Machine Learning, and C...
The sparse linear model has seen many successful applications in Statistics, Machine Learning, and C...
The linear model with sparsity-favouring prior on the coefficients has important applications in man...
The linear model with sparsity-favouring prior on the coefficients has important applications in man...
Background: Identifying large gene regulatory networks is an important task, while the acquisition o...
<p><b>Copyright information:</b></p><p>Taken from "Experimental design for efficient identification ...
<p><b>Copyright information:</b></p><p>Taken from "Experimental design for efficient identification ...
Sparse linear models are cornerstones of applied statistics, embodying fundamental ideas such as fea...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Bayesian sparse factor analysis has many applications; for example, it has been applied to the probl...
Expectation propagation (EP) is a novel variational method for approximate Bayesian inference, which...
Differential equations have been established to model the dynamic behavior of gene regulatory networ...
Abstract. We present a framework for efficient, accurate approximate Bayesian inference in generaliz...