Bayesian Averaging of Classifiers and the Overfitting Problem
ICML '00 Proceedings of the Seventeenth International Conference on Machine Learning
Pattern Classification (2nd Edition)
Pattern Classification (2nd Edition)
Feature importance in Bayesian assessment of newborn brain maturity from EEG
AIKED'10 Proceedings of the 9th WSEAS international conference on Artificial intelligence, knowledge engineering and data bases
A probabilistic expert system for predicting the risk of Legionella in evaporative installations
Expert Systems with Applications: An International Journal
Classification of electroencephalogram signals with combined time and frequency features
Expert Systems with Applications: An International Journal
Feature extraction from electroencephalograms for Bayesian assessment of newborn brain maturity
CBMS '11 Proceedings of the 2011 24th International Symposium on Computer-Based Medical Systems
CBMS '11 Proceedings of the 2011 24th International Symposium on Computer-Based Medical Systems
Confident Interpretation of Bayesian Decision Tree Ensembles for Clinical Applications
IEEE Transactions on Information Technology in Biomedicine
Computer Methods and Programs in Biomedicine
Hi-index | 12.05 |
EEG experts can assess a newborn's brain maturity by visual analysis of age-related patterns in sleep EEG. It is highly desirable to make the results of assessment most accurate and reliable. However, the expert analysis is limited in capability to provide the estimate of uncertainty in assessments. Bayesian inference has been shown providing the most accurate estimates of uncertainty by using Markov Chain Monte Carlo (MCMC) integration over the posterior distribution. The use of MCMC enables to approximate the desired distribution by sampling the areas of interests in which the density of distribution is high. In practice, the posterior distribution can be multimodal, and so that the existing MCMC techniques cannot provide the proportional sampling from the areas of interest. The lack of prior information makes MCMC integration more difficult when a model parameter space is large and cannot be explored in detail within a reasonable time. In particular, the lack of information about EEG feature importance can affect the results of Bayesian assessment of EEG maturity. In this paper we explore how the posterior information about EEG feature importance can be used to reduce a negative influence of disproportional sampling on the results of Bayesian assessment. We found that the MCMC integration tends to oversample the areas in which a model parameter space includes one or more features, the importance of which counted in terms of their posterior use is low. Using this finding, we proposed to cure the results of MCMC integration and then described the results of testing the proposed method on a set of sleep EEG recordings.