Title :
Learning Graphical Model Parameters with Approximate Marginal Inference
Author_Institution :
NICTA, Australia Nat. Univ., Canberra, ACT, Australia
Abstract :
Likelihood-based learning of graphical models faces challenges of computational complexity and robustness to model misspecification. This paper studies methods that fit parameters directly to maximize a measure of the accuracy of predicted marginals, taking into account both model and inference approximations at training time. Experiments on imaging problems suggest marginalization-based learning performs better than likelihood-based approximations on difficult problems where the model being fit is approximate in nature.
Keywords :
approximation theory; computational complexity; inference mechanisms; learning (artificial intelligence); solid modelling; approximate marginal inference; computational complexity; graphical model parameter learning; inference approximations; likelihood-based approximations; likelihood-based learning; marginalization-based learning; model misspecification; Approximation algorithms; Entropy; Function approximation; Markov processes; Optimization; Vectors; Graphical models; conditional random fields; inference; machine learning; segmentation; Algorithms; Artificial Intelligence; Computer Simulation; Models, Statistical; Pattern Recognition, Automated; Reproducibility of Results; Sensitivity and Specificity; Subtraction Technique;
Journal_Title :
Pattern Analysis and Machine Intelligence, IEEE Transactions on
DOI :
10.1109/TPAMI.2013.31
