TY - CONF AB - The accuracy of automatic speech recognition systems in noisy and reverberant environments can be improved notably by exploiting the uncertainty of the estimated speech features using so-called uncertainty-of-observation techniques. In this paper, we introduce a new Bayesian decision rule that can serve as a mathematical framework from which both known and new uncertainty-of-observation techniques can be either derived or approximated. The new decision rule in its direct form leads to the new significance decoding approach for Gaussian mixture models, which results in better performance compared to standard uncertainty-of-observation techniques in different additive and convolutive noise scenarios. AU - Abdelaziz, Ahmed H. AU - Zeiler, Steffen AU - Kolossa, Dorothea AU - Leutnant, Volker AU - Haeb-Umbach, Reinhold ID - 11716 KW - Bayes methods KW - Gaussian processes KW - convolution KW - decision theory KW - decoding KW - noise KW - reverberation KW - speech coding KW - speech recognition KW - Bayesian decision rule KW - GMM KW - Gaussian mixture models KW - additive noise scenarios KW - automatic speech recognition systems KW - convolutive noise scenarios KW - decoding approach KW - mathematical framework KW - reverberant environments KW - significance decoding KW - speech feature estimation KW - uncertainty-of-observation techniques KW - Hidden Markov models KW - Maximum likelihood decoding KW - Noise KW - Speech KW - Speech recognition KW - Uncertainty KW - Uncertainty-of-observation KW - modified imputation KW - noise robust speech recognition KW - significance decoding KW - uncertainty decoding SN - 1520-6149 T2 - Acoustics, Speech and Signal Processing (ICASSP), 2013 IEEE International Conference on TI - GMM-based significance decoding ER -