8,303 research outputs found
A convolutional neural-network model of human cochlear mechanics and filter tuning for real-time applications
Auditory models are commonly used as feature extractors for automatic
speech-recognition systems or as front-ends for robotics, machine-hearing and
hearing-aid applications. Although auditory models can capture the biophysical
and nonlinear properties of human hearing in great detail, these biophysical
models are computationally expensive and cannot be used in real-time
applications. We present a hybrid approach where convolutional neural networks
are combined with computational neuroscience to yield a real-time end-to-end
model for human cochlear mechanics, including level-dependent filter tuning
(CoNNear). The CoNNear model was trained on acoustic speech material and its
performance and applicability were evaluated using (unseen) sound stimuli
commonly employed in cochlear mechanics research. The CoNNear model accurately
simulates human cochlear frequency selectivity and its dependence on sound
intensity, an essential quality for robust speech intelligibility at negative
speech-to-background-noise ratios. The CoNNear architecture is based on
parallel and differentiable computations and has the power to achieve real-time
human performance. These unique CoNNear features will enable the next
generation of human-like machine-hearing applications
A Novel Windowing Technique for Efficient Computation of MFCC for Speaker Recognition
In this paper, we propose a novel family of windowing technique to compute
Mel Frequency Cepstral Coefficient (MFCC) for automatic speaker recognition
from speech. The proposed method is based on fundamental property of discrete
time Fourier transform (DTFT) related to differentiation in frequency domain.
Classical windowing scheme such as Hamming window is modified to obtain
derivatives of discrete time Fourier transform coefficients. It has been
mathematically shown that the slope and phase of power spectrum are inherently
incorporated in newly computed cepstrum. Speaker recognition systems based on
our proposed family of window functions are shown to attain substantial and
consistent performance improvement over baseline single tapered Hamming window
as well as recently proposed multitaper windowing technique
Syllable classification using static matrices and prosodic features
In this paper we explore the usefulness of prosodic features for
syllable classification. In order to do this, we represent the
syllable as a static analysis unit such that its acoustic-temporal
dynamics could be merged into a set of features that the SVM
classifier will consider as a whole. In the first part of our
experiment we used MFCC as features for classification,
obtaining a maximum accuracy of 86.66%. The second part of
our study tests whether the prosodic information is
complementary to the cepstral information for syllable
classification. The results obtained show that combining the
two types of information does improve the classification, but
further analysis is necessary for a more successful
combination of the two types of features
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