Strukturní a temporální vlastnosti konsonantických intervalů u předškolních dětí / Structural and temporal attributes of consonantal intervals in pre-school children

Kropíková, Alena

January 2013

The aim of this diploma thesis is to describe the realizations of consonant clusters in an age- homogenous group of Czech-speaking children. The theoretical part of this thesis deals with the syllable and consonant clusters as language universals, as well as with the syllable structure and consonant clusters in Czech. Furthermore, some theories of speech acquisition which take combinations of segments and forming of syllable structure in children's speech into account are also presented. A number of studies in consonant cluster acquisition is also summarized. The practical part of this work consists of an experiment in which consonant clusters in 16 typically developing Czech children aged 3;8-4;9 ( x = 4,4) were analysed. Eleven various two-element consonant clusters were selected according to their frequency of occurrence in the corpus of written Czech. Clusters were placed in 30 real words and 30 pseudowords - the pseudowords had the same structure as real words. Imitation was used as a elicitation method. Pictures were used only as complementary elements. The entire sample consisted of 461 consonant clusters realized in real words and 464 clusters realized in pseudowords. We described the structure of the target consonant clusters (i.e. manner and quality/accuracy of realizations) and their...

Identifikace mluvčího v temporální doméně řeči / Speaker identification in the temporal domain of speech

Weingartová, Lenka

January 2015

This thesis aims to thoroughly describe the temporal characteristics of spoken Czech by means of phone durations and their changes under the influence of several prosodic and segmental factors, such as position in a higher unit (syllable, word or prosodic phrase), length of the higher unit, segmental environment, structure of the syllable or phrase-final lengthening. The speech material comes from a semi-spontaneous corpus of scripted dialogues comprising 4046 utterances by 34 speakers. The descriptions are afterwards used for the creation of a rule-based temporal model, which provides a baseline for analysing local articulation rate contours and their speaker-specificity. The results indicate, that systematic speaker-specific differences can be found in the segmental domain, as well as in the temporal contours. Moreover, speaker identification potential of articulation rate and global temporal features is also assessed. Keywords: temporal characteristics, temporal modelling, phone duration, speaker identification, Czech

Modelled response of the electrically stimulated human auditory nerve fibre

Smit, Jacoba Elizabeth

18 September 2008

This study determined whether the Hodgkin-Huxley model for unmyelinated nerve fibres could be more comprehensively modified to predict excitation behaviour at Ranvier nodes of a human sensory nerve fibre, as specifically applied to the prediction of temporal characteristics of the human auditory system. The model was developed in three phases. Firstly, the Hodgkin-Huxley model was modified to describe action potential dynamics at Ranvier nodes using recorded ionic membrane current data from single human myelinated peripheral nerve fibres. A nerve fibre cable model, based on a combination of two existing models, was subsequently developed using human sensory nerve fibre morphometric data. Lastly the morphological parameters of the nerve fibre model were changed to resemble a Type I peripheral auditory nerve fibre and coupled to a volume-conduction model of the cochlea. This study is the first to show that the Hodgkin-Huxley model equations can be modified successfully to predict excitation behaviour of a generalised human peripheral sensory nerve fibre without using the Goldman-Hodgkin-Katz equations. The model includes a more comprehensive establishment of temperature dependence of the physiological and electrical parameters compared to existing models. Two versions of the human Type I auditory nerve fibre model were developed, one simulating an undamaged (non-degenerate) fibre and another a damaged (degenerate) fibre. Comparison between predicted and measured results indicated similar transient and persistent sodium, as well as slow potassium ionic membrane currents to those found in generalised sensory nerve fibres. Results confirm that chronaxie, rheobase current, mean latency, threshold and relative refractive periods depend on the amount of degeneracy of fibres. The model could account for threshold differences observed between different asymmetric waveforms. The combination of persistent sodium and slow potassium ionic membrane currents could in part predict non-monotonic excitation behaviour observed experimentally. A simplified method was developed to calculate electrically evoked compound action potential responses following neural excitation. It provided a computationally effective way to obtain an estimate of profile widths from the output of models that calculate neural excitation profiles, and an indirect way to estimate stimulus attenuation by calculating the value of the parameter that produces the best fit to experimental data. Results also confirmed that electrode arrays located closer to the modiolus produce more focussed neural excitation spread than more laterally located arrays. / Thesis (PhD)--University of Pretoria, 2010. / Electrical, Electronic and Computer Engineering / unrestricted

Evoked compound action potential

Computational model

Human

Auditory nerve fibre

Generalised sensory nerve fibre

Hodgkin-huxley model

Temporal characteristics

Strength-duration time constant

Ionic membrane currents

Conduction velocity

UCTD