Abbas Nasri; Gholamhosain Karimi doustan
Abstract
How the brain encodes the speech acoustic signal into phonological representations is a fundamental question for the neurobiology of language. The following paper is aimed to investigate ...
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How the brain encodes the speech acoustic signal into phonological representations is a fundamental question for the neurobiology of language. The following paper is aimed to investigate the relationship between the phonological and phonetic properties of Persian simple vowels and neurophysiological events corresponding to them. To achieve such goal, we employed electroencephalography to map the Persian vowel system onto cortical sources using the N1 auditory evoked component. We found evidence that the N1 is characterized by asymmetrical indexes in the auditory areas of the cortex, structuring vowel representations. Properties of these ERPs were analyzed and modelled on one hand by the landmarks in the spectral window of their respective stimulus (such as F1, F2 and F2-F1) and on the other hand by the phonological distinctive features categorizing them (namely, height and place). The results revealed that the responses contain at least two distinguishable modulations of N1 components: a symmetric N1a which peaked between 113 to 149 milliseconds after the onset of the stimulus and a heavily left-leaning N1b which peaked between 149 to 170 milliseconds thereafter. Both N1a and N1b subcomponents showed strong correlations with a variety of parameters of both phonological and acoustic nature of the respective stimuli. However, N1a was significantly better modelled by acoustic factors while N1b displayed a better fit to a model based on phonetic factors. Based on such results, this paper argues that firstly the perceptual procedure of vowel categorization is a gradient process starting from demarcation of the stimulus signal according to acoustic landmarks which is done almost symmetrically then the processing load shifts significantly to the left hemisphere for the categorization of the input based on its perceived distinctive features. And secondly, that such information can be exploited to draft a ‘tonochronic’ map of such perceptual processes and define a perceptual field for every vowel and distinctive feature in the tonochronic space.