Somerset: Association for Computational Linguistics.Ĭyran, E., and E. Third meeting of the ACL special interest group in computational phonology: Proceedings of the workshop, ed. Stochastic phonological grammars and acceptability. Salford: European Studies Research Institute, University of Salford.Ĭoleman, J., and J. In Current trends in phonology: Models and methods 1, eds. Declarative syllabification in Tashlhit Berber. Cambridge: Cambridge University Press.Ĭoleman, J.S. 1: Between the grammar and physics of speech, eds. The role of the sonority cycle in core syllabification. Phonology Yearbook 2: 225–252.Ĭlements, G. Cambridge: Cambridge University Press.Ĭhomsky, N., and M. Katowice: Uniwersytet Śląski.Ĭhambers, J.K., and P. In Challenging tasks for psycholinguistics in the New Century, ed. Phonetic syllabification and morphological parsability: The case of prefixed words in Polish. Zeitschrift für Slawistik 49: 42–60.Ĭetnarowska, B., and M. Syllabification across a prefix-stem boundary in Polish: The role of semantic compositionality. Cambridge: Cambridge University Press.Ĭetnarowska, B., and M. Slavic prosody: Language change and phonological theory. Colombus, OH: Slavica Publishers.īethin, C.Y. Polish syllables: The role of prosody in phonology and morphology. Saarbruecken: University of Saarbruecken.īethin, C.Y. In Proceedings of the 16th international congress of phonetic sciences, Saarbrücken, 6–, eds. Intersegmental cohension and syllable division in Polish. Does a theory of language need a grammar? Evidence from Hebrew root structure. What we know about what we have never heard: Evidence for perceptual illusions. Selective visual streaming in face recognition: Evidence from developmental prosopagnosia. Cambridge: Cambridge University Press.īentin, S., L.Y. Analyzing linguistic data: A practical introduction to statistics using R, 2nd ed. Journal of Memory and Language 59 (4): 390–412.īaayen, H. Mixed-effects modeling with crossed random effects for subjects and items. (HairerSoft, Kenilworth, UK version 2.1, 1523 User reference guide for v1.4, Hairer 2009). The findings contribute to the ongoing discussion on sources of phonotactic knowledge, underlying a feature-based composition of clusters, and conflicting forces related to place and manner features in online processing and intuitive judgement.Īmadeus Pro software. bilabial–velar, bilabial–palatal, dental–velar) involves the least cognitive effort, and lends support to the principle of the clarity of perception. ![]() Reaction times are the longest for medial distances, and the shortest for large distances. ![]() In turn, response latencies are facilitated by the place of articulation distances. First, it is shown that sonority and existence affect only accuracy rates, and do not contribute to the processing of word-edge phonotactics. The studies offer new data for Polish phonotactics, from which the following conclusions are drawn. For each experiment, two types of data were collected: accuracy rates and response latencies. The concept of distance is represented by the proximity of places of articulation on a scale bilabial – labio-dental – dental – alveolar – alveolo-palatal – palatal – velar. Well-formedness is associated with the sonority profile of CC clusters, which is either sonority-violating or sonority-obeying following the hierarchy: plosive–affricate–fricative–nasal–liquid–glide. Existence distinguishes between clusters which are part of the phonotactic inventory of Polish, and which are hypothetical. Two reaction time experiments explore the psycholinguistic reality of three factors: (1) existence, (2) well- formedness and (3) distance in word-initial clusters (Experiment 1) and in word-final clusters (Experiment 2). This chapter discusses the role of phonological principles in online processing of CC phonotactics in Polish.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |