Laryngeal features are phonetically abstract : mismatch negativity evidence from Arabic, English, and Russian

2016-2017 > Academic research: refereed > Publication in refereed journal201804_a bcmaVersion of RecordPublishe

The Status of Coronals in Standard American English . An Optimality-Theoretic Account

Coronals are very special sound segments. There is abundant evidence from various fields of phonetics which clearly establishes coronals as a class of consonants appropriate for phonological analysis. The set of coronals is stable across varieties of English unlike other consonant types, e.g. labials and dorsals, which are subject to a greater or lesser degree of variation. Coronals exhibit stability in inventories crosslinguistically, but they simultaneously display flexibility in alternations, i.e. assimilation, deletion, epenthesis, and dissimilation, when it is required by the contradictory forces of perception and production. The two main, opposing types of alternation that coronals in SAE participate in are examined. These are weakening phenomena, i.e. assimilation and deletion, and strengthening phenomena, i.e. epenthesis and dissimilation. Coronals are notorious for their contradictory behavior, especially in alternations. This type of behavior can be accounted for within a phonetically grounded OT framework that unites both phonetic and phonological aspects of alternations. Various sets of inherently conflicting FAITHFULNESS and MARKEDNESS constraints that are needed for an OT analysis of SAE alternations are intoduced

Loanword adaptation as first-language phonological perception

We show that loanword adaptation can be understood entirely in terms of phonological and phonetic comprehension and production mechanisms in the first language. We provide explicit accounts of several loanword adaptation phenomena (in Korean) in terms of an Optimality-Theoretic grammar model with the same three levels of representation that are needed to describe L1 phonology: the underlying form, the phonological surface form, and the auditory-phonetic form. The model is bidirectional, i.e., the same constraints and rankings are used by the listener and by the speaker. These constraints and rankings are the same for L1 processing and loanword adaptation

Voice characteristics in smith–magenis syndrome: An acoustic study of laryngeal biomechanics

Smith–Magenis syndrome (SMS) is a rare genetic disease characterized by intellectual disability, serious behavior disorders, neurodevelopment delay, and speech and language disorders. An acoustic and biomechanical analysis of the voice of SMS young adults was carried out due to (a) the close relationship between the laryngeal biomechanics and the clinical and emotional state of a person; (b) the fact that no research on the voice in this syndrome has been conducted previously. The vocal timbre of most people diagnosed with SMS does not seem to be according to the complexion of diagnosed individuals, nor to their gender and age, so it could be interesting to attend the analysis of phonation of people with a rare genetic syndrome such as SMS. We used BioMetPhon, a specific piece of software to analyze the glottal source and biomechanics of vocals folds. Nineteen features related to dysphonia, physiology, and biomechanics of the vocal folds were considered. The adult phonation of 9 individuals with SMS was analyzed and compared to 100 normative male and female adult voices. Results showed that the phonation of the SMS group significantly deviates from the adult normophonic profile in more than one of the 19 features examined, such as stiffness of the thyroarytenoid muscle and dynamic mass of the vocal fold cover, among othersThis research was funded by grant TEC2016-77791-C4-4-R (Plan Nacional de I+D+i, Ministry of Economic Affairs and Competitiveness of Spain

Economy of Effort or Maximum Rate of Information? Exploring Basic Principles of Articulatory Dynamics

Economy of effort, a popular notion in contemporary speech research, predicts that dynamic extremes such as the maximum speed of articulatory movement are avoided as much as possible and that approaching the dynamic extremes is necessary only when there is a need to enhance linguistic contrast, as in the case of stress or clear speech. Empirical data, however, do not always support these predictions. In the present study, we considered an alternative principle: maximum rate of information, which assumes that speech dynamics are ultimately driven by the pressure to transmit information as quickly and accurately as possible. For empirical data, we asked speakers of American English to produce repetitive syllable sequences such as wawawawawa as fast as possible by imitating recordings of the same sequences that had been artificially accelerated and to produce meaningful sentences containing the same syllables at normal and fast speaking rates. Analysis of formant trajectories shows that dynamic extremes in meaningful speech sometimes even exceeded those in the nonsense syllable sequences but that this happened more often in unstressed syllables than in stressed syllables. We then used a target approximation model based on a mass-spring system of varying orders to simulate the formant kinematics. The results show that the kind of formant kinematics found in the present study and in previous studies can only be generated by a dynamical system operating with maximal muscular force under strong time pressure and that the dynamics of this operation may hold the solution to the long-standing enigma of greater stiffness in unstressed than in stressed syllables. We conclude, therefore, that maximum rate of information can coherently explain both current and previous empirical data and could therefore be a fundamental principle of motor control in speech production

Constraint-based phonology

Phonology is the systematic study of the sounds used in language, their internal structure, and their composition into syllables, words and phrases. Computational phonology is the application of formal and computational techniques to the representation and processing of phonological information. This chapter will present the fundamentals of descriptive phonology along with a brief overview of computational phonology. 1 Phonological contrast, the phoneme, and distinctive features There is no limit to the number of distinct sounds that can be produced by the human vocal apparatus. However, this infinite variety is harnessed by human languages into sound systems consisting of a few dozen language-specific categories, or phonemes. An example of an English phoneme is t. English has a variety of t-like sounds, such as the aspirated th of ten the unreleased t�of net, and the flapped of water (in some dialects). In English, these distinctions are not used to differentiate words, and so we do not find pairs of English words which are identical but for their use of th versus t�. (By comparison, in some other languages, such as Icelandic and Bengali, aspiration is contrastive.) Nevertheless, since these sounds (or phones, or segments) are phonetically similar, and since they occur in complementary distributio