Presentations

Abstract

This study aims to test recent theoretical frameworks in speech motor control which claim that speech production targets are specified in auditory terms. According to such frameworks, people with better auditory acuity should have more precise speech targets. Participants performed speech perception and production tasks in a counterbalanced order. Speech perception acuity was assessed using an adaptive speech discrimination task, where participants discriminated between stimuli on a /ɪ/-/ɛ/ and a /ɑ/-/ɔ/ continuum. To assess variability in speech production, participants performed a pseudo-word reading task; formant values were measured for each recording of the vowels /ɪ/, /ɛ/, /ɑ/ and /ɔ/ in 288 pseudowords (18 per vowel, each of which was repeated 4 times). We predicted that speech production variability would correlate inversely with discrimination performance. Results confirmed this prediction as better discriminators had more distinctive vowel production targets. In addition, participants with higher auditory acuity produced vowels with smaller within-phoneme variability but spaced farther apart in vowel space. This study highlights the importance of individual differences in the study of speech motor control, and sheds light on speech production-perception interactions.

Abstract

This study aims to test a prediction of recent
theoretical frameworks in speech motor control: if
speech production targets are specified in auditory
terms, people with better auditory acuity should
have more precise speech targets.
To investigate this, we had participants perform
speech perception and production tasks in a
counterbalanced order. To assess speech perception
acuity, we used an adaptive speech discrimination
task. To assess variability in speech production,
participants performed a pseudo-word reading task;
formant values were measured for each recording.
We predicted that speech production variability to
correlate inversely with discrimination performance.
The results suggest that people do vary in their
production and perceptual abilities, and that better
discriminators have more distinctive vowel
production targets, confirming our prediction. This
study highlights the importance of individual
differences in the study of speech motor control, and
sheds light on speech production-perception
interaction.

Abstract

In investigations of feedback control during speech production, researchers have focused on two different kinds of responses to erroneous or unexpected auditory feedback. Compensation refers to online, feedback-based corrections of articulations. In contrast, adaptation refers to long-term changes in the speech production system after exposure to erroneous/unexpected feedback, which may last even after feedback is normal again. In the current study, we aimed to compare both types of feedback responses by investigating the conditions under which the system starts adapting in addition to merely compensating. Participants vocalized long vowels while they were exposed to either consistently altered auditory feedback, or to feedback that was unpredictably either altered or normal. Participants were not aware of the manipulation of auditory feedback. We predicted that both conditions would elicit compensation, whereas adaptation would be stronger when the altered feedback was consistent across trials. The results show that although there seems to be somewhat more adaptation for the consistently altered feedback condition, a substantial amount of individual variability led to statistically unreliable effects at the group level. The results stress the importance of taking into account individual differences and show that people vary widely in how they respond to altered auditory feedback.

Abstract

A recurring criticism in the field of psycholinguistics and is the lack of ecological validity of experimental designs. For example, many experiments on sentence comprehension are conducted enclosed booths, where sentences are presented word by word on a computer screen. In addition, very often participants are instructed to make judgments that relate directly to the experimental manipulation. Thus, the contexts in which these processes are studied is quite restricted, which calls into question the generalizability of the results to more naturalistic environments. A possible solution to this problem is the use of virtual reality (VR) in psycholinguistic experiments. By immersing participants into a virtual environment, ecological validity can be increased while experimental control is maintained.
In the current experiment we combine electroencephalography (EEG) and VR to look at semantic processing in a more naturalistic setting. During the experiment, participants move through a visually rich virtual restaurant. Tables and avatars are placed in the restaurant and participants are instructed to stop at each table and look at the object (e.g. a plate with a steak) in front of the avatar. Then, the avatar will produce an utterance to accompany the object (e.g. “I think this steak is very nice”), in which the noun will either match (e.g. steak) or mismatch (e.g. mandarin) with the item on the table. Based on previous research, we predict a modulation of the N400, which should be larger in the mismatch than the match condition. Implications of the use of virtual reality for experimental research will be discussed.

Abstract

Fluctuations in pupil size have been shown to reflect variations in processing demands during language
comprehension. Increases in pupil diameter have been observed as a consequence of syntactic anomalies
(Schluroff 1982), increased syntactic complexity (Just & Carpenter 1993) and lexical ambiguity (Ben-
Nun 1986). An issue that has not received attention is whether pupil size also varies due to pragmatic
manipulations. In a pupillometry experiment, we investigated whether pupil diameter is sensitive to
increased processing demands as a result of comprehending an indirect request versus a statement. During
natural conversation, communication is often indirect. For example, in an appropriate context, ''It'' cold in
here'' is a request to shut the window, rather than a statement about room temperature (Holtgraves 1994).
We tested 49 Dutch participants (mean age = 20.8). They were presented with 120 picture-sentence
combinations that could either be interpreted as an indirect request (a picture of a window with the
sentence ''it's hot here'') or as a statement (a picture of a window with the sentence ''it's nice here''). The
indirect requests were non-conventional, i.e. they did not contain directive propositional content and were
not directly related to the underlying felicity conditions (Holtgraves 2002). In order to verify that the
indirect requests were recognized, participants were asked to decide after each combination whether or
not they heard a request. Based on the hypothesis that understanding this type of indirect utterances
requires additional inferences to be made on the part of the listener (e.g., Holtgraves 2002; Searle 1975;
Van Ackeren et al. 2012), we predicted a larger pupil diameter for indirect requests than statements. The
data were analyzed using linear mixed-effects models in R, which allow for simultaneous inclusion of
participants and items as random factors (Baayen, Davidson, & Bates 2008). The results revealed a larger
mean pupil size and a larger peak pupil size for indirect requests as compared to statements. In line with
previous studies on pupil size and language comprehension (e.g., Just & Carpenter 1993), this difference
was observed within a 1.5 second window after critical word onset. We suggest that the increase in pupil
size reflects additional on-line processing demands for the comprehension of non-conventional indirect
requests as compared to statements. This supports the idea that comprehending this type of indirect
request requires capacity demanding inferencing on the part of the listener. In addition, this study
demonstrates the usefulness of pupillometry as a tool for experimental research in pragmatics.

Abstract

Fluctuations in pupil size have been shown to reflect variations in processing demands during language
comprehension. Increases in pupil diameter have been observed as a consequence of syntactic anomalies
(Schluroff 1982), increased syntactic complexity (Just & Carpenter 1993) and lexical ambiguity (Ben-
Nun 1986). An issue that has not received attention is whether pupil size also varies due to pragmatic
manipulations. In a pupillometry experiment, we investigated whether pupil diameter is sensitive to
increased processing demands as a result of comprehending an indirect request versus a statement. During
natural conversation, communication is often indirect. For example, in an appropriate context, ''It'' cold in
here'' is a request to shut the window, rather than a statement about room temperature (Holtgraves 1994).
We tested 49 Dutch participants (mean age = 20.8). They were presented with 120 picture-sentence
combinations that could either be interpreted as an indirect request (a picture of a window with the
sentence ''it's hot here'') or as a statement (a picture of a window with the sentence ''it's nice here''). The
indirect requests were non-conventional, i.e. they did not contain directive propositional content and were
not directly related to the underlying felicity conditions (Holtgraves 2002). In order to verify that the
indirect requests were recognized, participants were asked to decide after each combination whether or
not they heard a request. Based on the hypothesis that understanding this type of indirect utterances
requires additional inferences to be made on the part of the listener (e.g., Holtgraves 2002; Searle 1975;
Van Ackeren et al. 2012), we predicted a larger pupil diameter for indirect requests than statements. The
data were analyzed using linear mixed-effects models in R, which allow for simultaneous inclusion of
participants and items as random factors (Baayen, Davidson, & Bates 2008). The results revealed a larger
mean pupil size and a larger peak pupil size for indirect requests as compared to statements. In line with
previous studies on pupil size and language comprehension (e.g., Just & Carpenter 1993), this difference
was observed within a 1.5 second window after critical word onset. We suggest that the increase in pupil
size reflects additional on-line processing demands for the comprehension of non-conventional indirect
requests as compared to statements. This supports the idea that comprehending this type of indirect
request requires capacity demanding inferencing on the part of the listener. In addition, this study
demonstrates the usefulness of pupillometry as a tool for experimental research in pragmatics.

Abstract

A series of results from event-related brain potential recordings and fMRI research will be presented, suggesting that language processing does not obey strict compositionality, and, moreover immediately recruits extralinguistic information. It will also be shown that pragmatic inferences require contributions from TOM networks. This implies that an embodied account of semantics fails (under the somewhat strange assumption that the brain is not part of the body). I will put forward an embrained perspective on language processing.

Abstract

In my presentation I will summarize the results of a number of ERP and fMRI studies on the processing and integration of co-occurring speech and gestures/pantomimes. The ERP results indicate that the time course of integrating language and action (i.e., gesture) is very similar to that of integrating linguistic meaning into a sentence or discourse representation. Moreover, in both cases the Left Inferior Frontal cortex plays a central role in orchestrating the multimodal unification of language and action. This orchestration is partly done by modulating temporal areas that store representations activated by the input. I will discuss the parameters of this modulation.

Abstract

For over 20 years, researchers have investigated syntactic priming of transitives by measuring the frequency of sentence choice. These studies have shown syntactic priming for passives but weaker or absent syntactic priming for actives (e.g. [1],[2]). Until recently very few studies have reported syntactic priming by measuring reaction times of language production and none of these studies included transitive sentences. We previously found syntactic priming of both active and passive Dutch transitives in speech onsets, and interestingly the effect appeared to be stronger for actives than passives [3][4]. In order to explain the discrepancy between our results and other results reported in the literature, we hypothesized that there is a ceiling effect in the frequency of using an active transitive (in general about 94% of produced transitives are actives) but not in the speed of producing one. To confirm this hypothesis we conducted a syntactic priming experiment with a picture description task measuring both reaction times and the frequency of occurrence on the same trials. This way we could exclude the alternative explanation that the discrepancy in results is caused by differences in design or stimuli. The results of this experiment show syntactic priming effects for passives and not for actives in the frequency of occurrence (in line with the literature). However, the reaction times of producing these sentences do show syntactic priming for actives and these effects appear to be even stronger than for passives (in line with our previous data). In conclusion, our results suggest that measuring the frequency of occurrence is not enough to get a complete picture of syntactic priming. Measuring reaction times in addition to the frequency of occurrence could provide us with a more complete picture. References [1] Bock, K., & Loebell, H. (1990). Framing sentences. Cognition, 35, 1-39. [2] Hartsuiker, R. J., & Kolk, H. H. J. (1998). Syntactic persistence in Dutch sentence production. Language and Speech, 41, 143-184. [3] Menenti, L., Segaert, K., & Hagoort, P. (2008). Repetition suppression for syntax and semantics: overt speech in fMRI. Society for Neuroscience, Washington DC. [4] Segaert, K., Menenti, L., & Hagoort, P. (2009) Scanning speech with fMRI: Short and long term priming of syntax and verbs, CUNY conference on human sentence processing, Davis, CA.

Abstract

Syntactic priming has been frequently used to study syntactic processes in language production in monolinguals [1][2] and bilinguals [3]. In a previous study in language comprehension [4] we showed that passive sentences in English (the participant’s L2) can be primed by passive sentences in German (L1) and English (L2). This was manifested in faster reading times for target sentences and repetition suppression effects in left inferior frontal, left precentral and left middle temporal regions of interest in an fMRI study. However, syntactic priming in comprehension is complicated by the influence of verb repetition between prime and target [5][6]. Therefore, we conducted a reading time and fMRI study looking at the influence of verb repetition on syntactic priming. In this study of monolingual comprehension in Dutch we primed passive sentences as well as sentences with crossed-dependency structures. The reading time results revealed a syntactic priming effect for passive sentences, while the effect for crossed-dependency structure sentences interacted with the factor verb repetition. The preliminary fMRI results suggest that the repetition of passive structures leads to reductions in neural activity. The repetition of crossed dependency structures causes repetition enhancement, an increase in the BOLD response, an effect that interacts with the factor verb repetition. In conclusion, the influence of verb repetition on syntactic priming in comprehension is complex and seems to depend on the type of syntactic structure investigated. References [1] Bock K. (1986). Syntactic persistence in language production. Cognitive Psychology, 18(3), 355-387. [2] Pickering M, & Branigan H. (1999). Syntactic priming in language production. Trends in Cognitive Sciences, 3(4), 136-141. [3] Schoonbaert S, Hartsuiker RJ, & Pickering MJ. (2007). The representation of lexical and syntactic information in bilinguals: Evidence from syntactic priming. Journal of Memory and Language, 56(2), 153-171. [4] Weber K, & Indefrey P. (in press). Syntactic priming in German-English bilinguals during sentence comprehension. NeuroImage. [5] Arai M, van Gompel R, & Scheepers C. (2007). Priming ditransitive structures in comprehension. Cognitive Psychology, 54, 218-250. [6] Thothathiri M, & Snedeker J. (2008). Give and take: Syntactic priming during spoken language comprehension. Cognition, 108(1), 51-68.