ライフサイエンスコーパス: utterance

1 ng) from the coded meaning of the linguistic utterance.

2 e goal, meaning, and affective subtext of an utterance.

3 h typically involving one to three words per utterance.

4 intensity, for example, the loudness of the utterance.

5 eded to interpret the intended meaning of an utterance.

6 as correlates with the sound envelope of the utterances.

7 isomorphism in the mapping from meanings to utterances.

8 se these predictions to monitor the upcoming utterances.

9 sk of recovering intended meaning from noisy utterances.

10 imized for processing meaningful conspecific utterances.

11 s) that describe the acceptable structure of utterances.

12 ironic comments or interpreting non-literal utterances.

13 the production of increasingly refined vocal utterances.

14 cing study of participant ratings of officer utterances.

15 back perturbations applied to two classes of utterances: (1) those that fell nearer to the category b

16 endency length is actually minimized in real utterances across many languages; previous work has focu

17 d with the repetition of the nonsense speech utterance "ah-wah." This speech task involved the recrui

18 ction (full contextual applicability) of the utterance and actively engaged the subject in learning (

19 e resting lip shape from articulation of the utterances and accounted for 17.2% of the total variance

20 as significant in discriminating between the utterances and accounted for 72.8% of the total variance

21 k-specific processes (including attention to utterances and attempts to overcome pre-response conflic

22 ith speakers making predictions of their own utterances and comprehenders making predictions of other

23 Alterations occurred in 56% of interpreted utterances and included additions, omissions, substituti

24 oal), repetitiveness (recurrent behaviors or utterances), and rigidity (emphasis on fidelity and inva

25 , such as syntactic complexity and length of utterance, and decreased by changes in perception, such

26 t it means for speakers to predict their own utterances, and how prediction during production can be

27 onal turns, parent verbal responses to child utterances, and words produced by parents in 3 different

28 henders making predictions of other people's utterances at different linguistic levels.

29 dition, in which speakers repeated the study utterances at test, and a "different sentence" condition

30 el linguistic features resulting from verbal utterances could aid diagnosis of patients with probable

31 vements, can lead to illusory agency over VB utterances even though the participant does not speak.

32 y meetings, physicians should speak in short utterances (fewer than 20 words) and ask interpreters to

33 rammars to parse all of the unique multiword utterances from transcriptions of separate recordings of

34 to five synthesized CVC_CV (e.g., /dad_da/) utterances have been examined using information-theoreti

35 e plausible meaning is close to the observed utterance in terms of the number of edits; (ii) this pro

36 ed, adjusted, and shifted the signs in their utterances in conversationally appropriate rejoinders.

37 c role for the cerebellum in enabling fluent utterances in persons who stutter.

38 the place of words, and function as complete utterances in their own right.

39 a listener's ability to predict a speaker's utterance increases such neural coupling between speaker

40 sound when language is generated before any utterance is produced or heard.

41 that is part of the ability to construct new utterances minimally requires a 'context-free' grammar t

42 nce even the earliest and most simple verbal utterances must have increased the versatility of vocal

43 arning linguistic biomarkers from the verbal utterances of elderly individuals could help the clinica

44 pecific role of the cerebellum in the fluent utterances of persons who stutter.

45 the nature of sequencing of subgoals during utterance planning in language production.

46 of amplitude-frequency combinations in human utterances predicts both the structure of the chromatic

47 roca's area correlates with the sound of the utterances produced.

48 yses of how visible bodily action is used in utterance production is reexplained.

49 She was unable to track multisyllabic utterances reliably and was insensitive to vision when i

50 For a bilingual human, every utterance requires a choice about which language to use.

51 am correlates with the sound envelope of the utterances, starting before any sound is produced and ev

52 production or comprehension of single speech utterances such as syllables, words, or sentences.

53 ecognize familiar human voices from variable utterances, suggesting the acquisition of speech-invaria

54 Humans regularly produce new utterances that are understood by other members of the s

55 he vowel sound and playing back the modified utterance to the subject through headphones.

56 -modulation was imposed on target and masker utterances to enhance perceptual fusion between the two

57 ted the fundamental frequency of their later utterances toward the stimulus voice.

58 Longer utterances were associated with more alterations.

59 ware of the overall meaning of the speaker's utterance without the need to direct attention to indivi