ライフサイエンスコーパス: acoustical

1 ical, use-wear, taphonomic, experimental and acoustical analyses, we demonstrate that these objects w

2 We find that the frequency dependence of acoustical and physiological interaural delays are match

3 loped a combined approach including optical, acoustical, and electrophysiological techniques to enabl

4 This review examines the acoustical basis of auditory motion perception and a wid

5 th higher frequencies, better control of the acoustical beam, and tests in media with higher rates of

6 CD-based optico-acoustical biosensor (OAB) was used for detection of var

7 communicate identity, engage other birds in acoustical combat, and attract mates.

8 Acoustical comparison between free and phagocytosed micr

9 ditory brightness perception under realistic acoustical conditions.

10 e effects of intelligibility from underlying acoustical confounds.

11 d representation of the speech envelope, the acoustical cue that provides syllable pattern informatio

12 These observations rule out simple acoustical cues as a basis for voice selectivity in the

13 level differences (ILDs), one of the primary acoustical cues for sound location.

14 ing loss (i.e., conductive; CHL) can distort acoustical cues needed for spatial hearing, which depend

15 What are the acoustical cues that carry these different types of voca

16 itory pathway that is involved in processing acoustical cues to sound location.

17 nt over earphones stimuli containing all the acoustical cues to the location of broadband stimuli and

18 is to encode a correlate of ILDs, one of the acoustical cues to the spatial location of sound.

19 That ability relies on sensitivity to acoustical cues-particularly interaural time and level d

20 voice even when accounting for a variety of acoustical cues.

21 known to attract cetacean strandings produce acoustical "Dead Zones" where echolocation signals are s

22 rmed by the auditory pathway from an initial acoustical encoding to higher level cognition.

23 ding a near-ubiquitous transformation of the acoustical environment due to the propagation of anthrop

24 d species, exposure to a naturalistic social-acoustical environment during development has a profound

25 Because the acoustical environment is a critical ecological dimensio

26 ource of periodic sound stimuli in the human acoustical environment, shows that the probability distr

27 Detailed information on the acoustical environmental quality (including sound levels

28 the auditory cortex adapts to noisy, complex acoustical environments by strengthening inhibitory circ

29 cortex, but less is known about how the rich acoustical environments experienced by vocal communicato

30 ion remains flexible in the face of changing acoustical environments, pointing to rapid interactions

31 or encoding sound information across varying acoustical environments.

32 d living sheep was exposed to the sinusoidal acoustical excitation of 40-90dB SPL, in the frequency r

33 Many mechanical and acoustical factors have been proposed to account for thi

34 We briefly discuss acoustical feature selectivity and invariance in the cen

35 speech decrease with age; (2) whether other acoustical features associated with child-directed speec

36 culturally specific, learned features, or if acoustical features can reliably distinguish them.

37 h age; and, (3) the relative contribution of acoustical features in predicting child's age.

38 functional groups that divided the space of acoustical features into regions that represent cues for

39 nditions that yielded the precedence effect, acoustical features known to evoke neuronal discharges w

40 suggests that binaural neurons are tuned to acoustical features of ecological environments, rather t

41 se subjective ratings to style of origin and acoustical features of the chords as well as musical sop

42 We first show that the acoustical features of the LFH call do not differ betwee

43 ditory chimeras", which preserved subsets of acoustical features of the vocal sounds.

44 requires a memory for vocalizers to identify acoustical features.

45 Acoustical geographic variation is common in widely dist

46 (PT) symmetry can be constructed in optical-acoustical hybrid modes, where Brillouin scattering-indu

47 , when combined with the processing of other acoustical information (e.g., timbre or auditory scenes)

48 illates at small amplitude in the absence of acoustical input.

49 ransmitting properties of song, avoidance of acoustical interference with other species, and random p

50 cal observation with a high-speed camera and acoustical interrogation of individual bubbles and cells

51 we construct a global mechanical-electrical-acoustical mathematical model of the cochlea based on a

52 ogist may not understand the finer points of acoustical measurement.

53 ty of vibrating systems, whether mechanical, acoustical, optical, or quantum.

54 re calcium carbonate components of the stato-acoustical organ responsible for hearing and maintenance

55 ion results in progressive changes to speech acoustical outputs that serve to correct for the perturb

56 urthermore mutant mice showed alterations in acoustical parameters of ultrasonic vocalizations, which

57 frequency optical phonons and heat carrying acoustical phonons.

58 elays in cochlear processing, as well as the acoustical properties of sound sources in the natural en

59 This implies that the acoustical properties of the voice (e.g., pitch) are ver

60 rances transfer across languages and whether acoustical properties play a similar role in driving per

61 Conversely, the acoustical properties that listeners pay attention to wh

62 Based on objective acoustical properties, chords can be situated on a disso

63 hat behave as effective materials with novel acoustical properties.

64 In acoustical recordings, we found that interaural delay va

65 s prefrontal processes that are sensitive to acoustical regularities rather than the bottom-up encodi

66 ed for in-vitro and in-vivo investigation of acoustical response of sheep's middle-ear ossicles.

67 bles and cells, we assessed the physical and acoustical responses of both phagocytosed and free micro

68 Wearable acoustical sensors and related monitoring systems can be

69 is paper reviews recent advances in wearable acoustical sensors for medical applications.

70 It has been shown that the acoustical signal of posed laughter can convey affective

71 s from sound to generate an auditory map for acoustical signal processing.

72 hrough the environment, sum to form a single acoustical signal.

73 larvae and pupae employ complex chemical and acoustical signals to manipulate ants.

74 of neural responses in increasingly complex acoustical situations, including spectrum variations, no

75 mposium held at the June 2006 meeting of the Acoustical Society of America, and illustrate some of th

76 s, opposite to the correlation observed with acoustical stimulation.

77 ined by the statistical relationship between acoustical stimuli and their naturally occurring sources

78 essentially silent when presented with other acoustical stimuli.

79 , indicating that either an electrical or an acoustical stimulus evoked a forward travelling wave.

80 d intracellular calcium response elicited by acoustical streaming induced shear stress under various

81 We investigate how intelligibility and acoustical structure affect acoustic and linguistic neur

82 ts categorize into call types based on their acoustical structure and behavioral context.

83 e-frequency scales that best represented the acoustical structure in zebra finch song, we concluded t

84 sound into frequency bands and preserved the acoustical structure present in the original song with v

85 th neuroimaging and only weakly to low-level acoustical structure.

86 n and community science, radar analyses, and acoustical studies, birds are thought to stop singing an

87 We developed a simple computer-based acoustical test that has allowed us to subdivide AP poss

88 at sounds is believed to benefit mainly from acoustical training [2].

89 ps and provides a bridge between optical and acoustical trapping.

90 recently developed technique of single-beam acoustical tweezers to trap microbubbles, an important c

91 song from speech than a broad range of other acoustical variables, suggesting that spectro-temporal m

92 use light whose frequency is modulated by an acoustical wave.

93 ings provide us an enhanced understanding of acoustical-wave scattering and lead potentially to wides

94 If the acoustical waveforms from a real sound source are reprod

95 , e.g., polarized waves in electromagnetism, acoustical waves and matter waves in quantum mechanics.

96 the intensity of infrared light rather than acoustical waves.