ライフサイエンスコーパス: octave

1 e dyads, triads, and tetrads within a single octave.

2 ferent frequencies, varying by as much as an octave.

3 to less than approximately one eighth of an octave.

4 , and 2.0 cpd and a spatial bandwidth of 1.0 octave.

5 e conditioning stimuli was < approximately 1 octave.

6 the octave and the cycle of notes within the octave.

7 anged from close to one octave to about 1/12 octave.

8 -frequency roll-off of approximately -8.4 dB/octave.

9 spatial or temporal frequency separation in octaves.

10 ide band of frequencies, spanning over three octaves.

11 ion, have wider frequency tuning than +/-1/6 octaves.

12 oss sounds that differed in frequency by two octaves.

13 frequency (BF) shifts downwards by about 0.5 octaves.

14 perceived distance in response to monaural 1 octave 4 kHz noise source sounds presented at distances

15 Versions are available in Octave and Java (with a graphical user interface).

16 was evaluated on spectral levels (one-third octave and one- twelfth octave band).

17 n the keyboard, these are illustrated by the octave and the cycle of notes within the octave.

18 d broad spectral tuning (approximately three octaves) and were excitatory in the contralateral ear, i

19 Common Lisp, Java, Python, Perl, MATLAB and Octave, and includes many features that facilitate adopt

20 e shifted downwards in frequency by nearly 1 octave, and the maximum phase lags amounted to only 180

21 t comb-like optical spectra spanning several octaves are a chief ingredient in the emerging field of

22 ng white-noise masking notch-filtered +/-1/6 octaves around the tone center frequencies.

23 substantially to DeltaCF approximately 0.62 octave at 24 weeks.

24 p misalignment of DeltaCF approximately 1.27 octaves at 6 weeks after overstimulation decreases subst

25 ctive noise profiles, based on decibel-A and octave band assessments.

26 SSwap in Experiment 3 used octave band noise (2-4, 4-8, 8-16, or 16-32 kHz) and sep

27 We used octave band noise (8--16 kHz) at three levels (106, 112,

28 A separate group of chimeras was exposed to octave band noise (8-16 kHz for 2 hours) 2 weeks after t

29 days before and 3 days after a 3 hour 4 kHz octave band noise at 117 dB (SPL).

30 ne plus tempol and exposed to 120 dB SPL one-octave band noise centered at 4 kHz for 5 h.

31 nts, CBA/CaJ mice were exposed to an intense octave band of noise (8-16 kHz) at 100 dB SPL for 2 hr,

32 The noise exposure was an 8kHz octave band of noise at 105dB SPL for 4h.

33 al levels (one-third octave and one- twelfth octave band).

34 The noise exposure (4-kHz octave band, 115 dB SPL, 5 h) created permanent threshol

35 ale guinea pigs were exposed to noise (4 kHz octave band, 115 dB SPL, 5 h).

36 udes comparable to those of responses to 1/3 octave band-pass noise.

37 ersonal noise measurements and environmental octave-band analyses were performed to divide subjects i

38 sing the decibel-A scale and at each of nine octave bands at each bedspace.

39 ed from 81.5-95.5 dB re 1 muPa for one-third octave bands from 63-500 Hz.

40 To date, octave bandwidth (25-50 THz) single-channel links have b

41 ) for both narrowband tonal carriers and two-octave bandwidth noise carriers in the auditory core of

42 ventional horn antennas over greater than an octave bandwidth with negligible loss and advance the st

43 en the mask was presented at approximately 1 octave below the test spatial frequency.

44 iments revealed, however, that the peak at 1 octave below the test was mediated by image size and/or

45 The OC motion at approximately 2-6 octaves below the characteristic frequency of the region

46 e of the compression mode at about one-third octave beyond the best frequency.

47 nm in these structures, we generated a multi-octave broadband SC spectrum ranging from 1.5 um-25 um a

48 re measured over headphones for STM (2cycles/octave density, 4-Hz rate) applied to an 85-dB SPL, 2-kH

49 multiple frequency bands (1) at exactly one octave distance from each other, (2) at multiple harmoni

50 Intriguingly, this "octave effect" not only occurs for physically presented

51 diffuser lens to 2.3 +/- 0.7 and 3.5 +/- 0.8 octaves for the intermediate and strongest diffuser lens

52 difference increased systematically from 0.6 octaves for the weakest diffuser lens to 2.3 +/- 0.7 and

53 s designed exhibiting a bandwidth of several octaves for use in both multi-band plasmonic resonance-e

54 The results confirmed that the peak at 1 octave from the test still occurred when the potential f

55 2) near stereoacuity decreased by at least 2 octaves from baseline, both assessed by a masked examine

56 pecific aspects of music perception (such as octave generalization), as well as studies that investig

57 n acuity adjusted for age was reduced by 1.2 octaves in isolated infantile nystagmus and by 1.7 to 2.

58 olated infantile nystagmus and by 1.7 to 2.5 octaves in nystagmus with associated sensory defect.

59 d diverse stimulus preferences spanning five octaves in spatial and temporal frequency.

60 In the OCTAVE Induction 1 and 2 trials, 598 and 541 patients, r

61 In the OCTAVE Induction 1 and 2 trials, the rates of overall in

62 In the OCTAVE Induction 1 trial, remission at 8 weeks occurred

63 8.2% in the placebo group (P=0.007); in the OCTAVE Induction 2 trial, remission occurred in 16.6% ve

64 ed to generalize to frequencies separated by octave intervals both lesser and greater than the CS.

65 ated music using pitch intervals that divide octaves into the 12 tones of the chromatic scale.

66 plain prominent perceptual phenomena such as octave invariance.

67 , 1.23+/-0.417 octaves; medium, 1.41+/-0.593 octaves; low, 1.52+/-0.475 octaves; mean +/- SD).

68 ponses in adult gerbils: BF was more than an octave lower, the steep slopes of the phase vs. frequenc

69 he pitch of IIRN[-] for the same delay is an octave lower.

70 a-broadband radiation (extending over more 5 octaves) making a great challenge to reach resolution li

71 ium, 1.41+/-0.593 octaves; low, 1.52+/-0.475 octaves; mean +/- SD).

72 of stimulus presentation (high, 1.23+/-0.417 octaves; medium, 1.41+/-0.593 octaves; low, 1.52+/-0.475

73 to pure tones of 2, 8, 16, or 32 kHz or half-octave noise bands centered on 2, 8, or 32 kHz at 80-120

74 localization of narrow-band (one-sixth of an octave) noise bursts presented from sources along the mi

75 nse of individual optical antennas across an octave of the visible to near-infrared spectrum.

76 ead to future on-chip circulators over multi-octaves of frequency.

77 s sensitive to and controllable by the super-octave optical field.

78 g acuity (across all five test ages) was 0.5 octave or better in 57% of eyes and 1.0 octave or better

79 (3.5-, 4.5-, and 5.5-year test ages) was 0.5 octave or better in 71% of eyes and 1.0 octave or better

80 0.5 octave or better in 57% of eyes and 1.0 octave or better in 85% of eyes.

81 0.5 octave or better in 71% of eyes and 1.0 octave or better in 93% of eyes.

82 ity difference, interobserver agreement of 1 octave or better was found in 88% of clinical subjects a

83 Interobserver agreement of 1 octave or better was found in 91% of the monocular and 9

84 The Quikr computational package (in MATLAB, Octave, Python and C) for the Linux and Mac platforms is

85 In any given subject, there was a 1- to 2-octave range in acuity estimates over the 8 seconds of s

86 oad spectral selectivity over a four-to-five octave range.

87 ttention involves multiple pass-bands around octave-related frequencies above and below the cued tone

88 esults suggest neural interactions combining octave-related frequencies, likely located in nonprimary

89 om exposure to natural vibrations containing octave-related spectral peaks, e.g., as produced by voca

90 s covering more than 6 octaves with only 0.2 octave resolution.

91 This implies that the half-octave shift in mammalian hearing is an epiphenomenon of

92 the effects of five musical transformations: octave shift, permutation, transposition, inversion, and

93 rged as a promising solution, owing to their octave spanning bandwidths, the ability to achieve group

94 ive polarization transformation over a broad octave-spanning bandwidth.

95 monstrate generation and guidance of a three-octave spectral comb, spanning wavelengths from 325 to 2

96 In the OCTAVE Sustain trial, 593 patients who had a clinical re

97 In the OCTAVE Sustain trial, remission at 52 weeks occurred in

98 In the OCTAVE Sustain trial, the rate of serious infection was

99 ination thresholds changed from close to one octave to about 1/12 octave.

100 The cortical distance representing a given octave was similar, yet response frequency resolution wa

101 Over a range of frequencies at least an octave wide, the depth is independent of frequency.

102 ic tuning in many cells was at least 1.5-2.0 octaves wide and, on average, was more than twice as wid

103 infrared dispersive waves, embedded in a 4.7-octave-wide supercontinuum that uniquely reaches simulta

104 ith a wide range of SFs covering more than 6 octaves with only 0.2 octave resolution.

105 quency of PVNs to higher frequency by a full octave, with no significant effect on average best frequ

106 wing formats: SBML, BioPAX, SBGN-ML, Matlab, Octave, XPP, GPML, Dot, MDL and APM.