ライフサイエンスコーパス: pulse width

1 requency, intensity, treatment duration, and pulse width).

2 nnabidiol and interference #1 at 70 mus gate pulse width.

3 g cascade creates a system that is robust to pulse width.

4 GnRH pulse, and this reduces sensitivity to pulse width.

5 nd broadening, and by reducing the injection pulse width.

6 f 0.5 msec is more efficient than the 1-msec pulse width.

7 ith the 0.5-msec pulse width than the 1-msec pulse width.

8 ith the 0.5-msec pulse width than the 1-msec pulse width.

9 D50, and they both decreased with decreasing pulse width.

10 threshold showed a similar relationship with pulse width.

11 w long the waves continued, namely, on their pulse widths.

12 or better, being limited only by the optical pulse widths.

13 OG, without change in contacts, voltages and pulse widths.

14 threshold voltage was insensitive to longer pulse widths.

15 follows: mean pacing threshold (at a 0.4-ms pulse width), 0.40 +/- 0.26 V and 0.43 +/- 0.30 V; R-wav

16 mented torques, non-linear responses to wide-pulse width (1 ms), low-intensity, variable-frequency (2

17 on of cartridge-type N2 lasers (337 nm, 4-ns pulse widths, 1-30-Hz repetition rates) more than a deca

18 a subcutaneously implanted nerve stimulator (pulse width 100 micros or 1 ms, frequency 20 or 160 Hz,

19 e active neurostimulation (frequency 180 Hz; pulse width 120 mus; amplitude 0.5 V below adverse event

20 requency (2-20 Hz), intensity (0-3.5 mA) and pulse widths (130-750 mus) over 14 months.

21 A train of 10 pacing stimuli (10-ms pulse width, 200-ms cycle length) was coupled to the sho

22 f live rhesus monkey eyes for five different pulse widths (7 nsec; 80, 20, and 1 psec; and 150 fsec).

23 grown culture to PEF of 5.0 kV/cm and 20 mus pulse width, accumulation of magnesium and zinc in yeast

24 er, (76 MHz repetition rate, 150 femtosecond pulse width), allowing for the visualization of individu

25 e, the temporal resolution is limited by the pulse width and by the difference in group velocities of

26 s to GES were strengthened with an increased pulse width and/or frequency of stimulation; T9-T10 spin

27 s for different photostimulation amplitudes, pulse widths, and frequencies.

28 LFP (380 nm, pulse width approximately 350 fs) of 2 and 3 allowed dir

29 nm absorption obtained from the 355 nm LFP (pulse width approximately 7 ns) of 1, 2, and 4 has been

30 In this approach, microJoule pulses (pulse widths, approximately 600 ps) are focused using hi

31 Phase-2 voltage and maximum pulse width are dependent on phase-1 pulse characteristi

32 ted with increased membrane conductance when pulse widths are microseconds rather than nanoseconds.

33 Also, the near-IR thresholds for these pulse widths are much higher than for the visible wavele

34 nctionalities or performances in response to pulse width as a new capability.

35 onse function (i.e., a negligible excitation pulse width) as does most current rapid lifetime determi

36 We implemented a single-wavelength pulse-width-based method with a one-dimensional imaging

37 ubcycle field waveforms with almost constant pulse widths can be generated without a dramatic degrada

38 690 to 1050 nm, prechirper optics for laser pulse-width compression, resonant galvanometer for video

39 termined to be both compound and initial ion pulse width dependent.

40 drift length, voltage across drift cell, and pulse width determined the requirements for designing a

41 ations using time-gated detection and finite pulse width excitation.

42 induced by fewer, lower amplitude and short pulse width exposures may only allow extracellular calci

43 interval bipolar capture threshold at 0.5-ms pulse width for the IPL increased from 0.69+/-0.14 V at

44 n mobility spectra were studied with various pulse widths for both positive and negative ions, giving

45 epetition rate Nd:YAG laser (355 nm, <500-ps pulse widths) for atmospheric pressure MALDI-QqTOFMS, an

46 ponses, over a range of pulse amplitudes and pulse widths, for 21 cell types spanning the inner two l

47 depends on stimulation parameters, including pulse width, frequency, amplitude, and pulse train durat

48 ed in 3 PD patients simply by increasing the pulse width from 60 to 240 microseconds, even at a lower

49 t 1.55 microm, exhibiting approximately 2 ps pulse width from an Er-doped glass oscillator (ERGO).

50 Second, stretching the pulse width in time by introducing negative dispersion w

51 essful for subsequent ECTs when the 0.5-msec pulse width is used.

52 d discovered that a BP nsEP with symmetrical pulse widths is not required to generate BPC.

53 sent sounds in which the waveform shape, the pulse-width, is fixed throughout the presentation or whe

54 A temporal pulse width larger than the time needed for pressure red

55 Laser pulse widths less than 1 nsec in the near-IR are capable

56 be predominately diffusion rather than gate pulse width limited.

57 The mathematical underpinning of the pulse width modulation (PWM) technique lies in the attem

58 l of gene expression using a strategy termed pulse width modulation (PWM).

59 cules over a large concentration range using pulse-width modulation (PWM).

60 apture thresholds at 6 months (</=2.0 V at a pulse width of 0.24 msec and an increase of </=1.5 V fro

61 The pulse width of 0.5 msec is more efficient than the 1-mse

62 eters: electric field strength of 3kV/cm and pulse width of 10mus after the treatment of 20-h culture

63 zation, and a Q-switched pulse output with a pulse width of 5 ns and peak power of 255 W was achieved

64 slope efficiency of 29.4% and with a minimum pulse width of 5.1 ns.

65 t response time is limited only by the laser pulse width of 500 fs, and permits a measurement of the

66 23.8 mJ of photobleaching light energy at a pulse width of 6 msec and a duty cycle of 50%.

67 of 0.71 J/cm2, repetition rate of 5 Hz, and pulse width of 750 picoseconds in combination with a dif

68 beams in a time shorter than the synchrotron pulse width of about 100 ps.

69 uous extraction mode essentially matches the pulse width of the laser (4 ns).

70 tical charge (average mC=2.5 times age) with pulse widths of 0.5 msec and 1 msec and frequencies of 3

71 oF monophasic capacitive-discharge pulses at pulse widths of 1.5, 3.0, 7.5, and 15 ms.

72 hrough this zone is very rapid, resulting in pulse widths of ~200 mus for the nanopores used in this

73 nce in response to the varying amplitude and pulse-width of the applied signal.

74 ars in </=3 ps after 452 nm excitation (5 ps pulse width) of PYP.

75 ngth-duration relationship, or the effect of pulse width on defibrillation efficacy.

76 They also do not include the effect of input pulse width on the output.

77 Paired pulse width pacing thresholds at 2.8 V were compared in

78 tages declined exponentially with increasing pulse width reaching an asymptote by 6 ms (451+/-68 V, P

79 time-dependent experimental variables (laser pulse width, reagent fluorescence lifetime, etc.).

80 There is a specific optimum voltage, gate pulse width, resolving power, and now CRM for each ion.

81 60 beats per minute, 2 V amplitude, and 1 ms pulse width, restoring mean arterial pressure from 0 to

82 f some neurons were charge insensitive; (ii) pulse-width sensitivity varied between cell types, allow

83 low current intensity (<5 mA and 100 micros pulse width) stimulation, our results show that all of o

84 uction was more successful with the 0.5-msec pulse width than the 1-msec pulse width.

85 ak heart rates were higher with the 0.5-msec pulse width than the 1-msec pulse width.

86 For all pulse widths, the 24-hour MVL-ED50 was lower than the 1-

87 ation by implanted electrodes (10 Hz, 0.3 ms pulse width, up to 6 V, 8 h day-1) for 2 or 7 days with

88 Compression of optical pulses to ultrashort pulse widths using methods of nonlinear optics is a well

89 The physical limitation of the pulse width was discussed with the calculated results.

90 Phase-2 pulse width was held constant at 3 ms in all waveforms.

91 epetitive white light stimulation of varying pulse width was observed.

92 ipolar pacing at an output of 10 mA and 2-ms pulse width was required.

93 Frequency and pulse width were fixed.

94 perating point, based on frequency-amplitude-pulse width, where a null heart rate response is reprodu

95 osure dose VT (applied voltage x frequency x pulse width x treatment duration) of about 4700 Vs, ther