ライフサイエンスコーパス: power supply

1 n, and eliminating the percutaneous lead for power supply.

2 g, wireless power transmission, and on-board power supply.

3 swer analysis of viruses without an external power supply.

4 cal redox processes in situ with no external power supply.

5 access to electricity or face an unreliable power supply.

6 medical devices necessitates a high-capacity power supply.

7 p and thus eliminating the need for external power supply.

8 form with sensing, communication, and stable power supply.

9 the PB film without the need for an external power supply.

10 te pencil electrode tip using a high-voltage power supply.

11 teraction (HMI) application without external power supply.

12 ay represent an ultimate solution for mobile power supply.

13 y harvester is highly desired as a potential power supply.

14 two-chambered microbial fuel cell (MFC) as a power supply.

15 gh-voltage (8 kV) and high-frequency (6 kHz) power supply.

16 e energy storage devices to realize a stable power supply.

17 emitters, photodetectors and a photovoltaic power supply.

18 ternal pumping systems, valves, and electric power supply.

19 s requires bulky instrumentation and intense power supply.

20 cells and wireless coils provide options for power supply.

21 ith just two driving electrodes and a simple power supply.

22 (PDMS) fabricated microchip and a common dc power supply.

23 e outstanding values were obtained under 1 V power supply.

24 mittently gates the output of a conventional power supply.

25 erated with a home-built high-voltage pulsed power supply.

26 , which is resistively heated by a precision power supply.

27 ut employing higher drift voltages and bulky power supplies.

28 ractical design and independence of external power supplies.

29 rents, which serve as both clock signals and power supplies.

30 l motor controllers, powered by six separate power supplies.

31 energy density capacitors in modern electric power supplies.

32 anic LEDs, wireless-control electronics, and power supplies.

33 ational lifetimes constrained by traditional power supplies.

34 umbersome, expensive optics nor high voltage power supplies.

35 al optoelectronic components, computers, and power supplies.

36 p, microchip holder, two 0-8-kV high-voltage power supplies, a high-voltage switch, a solid-state dio

37 been developed, they either rely on tethered power supplies and complex designs or cannot move extern

38 myocardium, and of displacements of external power supplies and control systems.

39 With miniaturization of the power supplies and controllers, such mechanical circulat

40 nce applications, including un-interruptible power supplies and energy-harvesting systems that demand

41 om extreme heat (for example through back-up power supplies and/or passive cooling) and using databas

42 A digital power supply and a 6 1/2 digit voltmeter were used.

43 rbable optoelectronic system with an onboard power supply and a wireless, optical control mechanism w

44 The valve operates on a 5 V power supply and can be controlled via USB cable or I2C

45 s a weak electric field without any external power supply and can be used as any other disposable dre

46 The device is not dependent on a power supply and can perform on-site rapid virus detecti

47 ulator is heated by current pulses from a dc power supply and cooled by a conventional two-stage refr

48 imited by the essential need for an external power supply and electrical wires for electrode connecti

49 To overcome these hurdles, solutions in power supply and interface strategies that maintain high

50 We find that the relation between the future power supply and long-term mean solar radiation trends i

51 re programmably controlled by a high-voltage power supply and monitored by an epifluorescence microsc

52 -4) thus need to fly tethered to an offboard power supply and signal generator owing to the challenge

53 , working in passive mode and used herein as power supply and signal transducer.

54 oring systems particularly need a continuous power supply and wireless transmission capability for mo

55 operating system has been developed for the power supplying and data reception from the tag.

56 egration of diverse electronic devices, both power-supplying and power-consuming, on flexible substra

57 ioresorbable electronic components, sensors, power supplies, and in integrated diagnostic and therape

58 plications such as self-powered logic gates, power supplies, and sensors.

59 ual components such as a waveguide, antenna, power supply, and an oscillator.

60 for various energy storage requirements and power supply, and the energy conversion efficiency of th

61 nsors, stimulators, radios, and battery-free power supplies are resulting in a new generation of full

62 LODs with an on-board electrical power supply are called electrified-LODs (eLODs) and are

63 benefit from reduced dependency on external power supplies as well as from further miniaturization a

64 ystem, data acquisition components, and lens power supplies, as well as a custom-software application

65 ation detectors, data acquisition cards, and power supplies, as well as computer control and user int

66 For metabolically demanding behaviours, power supply (ATP resynthesis per unit time) is an impor

67 ower dissipated in the load resistor and the power supplied by the secondary voltage.

68 e system consisting of display, keyboard and power supply can serve as a communication tool, demonstr

69 Its power supply capabilities have also been successfully de

70 miniature 400 W solid-state constant current power supply controls the temperature of the coil.

71 tantly, the pouch cell exhibits a continuous power supply despite conditions of -50 degrees C.

72 ll increase coincides with a markedly higher power supply driven mainly by intensified anammox reacti

73 Miniaturized, battery-powered, high-voltage power supply, electrochemical (EC) detection, and interf

74 The elimination of electrochemical power supplies enables control over device operation, an

75 hout any extra optical elements nor external power supplies, explicitly showing great potential for t

76 nning on hydrogen are attractive alternative power supplies for a range of applications, with in situ

77 d powering the PCR reactor, and high-voltage power supplies for conducting CE separations.

78 t as a promising alternative to conventional power supplies for IMDs.

79 a stable capacity of 0.5 Ah and realize the power supply for mobile phones and other electronic devi

80 ab-on-disc (LOD) devices require an on-board power supply for powering active components.

81 ntially provides a practical and sustainable power supply for the environmental sensing applications.

82 For the first time, a stable power supply for the monitoring system has been realized

83 3D printed components, and the high-voltage power supply from a plasma globe toy.

84 onary energy storage technology for leveling power supply from intermittent renewable energy sources

85 both active and passive mode, obtaining the power supply from the electromagnetic waves of the RFID

86 ecifically, feeder electrodes connected to a power supply generate an electric field, while the bipol

87 uld offer a wireless scheme with sustainable power supply; however, current ultrasound implantable sy

88 tical components to ensure the uninterrupted power supply in a secure manner to withstand extreme wea

89 an open up exciting opportunities for mobile power supply in diverse applications.

90 at in the case where R(s) is negligible (the power supply is connected directly to a conducting needl

91 tibility between body movement and sustained power supply is further displayed.

92 e, so that a body sensor network with hybrid power supply is much more reliable than that with single

93 pump stream can be achieved (e.g., where the power supply is not constrained by field conditions).

94 The power supply is realized with a lightweight battery, whi

95 This MGD can be driven by a portable power supply (less than two pounds), which can be powere

96 biomedical devices, but their efficiency and power supply limitations hinder prolonged operation.

97 ed ohmically using electrical current from a power supply monitored and regulated with a precision of

98 able and sustainable method for the reliable power supply of widely distributed electronics in the ne

99 augmentative devices currently require bulky power supplies, often making these tools more of a burde

100 as frequency converters without an external power supply or DC bias source.

101 odes can be controlled with just a single DC power supply or even a battery.

102 activate, and without the need for external power supply or signal generation, the all-optical simpl

103 le MOA instrument integrates high voltage CE power supplies, pneumatic controls, and fluorescence det

104 stigated the techno-economic feasibility and power supply potential of enhanced geothermal systems (E

105 The CE power supply power is connected to the microchip through

106 rid system with the consideration of loss of power supply probability (LPSP), stochastic load profile

107 Programmable high-voltage power supplies provide bidirectional currents up to 100

108 The dual source CE power supply provides +/- 1 kVDC at 380 microA and can o

109 simplified electrical circuitry, and reduced power supply requirements.

110 ure control rather than complex high voltage power supplies, sieving matrices, and wall coatings.

111 The components of the power supply system are modeled, the objective function

112 m is best at finding the optimal size of the power supply system at the minimum annual cost.

113 e optimal size of the renewable energy-based power supply system for rural communities is evaluated b

114 rimary issue with the renewable energy-based power supply system for rural electrification.

115 lysis of the renewable energy-based off-grid power supply system with the stochastic load profile of

116 ent circuit, a triboelectric-generator-based power-supplying system can provide a constant direct-cur

117 Finally, a portable power-supplying system, which provides enough d.c. power

118 In addition, physical tethers to power supply systems and data acquisition hardware limit

119 ent coupled with clean energy production and power supply systems for isolated low-power sensor devic

120 skin, modern sensors, circuits, radios, and power supply systems have the potential to provide clini

121 together with integrated sensors, actuators, power supply systems, and wireless control strategies.

122 Three off-grid power supply systems, such as PV-BAT, PV-WT-BAT, and WT-

123 to traditional transformer in some specific power supply systems.

124 for packaging, circuit design, and on-board power supplies that are benign, nontoxic, and even biode

125 e electronics, a persistent difficulty is in power supplies that have similar mechanical properties,

126 sable devices, a syringe pump and a low-cost power supply that provides a constant voltage.

127 It is a series circuit which consists of the power supply, the electrochemical contact to the solutio

128 m the requirement of the external electrical power supply throughout the sensing.

129 The power supplied to the geodynamo, measured by the heat fl

130 At least 84% of the electrical power supplied to the nanotube is dissipated directly in

131 ic focusing but uses additional high-voltage power supplies to provide control over the shape of the

132 ng microgrid at minimum cost and providing a power supply to a residential complex of 100 units.

133 lear water and in field conditions where the power supply to a water pump is limited, e.g., from batt

134 of approximately 50%, making it a sufficient power supply to regular electronics, such as light bulbs

135 e still lack an ATP-like or electricity-like power supply to sustain diverse molecular machines.

136 es, smart glass and virtual reality, and the power supply to the wearable electronics have been revea

137 timised for nanometre vibrations at 1 kHz, a power supply unit, which supplies a 1 kHz sine wave sign

138 acts of cooling water shortages on Britain's power supplies using a probabilistic spatial risk model

139 nd attaining a voltage gain above 60 dB at a power supply voltage below 8 V.

140 amplifiers operating at a battery-compatible power supply voltage of 5 V with power dissipation of 11

141 Subtracting the iRs voltage from Vapp (power supply voltage) yields the current-voltage curve f

142 n any architecture) to achieve this at a low power-supply voltage of 0.1 volts.

143 The performance of the microfluidic MFC as a power supply was characterized based on polarization beh

144 lity was enabled by creating a novel dynamic power supply, which allowed spray voltage to be applied

145 ies of surfaces without the requirement of a power supply, which can potentially benefit applications

146 uency mechanical stimuli without an external power supply, which has extended the application of trib

147 vel of 60% for the future additional Jiangsu power supply, wind resources distributed along the offsh

148 soft devices are also discussed in terms of power supply, wireless control, biocompatibility, and th

149 rometry are usually driven by direct current power supplies with no user control over the total charg

150 ght (22 g), and low cost ( approximately $2) power supply with only 1.5 VDC input.

151 A rapid and deep decarbonization of power supply worldwide is required to limit global warmi

152 rt electricity to hydrogen at times of ample power supply, yet they can also operate in the reverse d