ライフサイエンスコーパス: low-power

1 CI: 0.7, 12.4), which was most likely due to low power.

2 issues/tumors in pulsed mode with relatively low power.

3 ank chi21 = 0.4; P = .54), possibly owing to low power.

4 howed that multiple CMH tests still had very low power.

5 r researcher allegiance, which suffered from low power.

6 higher mental health status than women with low power.

7 ime points to address serial correlation and low power.

8 her rely on false assumptions or suffer from low power.

9 at operate at low voltages (200 microvolts), low power (10 nanowatts) and are completely compatible w

10 Requiring only a low-power ( 3.5 mW) laser source to activate, and withou

11 illumination of the inoculation site with a low power 532 nm Nd:YAG laser enhanced the permeability

12 onstrated in a four-channel system, in which low power (a few tens of picowatts) fluorescent signals

13 this strain response to achieve coherent and low-power acoustic control of a single SiV spin, and per

14 ory motion is driven by the application of a low-power acoustic field, which is biocompatible with bi

15 ctivated localization microscopy (PALM) with low-power activation light under physiological condition

16 arities have great potential for high speed, low power all-optical processing.

17 0 degrees magnetization switching provides a low-power alternative to current-driven magnetization sw

18 the technological basis for highly efficient low-power analog and digital electronics using ZnO and/o

19 Analytical DBDs are often operated at low power and atmospheric pressure, making a direct tran

20 a disruptive device concept which meets both low power and high performance criterion for post-CMOS c

21 However, low power and low voltage output of MFCs typically do no

22 s that offers devices with high performance, low power and multiple functionality.

23 Low power and poor instrumentation of activity limited c

24 This system provides a rapid, sensitive, low power and reagents consumption and fully automated f

25 -based devices offer non-volatile, scalable, low power and reprogrammable functionality for emerging

26 The low power and resource usage of these biosensors enables

27 Here, we introduce off-resonance, low power and short pulse infrared nanospectroscopy (ORS

28 e SiPMs are much more compact and operate at low power and voltage.

29 after surgery, which may be attributable to low power and, thus, random chance.

30 bility to perform fast and at the expense of low-power and -space requirements.

31 s to its potential advantages like low-cost, low-power and easy miniaturization of the required instr

32 In principle, low-power and high-density information storage that comb

33 ides an additional viable route to realizing low-power and high-speed spintronics.

34 mally responsive systems with a narrow beam, low power, and low cost 405 nm laser perturbs the therma

35 use of smartphones in designing small-sized, low-power, and affordable retinal imaging systems to per

36 ms and nanostructures by a room-temperature, low-power, and bias-free reactive sputtering process.

37 ntegrated into a power management system for low power application (eg.

38 ds, modest public health infrastructure, and low power availability.

39 The quest for low power becomes highly compelling in newly emerging ap

40 analytical methodology in combination with a low power benchtop total reflection X-ray fluorescence (

41 hetic effect itself unless irradiated with a low-power blue light emitting diode (LED), resulting in

42 zing prospects for hardware realization of a low-power brain-inspired computing architecture that cap

43 be triggered to photorelease CO remotely by low-power broadband visible light (<1mWcm(-2)) with the

44 However, poor cycle life and low power capability are major technical obstacles.

45 tion makes the polariton laser an attractive low-power coherent light source for medical and biomedic

46 In this paper, we present a low power, compact and computationally inexpensive setup

47 ial to act as information carriers in future low-power computing technologies.

48 for the development of high performance and low-power consuming logic circuits.

49 attention as active materials for flexible, low-power-consuming devices.

50 We present a monolithic low-power-consuming PMS integrated circuit (IC) chip cap

51 This work presents a low-power-consuming, active, and a general approach to e

52 It offers low power consumption (<400 mW), low helium consumption

53 2 Pa), fast response ( approximately 24 ms), low power consumption (<6 microW), and mechanical stabil

54 The advantages of low carrier gas and low power consumption (<6 W), as well as zero solvent us

55 cm x 40 cm x 14 cm), low weight (13 kg), and low power consumption (50 W).

56 ppb), fast response time (down to ~1 s), and low power consumption (down to ~30 mW).

57 atable all-optical quantizer for on-chip and low power consumption all-optical analog-to-digital conv

58 iples of biological neural systems may offer low power consumption along with distinct cognitive and

59 agnetoelectric (ME) effect, offers versatile low power consumption alternatives to current data stora

60 , nonvolatile magnetic memory can operate at low power consumption and high frequencies.

61 e second is to use self-powered devices with low power consumption and high performance as active sen

62 results suggest that, given the portability, low power consumption and high sensitivity of the device

63 information display revolution due to their low power consumption and potentially long operational l

64 ely the mixture of all-optical Internet with low power consumption and quantum Internet with absolute

65 ly realize next-generation devices featuring low power consumption and quantum operation capability.

66 ti-stable LCDs to display static images with low power consumption and thus opens applications in var

67 threshold laser system with small footprint, low power consumption and ultrafast modulation.

68 w at high flow rates, yet with exceptionally low power consumption by electrowetting/deelectrowetting

69 licon with high storage density, high speed, low power consumption has attracted intense research on

70 pplications in cochlear implants where ultra-low power consumption is a primary requirement.

71 Only a reduced electronics with very low power consumption is required for the reading of the

72 This design has the advantages of low power consumption of 60 mW and good sensitivity to s

73 wireless fluorescence endoscope capsule with low power consumption that will pave the way for future

74 our saturation, versatile form factor(8) and low power consumption(9), but could still be improved in

75 , fast temperature programming and analysis, low power consumption, and good versatility (ambient tem

76 nverter with desirable gain (8.3 V mm(-1) ), low power consumption, and high stability is also demons

77 ve drying and freezing, and small footprint, low power consumption, and simplicity make OTIC a good c

78 to enhance the device stability, to achieve low power consumption, and to prevent the formation of r

79 synergistic organic memory devices represent low power consumption, high cycle endurance, high therma

80 tion wire resistance, low voltage operation, low power consumption, long-term reliability, and only a

81 our filtering offers increased efficiencies, low power consumption, slim dimensions, and enhanced res

82 e-controlled miniaturized pacing system with low power consumption, thereby providing a basis for the

83 , fast response speed, silent operation, and low power consumption.

84 th tunable symmetry, retention, and speed at low power consumption.

85 n storage and signal processing devices with low power consumption.

86 ic circuits with less physical resources and low power consumption.

87 the limelight due to the great potential for low power consumption.

88 due to its non-volatility, high density and low power consumption.

89 th CMOS fabrication processes, low cost, and low power consumption.

90 lutions for lasers with small footprints and low power consumption.

91 M display features a reduced form factor and low power consumption.

92 ices that store and process information with low power consumption.

93 that provide high performance operation with low power consumption.

94 s to solve the image-flickering issue in the low-power consumption display in terms of the physical p

95 ults demonstrate information processing with low-power consumption inside artificial cells.

96 ical analog computing offers high-throughput low-power-consumption operation for specialized computat

97 e for intelligent communication systems with low power consumptions and high communication bandwidths

98 tform and demonstrate their use for tunable, low power continuous wave second harmonic generation.

99 e promising results indicate that relatively low power continuous wave transcranial MRgFUS in conjunc

100 It is based on the use of a low-power continuous-wave vortex beam that traps and tra

101 We report a pilot clinical trial of low-power, continuous-wave, near-infrared laser adjuvant

102 Microvascular perfusion was evaluated by low-power contrast ultrasound perfusion imaging.

103 ication bias, neglected quality criteria and low power, contribute to the stepwise efficacy decline o

104 However, in general they exhibit low power conversion efficiencies (PCEs) because of the

105 olar energy remains costly, largely owing to low power conversion efficiencies of solar cells.

106 Here we describe a low-power cryogenic near-field scanning microwave micros

107 art, with unique operational capabilities in low power defibrillation.

108 gh specific energy, however, results in very low power densities (less than 2 W/m(2)), indicating tha

109 but CapMix devices have produced relatively low power densities and often require expensive material

110 sfer to yield bright visible emissions using low power density excitations.

111 However, major challenges remain including low power density, difficult scale-up, and durability of

112 thermal emitters, have long been limited by low power density.

113 erties were developed; they can operate with low-power density far-red light-emitting diode light.

114 d optical isolation, wireless technology and low power design.

115 -layered structure, we were able to create a low powered device that can operate less than 15 V that

116 rformance field-effect transistors and ultra-low power devices such as tunneling field-effect transis

117 ously generate bioelectricity to power ultra-low powered devices and sense glucose.

118 solar-panel') with potential applications in low-power devices.

119 bulk strontium oxide irradiated by a simple low power diode laser.

120 CERS with low power diode lasers is suitable for online monitoring

121 nd a low input impedance of 500 Omega with a low power dissipation of 40 muW.

122 ohertz up to gigahertz and usually have very low power dissipation.

123 write" linearity, low-voltage switching, and low power dissipation.

124 w route to control domain wall dynamics with low-power dissipation.

125 gnetic moment provides a promising route for low-power-dissipation spintronic devices.

126 We report primed conversion, in which low-power, dual-wavelength, continuous-wave illumination

127 s a miniature format, and uses exceptionally low power due to the lack of RF separation fields normal

128 lternative to the development of high-speed, low-power dynamic random access memory-like phase change

129 ctor (CMOS) circuit designs can still suffer low power efficiency, motivating designs leveraging nonv

130 romising candidate for future high-speed and low-power electronic applications.

131 es can be made enabling high-performance and low-power electronic circuits using imperfect two-dimens

132 ing the spin degree of freedom in very fast, low-power electronic devices.

133 efficient transitions would enable fast and low-power electronic devices.

134 ME) effect is recognized for its utility for low-power electronic devices.

135 s of great current interest for a variety of low power electronics in which the magnetic state is use

136 With the ever-increasing demand for low power electronics, neuromorphic computing has garner

137 The biosensor on integration with low-power electronics and a portable saliva swab serves

138 e been regarded as a promising candidate for low-power electronics due to their high capacitance.

139 f neural probes, design of implantable ultra-low-power electronics, implementation of high-data-rate

140 Advances in wireless technologies, low-power electronics, the internet of things, and in th

141 uantum effects and potential applications in low-power electronics, thermoelectrics and spintronics.

142 such as wireless and self-powered sensors or low-power electronics.

143 new pathway to the realisation of high-yield low-power electronics.

144 en of great interest due to its potential in low-power electronics.

145 demonstrate their applications in flexible, low-power energy harvesting.

146 Since chemiresistors require low-power equipment and are able to detect low concentra

147 h UCNPs, as well as their ability to utilize low-power excitation, which attenuates any local heating

148 plications require accelerators for fast and low-power execution.

149 c substrates represent a new approach toward low power, fast, high density spintronics.

150 pathway towards designing future generation low-power ferroelectric based microelectronic devices by

151 putum specimens, 2608 (69%) had <10 SECs per low-power field (LPF) and 2350 (62%) had >25 PMNs per LP

152 ty sputum (defined as </=10 epithelial cells/low-power field [lpf] and >/=25 white blood cells/lpf or

153 iterion of <10 squamous epithelial cells per low-power field, and 1162 (44.6%) had radiographic pneum

154 ntrary, NOx from diesel vehicles and CO from low-powered gasoline vehicles were significantly higher

155 tance, small switching currents in nA range, low power generated, and signals that can be difficult t

156 hod to enhance Kerr nonlinearity and realize low-power gigahertz solitons via plasmon-induced transpa

157 ed "structural peace"), while members of the low-power group (in this case Palestinians) exhibit an o

158 nt transcranial ultrasound device delivering low-power high-frequency ultrasound could improve functi

159 While silicon ICs thrive at low-power high-performance computing, creating flexible

160 sensitive and fast photodetectors can enable low power, high bandwidth on-chip optical interconnects

161 Scalable, low power, high speed data transfer between cryogenic (0

162 rest thanks to its outstanding potential for low-power, high-density and high-speed data storage.

163 Recent interest in ultra-low-power, high-density cryogenic memories has spurred n

164 have the potential to provide solutions for low-power, high-density data storage and processing.

165 dous attention as it can potentially deliver low-power, high-speed and dense non-volatile memories.

166 ng candidates for next-generation ultrathin, low-power, high-speed electronics.

167 We envision that a new class of low-power, high-speed, special-purpose signal processors

168 pplication as a new generation of miniature, low power humidity sensors for the internet of things.

169 To address the low power implicit in single-locus tests of rare genetic

170 R sensor instrument was configured to run on low power in a miniaturized platform to improve the devi

171 subfields of neuroscience, with particularly low power in candidate gene association studies.

172 r, sensitivity is suboptimal and can lead to low power in clinical trials.

173 that asynchronous cortical states (marked by low power in delta-band LFPs) are linked to high spike r

174 on with small population sizes, resulting in low power in detecting useful QTLs.

175 repeatedly switched on and off at remarkably low powers in the milliwatt regime.

176 delineates a general strategy to converge a low-power incident light beam into a photonic hotspot of

177 with the motivated cognition account, having low power increases individuals' hope and, in turn, thei

178 by rational actor models, which assume that low-power individuals are able to anticipate that a more

179 otivated cognition theory, which posits that low-power individuals want their exchange partner to be

180 between an engineered resonant surface and a low-power infrared laser can cause enough photoemission

181 l to open up new avenues for ultra-dense and low-power integrated circuits, as well as for ultra-sens

182 w the promise of our system as a high speed, low power, integrated platform for physics and devices b

183 ysis of extremely long eyes implanted with a low power intraocular lens indicated that predicted RE w

184 , amplifier-free, light-emitting-diode-based low-power ion-indicator.

185 atically underpowered is not the full story: low power is far from a universal problem.SIGNIFICANCE S

186 disc produced massive retinal lesions, while low power laser shots in the retina produced restricted

187 The writing is performed with a low-power laser and the entire process stays below 90 de

188 mit spatiotemporal optogenetic ablation with low-power laser light.

189 ve hypersensitive NMR applications employing low-power laser sources.

190 h-power laser therapy is more effective than low-power laser therapy in improving OM lesion healing,

191 hich we compare the efficacy of the standard low-power laser therapy protocol with an innovative prot

192 tion mechanism allows the use of inexpensive low-power lasers.

193 aser but the signal decrease is <2% with the low-power LED-based photoacoustic system and the same ra

194 o transduce and digitize temperature at very low power levels.

195 lene derivative is involved as an emitter in low power light frequency conversion.

196 vasively triggered drug release using brief, low-power light exposure.

197 the first proof-of-concept for the usage of low-power light sources for challenging reactions employ

198 been widely discussed because it could allow low-power logic operation by overcoming the fundamental

199 ecular membrane promises new applications in low-power logic switches for computing and ultrasensitiv

200 w 1 MHz offers significant opportunities for low power, long range communication systems to meet grow

201 canceled by requirements for no consumables, low power, low cost, and unobtrusive form factors for In

202 These results present a simple low-power magnetization mechanism when operating at ambi

203 gical feature recognized first and easily at low-power magnification.

204 The low-power manipulation of the magnetization, preferably

205 rocess tactile information in a parallel and low power manner.

206 mping and the spring stiffness, facilitating low-power mechanical cooling in the vicinity of gain-los

207 and for realizing their potential for ultra-low power memory and logic devices as well as novel comp

208 re show the potential of 2D ferromagnets for low-power memory and logic applications.

209 makes this approach promising in context of low-power memory and neuromorphic computation.

210 r based circuit was able to operate an ultra-low-power microcontroller continuously, by running a pro

211 harge pump circuit was connected to an ultra-low-power microcontroller.

212 ded RTIL sensing element, integrability with low-power microelectronic and IOT interfaces makes this

213 ant benefits, e.g. high aperture efficiency, low-power, minimal cost, wide beam scanning angle and br

214 u and Ag electrodes together with a bespoke, low-power, multichannel, portable data-acquisition syste

215 arge pump powers, and realizing an efficient low-power nanocrystal laser has remained a difficult cha

216 ls with unique potential for applications in low-power nanoelectronics and novel metamaterials.

217 hereby providing the potential for effective low-power nanomanufacturing on-chip.

218 Low-power near-field nano-optical tweezers comprising pl

219 from this behaviour to realize high-density, low-power neuromorphic computing will require very large

220 massively parallel, compact, low-latency and low-power neuromorphic engineering devices.

221 Used in conjunction with an exceptionally low-power NIR LED light irradiation (10 mW cm(-2) ), the

222 ificant effect was observed; however, due to low power, no conclusions on the influence of anastomoti

223 is has important consequences for practical, low power non-volatile magnetoelectric devices utilizing

224 7), with immediate applications in ultrafast low-power non-volatile logic and memory(8) while also tr

225 g management systems equipped with portable, low-power, non-invasive CO(2) sensing techniques can pre

226 This robust, low-power, non-invasive, and miniaturized sensor aids in

227 witching can lead to a new paradigm of ultra-low power nonvolatile magnetoelectric random access memo

228 rge field-of-view, we demonstrate the use of low power objective to resolve the entire architecture o

229 factor of 8,700 while consuming an extremely low power of 1.36 nW, and transduced external excitation

230 odels accommodated by the software and (iii) low power of common multiple testing approaches.

231 ary responses, but it can also be due to the low power of former studies that have mainly focused on

232 ce metrics across multi-bit memory capacity, low-power operation, endurance, retention and stability.

233 totypes with solid electrodes (and therefore low power) or mesostructured electrodes not compatible w

234 rated a potential for designing scalable and low-power organic devices by utilizing doping of conjuga

235 bottlenecks in their widespread application, low power output and poor sensing capability.

236 on whether one belongs to the high-power or low-power party and 2) explain citizens' fundamental app

237 t emitting diodes (LEDs), provide relatively low power per independent spatial mode.

238 oelectric materials could potentially enable low-power perovskite ferroelectric tetragonality logic a

239 because of their great potential for driving low-power personal electronics and self-powered sensors.

240 field homogeneity making it more amenable to low-power portable applications.

241 cs, such as wearables, embedded systems, and low-power portable devices, has led to increasingly comp

242 In this work, the low power, portable TinyLev acoustic levitation system i

243 The system employed a UV-emitting LED for low-power, pulsed excitation and an intensified CCD came

244 composite films rapidly heat when exposed to low-power radio frequency fields.

245 in the brain, the application of an external low-power radiofrequency field was sufficient to remotel

246 tection was employed for its versatility and low power requirement.

247 devices, as such means typically have ultra-low power requirements and can provide coherent control.

248 onfinement leads to major advantages such as low power requirements, higher qubit densities and faste

249 This combination of spectral selectivity, low power requirements, low heat production, and fast re

250 rated into electronic devices, and they have low power requirements.

251 ucting magnets are widespread owing to their low power requirements.

252 cell cultures, irradiation with NIR light at low power results in precisely focused phototoxicity eff

253 pply to nanowire transistors, leading to new low-power, robust design approaches as large-scale fabri

254 Low-power samples are susceptible to 'winner's curse', w

255 ree operation of sensor nodes requires ultra-low-power sensing and data-logging techniques.

256 Such low-power sensing systems have major potential for futur

257 a radical approach for next generation ultra-low-power sensor design by embracing the evolutionary su

258 uction and power supply systems for isolated low-power sensor devices.

259 field of view with embedded and programmable low-power signal processing, high temporal resolution, a

260 ting a significant step towards advantageous low power silicon-based photonic technologies.

261 exible and stretchable sensors combined with low-power silicon-based electronics are a viable and eff

262 species in a ~1 mm(3) volume plasma using a low-power source, there is the potential for this method

263 Systems occupied by more efficient low-powered species suffer greater losses because of les

264 ive properties suitable for high-density and low-power spintronic device applications.

265 h is promising for the future development of low-power spintronic devices.

266 gnetoelectric coupling in view of efficient, low-power spintronic devices.

267 Spin waves may constitute key components of low-power spintronic devices.

268 ials for the realisation of high-density and low-power spintronic memory devices.

269 is one of the leading candidates to develop low-power spintronics and emerging memory technologies.

270 aser pulses is a pre-requisite for envisaged low-power spintronics combining storage of information i

271 ise a wide range of possible applications in low-power spintronics, optoelectronics, quantum computin

272 is a key issue for the future development of low-power spintronics.

273 ration stretchable electronics for realizing low-power, stand-alone, self-sustainable systems.

274 we simulate, design and fabricate arrays of low-power static random access memory circuits, achievin

275 nt patients, these were relatively small and low-powered studies.

276 electrodes provides a framework for sensing low-power (sub muW) and high-bandwidth (0.1-0.5 kHz) ion

277 flux quantum circuitry for novel high-speed low-power superconducting electronics.

278 T (in any architecture) to achieve this at a low power-supply voltage of 0.1 volts.

279 solid effect (FS-ISE) experiments that allow low power sweeps of the exciting microwave frequencies t

280 n fields including field effect transistors, low power switches, optoelectronics, and spintronics.

281 platinum filaments to enable high-speed and low-power temperature programming.

282 on high power, we found stronger effects of low power than high power.

283 of topological hard magnetic semimetals for low-power thermoelectric devices based on the Nernst eff

284 matrix-related ions, low matrix consumption, low power threshold for laser desorption/ionization, and

285 However, the diffraction limit precludes the low-power trapping of nanometre-scale objects.

286 nterest due to its potential application for low power ultra high-density data storage.

287 ime, microcavity polaritons hold promise for low-power, ultra-small devices and their localisation co

288 ntrol of the transition holds the promise of low-power, ultrafast electronics(2), but the relative ro

289 er excitons are promising for application as low-power, ultrafast lasers and modulators and for the s

290 d effect transistors (NWFETs) are low noise, low power, ultrasensitive biosensors that are highly ame

291 Here we demonstrate a generic, low-power ultrasonic separation technique, able to enric

292 he addition of intravascular high-frequency, low-power ultrasound energy facilitates the resolution o

293 Here, we show that low-power visible light can be used to control surface c

294 upconversion efficiency under both laser and low-power visible light excitation.

295 A novel, low power, waxing-and-waning optogenetic stimulation par

296 d much broader applications, for example, in low-power, wearable energy harvesting for internet-of-th

297 practice, testing only the top PCs often has low power, whereas combining signal across all PCs can h

298 sted TaiNi, a novel ultra-lightweight (<2 g) low power wireless system allowing 72-hours of recording

299 In industrial applications, low-power wireless sensor networks (WSNs) fulfill requir

300 ) is induced on the samples with an external low-power X-ray tube.