ライフサイエンスコーパス: processor

1 (e.g., restaurants, grocery stores, and food processors).

2 to both defined as convergent (local reflex processors).

3 g block of the arrangement is the half-adder processor.

4 n increase in the number of transistors in a processor.

5 nt graph using a two-qubit photonics quantum processor.

6 tected logical qubit using a diamond quantum processor.

7 al cloning and a single-step, coherent field processor.

8 surface code(15,16) in a trapped-ion quantum processor.

9 as basic building blocks of a future quantum processor.

10 ementation on an AMD Phenom II 810 quad-core processor.

11 ents for a silicon-based quantum information processor.

12 it to run faster than real-time on a desktop processor.

13 d for implementation of a spin-based quantum processor.

14 times the time R takes to complete it on one processor.

15 ic medium (ChromID) using the WASP automated processor.

16 rocessor that hosts the microphone and sound processor.

17 two quantum algorithms on a superconducting processor.

18 lization of a scalable silicon-based quantum processor.

19 eded for a large-scale semiconductor quantum processor.

20 on space on a five-qubit trapped-ion quantum processor.

21 in the variational solutions using our noisy processor.

22 s can interact with many other qubits in the processor.

23 submitting a problem to the quantum annealer processor.

24 t of efforts to create a solid-state quantum processor.

25 the existing experiments to scalable quantum processor.

26 tA), a peptide ligation enzyme, as a generic processor.

27 n-general, rather than word-specific, visual processor.

28 tion transmon circuit serving as the central processor.

29 ould be directly integrated on silicon-based processors.

30 alysis by distributing runs over two or more processors.

31 making it well suited to multi-core computer processors.

32 utational capabilities of massively parallel processors.

33 thus paving the way towards robust big-data processors.

34 blood disposal is a severe problem for meat processors.

35 e high stimulation rates used in clinical CI processors.

36 blems in fewer clock cycles than traditional processors.

37 computers or circuit quantum electrodynamics processors.

38 ng, thus producing important losses for food processors.

39 orks and general-purpose integrated photonic processors.

40 roaches are not as easily scaled on multiple processors.

41 ith further speedups possible using multiple processors.

42 ion (P = 2.2 x 10(-13)), in only 1.5 h on 10 processors.

43 que for resolving time dependence in quantum processors.

44 positive values interesting for growers and processors.

45 scale and fault-tolerant quantum information processors.

46 e using the mass spectrometer's (MS) onboard processors.

47 ce to the development of quantum information processors.

48 nt and attach dynamically a number of output processors.

49 lopment of silicon-based quantum information processors.

50 period of 10-19 weeks by using human speech processors.

51 ein docking server to be powered by graphics processors.

52 ned the same results in 6 h by utilizing 100 processors.

53 dering computer games, are powerful parallel processors.

54 ent of reagent concentrations in 11 parallel processors.

55 information to be globally accessed by local processors.

56 ravelling the wiring of the molecular signal processors.

57 distribute calculations across a network of processors.

58 quency (50 vs 400 Hz) in experimental speech processors.

59 tion is readily distributable across several processors.

60 b-domains which are distributed to different processors.

61 of scalable solid-state quantum information processors.

62 r on a quantum processor than on a classical processor(1).

63 coupled qubits required for a useful quantum processor(1-7).

64 n remotely connected superconducting quantum processors(1).

65 ration is performed in a trapped-ion quantum processor(17), the protocol is applicable to other quant

66 e basis of high-fidelity quantum information processors(5,6) and high-accuracy optical clocks(7).

67 m repeaters(7,8) and general-purpose quantum processors(9-12).

68 Second, comparing a processor account with a rational allocation mechanism t

69 logic gates in a superconducting multi-qubit processor, achieving an average single-qubit gate fideli

70 can interconnect remote quantum information processors, allowing interaction between different archi

71 nsequence, each cortical area is an adaptive processor, altering its function in accordance to immedi

72 This system acts as a biological signal processor, amplifying signal reception and filtering bio

73 rcial and experimental samples offers quinoa processors an accurate inexpensive way of measuring sapo

74 rrectly every problem that was mapped to the processor and demonstrated clear advantages over the bas

75 s checkpointing and better support for multi-processor and high-end computing extensions.

76 It makes efficient use of both computer processor and memory resources, requiring less than a mi

77 framework, which tracks provenance, profiles processor and memory use, records diagnostics, manages m

78 e we demonstrate a two-qubit superconducting processor and the implementation of the Grover search an

79 The database search processor and the mass spectra processor, running on a r

80 earning due to the data movement between the processor and the off-chip memory.

81 provements in its implementation, FitHiC2 (8 processors and 16 GB memory) is also scalable to genome-

82 to test imputation, findhap used 7 hours, 10 processors and 50 GB of memory for 1 million loci on one

83 -Ultra utilizes multiple available cores and processors and can be tuned for various memory settings.

84 d methods for parallel execution on multiple processors and cores.

85 at 1 mM or above destroyed the neurite-like processors and decreased the cell viability that paralle

86 First, processors and depletable resources should not be regard

87 Through a combination of novel optics, processors and filters, real-time high-resolution contra

88 are that can take advantage of both multiple processors and GPU-acceleration to perform the numerical

89 ull advantage of state-of-the-art multi-core processors and graphics cards, and is available as open-

90 ty to parallelize the work between available processors and is able to efficiently process millions o

91 e computing resources with a large number of processors and memory.

92 Computing (HPC) systems, which contain many processors and more memory than desktop computer systems

93 representation by the two independent speech processors and neural degradation of auditory pathways a

94 to a heterogeneous system consisting of x86 processors and NVIDIA GPUs.

95 g platform to bridge superconducting quantum processors and optical telecommunication channels.

96 lymphocytes, suggesting a role for microRNA processors and specific microRNAs in cell life/death dec

97 he needs of the nutraceutical industry, food processors and the consumers of fresh fruit.

98 uarantee authentic seafood products, seafood processors and traders must perform self-checks on the a

99 limiting the realization of scalable quantum processors and will provide fundamental insights into th

100 one adjustable time-lapse fluorescence image processor) and separation controller.

101 Telemetry, Tracking and Command, the Control Processor, and the Data Handling sub-subsystems.

102 ition from individual devices to large-scale processors, and the availability of a (28)Si form with n

103 LOSITAN is able to use modern multi-core processor architectures by locally parallelizing fdist,

104 Gate operations in a quantum information processor are generally realized by tailoring specific p

105 m networks, in which superconducting quantum processors are connected via optical links, will require

106 Integrated droplet microfluidic screening processors are poised to replace robotic automation by m

107 networks made of analog resistive switching processors are promising platforms for analog computing.

108 Two main ingredients of quantum information processors are quantum interference and single-photon de

109 If quantum information processors are to fulfill their potential, the diverse e

110 ility to move a product through the approval processor attract investment.

111 tems, R must be able to utilise the multiple processors available on these systems.

112 Tosi et al. present a design for a quantum processor based on electron-nuclear spins in silicon, wi

113 Processors based on a few qubits have been demonstrated

114 stem has often been thought of as a parallel processor because distinct regions of the brain process

115 omising candidate for implementing a quantum processor because of their potential for scalability and

116 tential applications in nanofluidic chemical processors, biomolecular separation and electrochemical

117 and distributing it across many information processors, both human and machine.

118 ecades have also seen the rise of multi-core processors, both in the central processing unit (CPU) an

119 d the vowel /alpha/ while a real-time signal processor briefly perturbed the pitch (100 cents, 400 ms

120 Subjects phonated while a real-time signal processor briefly perturbed their output pitch (speak co

121 e merged with the efficiency of neuromorphic processors, bringing the promise of embedded, intelligen

122 asing complexity in large-scale microfluidic processors, bubble logic provides an on-chip process con

123 experimentally on a superconducting quantum processor, building three-qubit gate reconstructions fro

124 ntum simulator--a special-purpose 'analogue' processor built using quantum bits (qubits)--would be in

125 thms, is trivial to distribute over multiple processors but is inherently inefficient.

126 isting modules that enable R to use multiple processors, but these are either difficult to use for th

127 ventional lens-based optical signal and data processors by several orders of magnitude.

128 ow-power, high-speed, special-purpose signal processors can be realized by spin-waves.

129 General-purpose processors can now contain many dozens of processor core

130 of qubits and beyond, at which scale quantum processors can outperform their classical counterparts i

131 oss micromechanical oscillators in a quantum processor, can be extended to sense forces beyond the st

132 a scalable, solid-state quantum information processor capable of operating at room temperature.

133 mental challenge is to build a high-fidelity processor capable of running quantum algorithms in an ex

134 restricted by the limited sampling rate and processor capacities of digital-to-analog convertor devi

135 logous to the search function in modern word processors, Cas9 can be guided to specific locations wit

136 be built by networking together many simple processor cells, thus avoiding the need to create a sing

137 great concern to prestigious Manchego cheese processors (Central Spain denomination of origin) becaus

138 gradient range for the actual COBE 2991 cell processor (COBE) purification is likely to maximize the

139 teractions that are available in our quantum processor, combined with a compact encoding of fermionic

140 tion of the main proteins belonging to miRNA processor complexes, reveals 66 high-confidence new geno

141 Herein, we present a programmable chemical processor comprising of a 5 by 5 array of cells filled w

142 y been used to demonstrate prototype quantum processors comprising a few tens of quantum bits.

143 Although this processor constitutes an important step in quantum compu

144 The retina is a tremendously complex image processor, containing numerous cell types that form micr

145 Conventional information processors convert information between different physica

146 In a 24-processor core configuration, CloudBurst is up to 30 tim

147 ng the computational burden between multiple processor cores and a graphics processing unit (GPU) sim

148 se processors can now contain many dozens of processor cores and support hundreds of simultaneous thr

149 e improves as a linear function of available processor cores.

150 ng the combined computational power of 8,400 processor cores.

151 g multiple orthogonal CRISPR/Cas9-based core processors could offer enormous computational capacity.

152 lopment of the deep-sea environmental sample processor (D-ESP).

153 short reads to the human genome per computer processor day.

154 introduction of photonics: while large-scale processors demand a modular implementation, coherency am

155 e transitions), using a D-Wave 2000Q quantum processor, demonstrated that RQA finds notably better so

156 m access superconducting quantum information processor, demonstrating universal operations on a nine-

157 e notion that these regions embody a central processor devoid of modality representation.

158 ddress here is whether the use of additional processors effectively reduces total computation time fo

159 grated microfluidic DNA-encoded library bead processors eliminates potentially cumbersome instrumenta

160 solution to this problem: an optical signal processor employing a group-delay-managed nonlinear medi

161 hnology as the VRNAT but contains an updated processor enabling complete automation, revealed the two

162 mmunications payloads powered by large-scale processors, enabling a dynamic allocation of hundreds of

163 gation protocol on a superconducting quantum processor, enhancing its computational capability, with

164 has pioneered a robotic Environmental Sample Processor (ESP) that overcomes some of the constraints a

165 mpler, a 2nd generation Environmental Sample Processor (ESP), was tested for autonomous analysis of e

166 A quantum processor executes algorithms by applying a programmable

167 applied to time-series data from any quantum processor experiment.

168 read pairs, and we then applied it as a pre-processor for genome assemblies of Illumina reads from t

169 Such an automated microfluidic tissue processor for in situ sequencing studies would greatly e

170 lding scalable, yet energy-efficient on-node processors for brain-chip interfaces.

171 can serve as a 'web' for connecting quantum processors for computation and communication, or as a 's

172 and sufficiently connected to bind multiple processors for efficient information transfer.

173 a computation engine that supports multicore processors for enhanced performance.

174 ortunities for building customized analog co-processors for solving hard problems efficiently.

175 ding molecular-scale quantum spin memory and processors for technological development.

176 tion for an unknown process on a multi-qubit processor from pairwise two-qubit tomographic data.

177 image processing software that uses graphics processors (GPUs) to address the most computationally in

178 The simulations, run using graphical processors (GPUs), were used to investigate the effect o

179 However, as these processors grow in size, standard process tomography bec

180 ealization of a scalable quantum information processor has emerged over the past decade as one of the

181 operty of a quantum processor, with an ideal processor having random access-the ability of arbitrary

182 The hydra image processor (HIP) is a new library providing hardware-acce

183 y 2-3.4 times compared with that of a single-processor implementation, with the number of processors

184 le of a bacterial transporter that acts as a processor in a transduction pathway.

185 dual-core CPU combining two orthogonal core processors in a single cell.

186 econdary function as sensors and information processors in signalling pathways.

187 tial improvement over the performance of the processors in the absence of error correction.

188 Performance scales with the number of processors in the cluster, allowing throughput to expand

189 three groups of fish act as adaptive sensory processors in which the signals conveyed by parallel fib

190 nd with near linear speedup as the number of processors increases.

191 These include micro-processor-independent biogenesis, pol-II-dependent trans

192 Concretely, an analog optoelectronic processor inspired by biological vision is developed, wh

193 Our quantum processor is a first step towards the surface code, usin

194 Building a quantum processor is challenging because of the need to meet sim

195 The fact that the scale of the processor is proportional to the wavelength of its signa

196 A microfluidic processor is used to separate the Watson and Crick stran

197 nvert these quantum devices from memories to processors, it is necessary to specify how a universal s

198 A typical SPADE analysis on a 2.27-GHz processor laptop takes approximately 5 min.

199 neral Likelihood Evaluator, a cross-platform/processor library for phylogenetic likelihood computatio

200 It is now affordable to buy a multi-processor machine, and easy to install Java and MySQL.

201 e can be readily implemented across multiple processors, making it adaptable for throughput sequencin

202 ly into native machine code for a variety of processors, making it appropriate for solving extremely

203 sing unit (CPU) and Graphics processing unit processor markets, enabling massively parallel computati

204 the meaning of time, speed, multiplicity of processors, memory, robustness of computation and hardwa

205 nge of new nanometric scale devices, such as processor-memory interconnections, devices with sensitiv

206 For a successful segmentation, a neural processor must capture envelope features associated with

207 Large-scale quantum information processors must be able to transport and maintain quantu

208 These processors must generate, incubate, and sort droplets fo

209 egulatory agencies, food producers, and food processors need accurate information about rates and cha

210 ectly implicates the amygdala as the primary processor of emotional information used by cortex to dri

211 We conclude that GBP-1 is a downstream processor of IFN-gamma via which T cells regulate cytosk

212 I transcription as a sensor, integrator, and processor of regulatory signals that converge on protein

213 le immunoproteasomes were first described as processors of antigen for presentation by major histocom

214 The cochlear nuclei are the first central processors of auditory information and provide inputs to

215 nsmitter receptor heteromers can function as processors of computations that modulate cell signaling.

216 les of multisite phosphorylation networks as processors of kinase signals.

217 nter streams and rivers, which are important processors of OC and conduits for carbon dioxide (CO2) t

218 s (470 and 217 Mb) in 120 CPU hours using 15 processors on a single machine.

219 ta are shared among a user-defined number of processors on a single multi-core machine or cluster.

220 al electronic solutions such as photonic pre-processors or accelerators, electronic-photonic hybrid c

221 Gradually introducing a speech processor parameter (eg, the degree of spectral mismatch

222 ceptor, screening 500 to 1,000 compounds per processor per day.

223 The programmable sample processor performs precise mixing, metering, and routing

224 dling characteristics, and magnetic particle processor programming all contributed to increased recov

225 We also implemented smallWig using multi-processor programming.

226 Quantum information processors promise fast algorithms for problems inaccess

227 erse applications, such as advanced computer processors, radio-frequency power devices, quantum casca

228 unprecedented demands on traditional single-processor read-mapping algorithms.

229 Large-scale quantum information processors require stable and addressable quantum memori

230 Scalable quantum processors require tunable two-qubit gates that are fast

231 authentication of food is important for food processors, retailers and consumers, but also for regula

232 rocessor (SDP) and the related rotating tube processor (RTP), are highlighted in the use of highly sh

233 tabase search processor and the mass spectra processor, running on a reconfigurable computing platfor

234 In this review the spinning disc processor (SDP) and the related rotating tube processor

235 al software implementation running on a dual processor server.

236 interfaces bypass a subject's clinical sound processor, several concerns exist regarding safety and s

237 32 nodes (each containing two Intel Haswell processors) shows reductions in execution time of over o

238 nomes to be loaded to memory, while multiple processors simultaneously map reads to the reference.

239 Using two graphics processors simultaneously, a typical 6D docking run take

240 fication and validation of candidate quantum processors, since it plays a key role in both performanc

241 chizophrenic conditions, implemented on a 72-processor supercomputer platform.

242 This processor supports parallel processing capability which

243 chieved on a dual Intel Xeon E5-2670 24-core processor system, the highest reported for an implementa

244 human-machine interfacing, smart sensor, and processor systems.

245 Our Sycamore processor takes about 200 seconds to sample one instance

246 e executed exponentially faster on a quantum processor than on a classical processor(1).

247 sses mounted with a small camera and a video processor that converted images into stimulation pattern

248 sses mounted with a small camera and a video processor that converted images into stimulation pattern

249 responsive TF Msn2 acted as a tunable signal processor that could track, filter, or integrate signals

250 sent a scalable design for a silicon quantum processor that does not require precise donor placement

251 Here, we introduce a CRISPR/Cas9-based core processor that enables different sets of user-defined gu

252 ntable devices with an externally worn sound processor that hosts the microphone and sound processor.

253 we demonstrate a two-qubit photonic quantum processor that implements two consecutive CNOT gates on

254 Here, we report a microfluidic tissue processor that permits accurate quantification of the ex

255 nted a hardware design of a raw mass spectra processor that, when implemented in Field Programmable G

256 ctored BLASTP algorithm for modern multicore processors that achieves much higher throughput with acc

257 ith up to 344 superconducting flux qubits in processors that have recently been shown to physically i

258 Expanding around the half-adder processor, the "butterfly" calculation process is demons

259 ally, using a prototypical quantum annealing processor, the ability of quantum annealers to sample th

260 CE STATEMENT In modern cochlear implant (CI) processors, the temporal information in speech or enviro

261 different sets of chromosomes using multiple processors, thereby enabling desirable scaling for futur

262 ted using SPRINT on an HPC resource of eight processors this computation reduces by more than three t

263 een mechanical systems and solid-state qubit processors, this paves the way for mechanical systems en

264 such as RPA in the presence of multiple DNA processors to better understand the associated mechanist

265 g at the high carrier pulse rates used in CI processors to deliver speech information.

266 ftware runs on multiple threads and multiple processors to increase the alignment speed.

267 cy, which would induce over-fortification by processors to obtain a minimum dose upon consumption.

268 oss of sensitivity is critical to allow food processors to safely decrease product holding time.

269 dom starting seed number, number of threads, processor type).

270 tion of accelerated calculations on graphics processor units and distributed computing to simulate te

271 processor implementation, with the number of processors used ranging from 2 to 8; in the same paramet

272 he realization of robust quantum information processors using electronic- and nuclear-spin qubits.

273 tum networks and on-chip quantum information processors using nanophotonic devices.

274 demonstration of quantum walks on a quantum processor, using superconducting qubits as artificial at

275 ve, given their respective roles as parallel processors versus discrete carriers of olfactory informa

276 In this study, a MS signal processor was developed to facilitate data integration f

277 robiology instrument, the Walk Away Specimen Processor (WASP), manufactured by Copan, Inc., in which

278 b was conducted using the Walk-Away specimen processor (WASP).

279 ng-machine consisting of a memory tape and a processor, we attempt to explore the link towards the fo

280 amics simulations in implicit solvent on GPU processors were used to generate ensembles of trajectori

281 ble Gate Arrays is the programmable photonic processor, where a common hardware implemented by a two-

282 as a result it can be used within a quantum processor, where coherences must be maintained.

283 lly-expressed genes using the Taverna RShell processor which has been developed for invoking this too

284 Recent advances in continuous-flow processors, which integrate sustainability metrics inclu

285 enes for structured motif extraction on 1056 processors, while current sequential tools require more

286 t are dense in directed paths are poor noise processors, while those that are sparse and strongly dir

287 Humans are selective information processors who efficiently prevent goal-inappropriate st

288 ing a highly reconfigurable photonic quantum processor with a conventional computer.

289 p 2.1 runs in approximately 45 s on a single processor with a sequence of length 10,000--a tremendous

290 We present a scalable optical processor with electronic feedback that can be realized

291 ver, building an error-corrected information processor with many such qubits will require solving spe

292 n-general, rather than word-specific, visual processor with no preferential functional connectivity w

293 ed to an implementation using Intel Xeon Phi processor with off-chip memory (with hypothetical on-chi

294 This optoelectronic processor with PPC memory mimics two core functions of h

295 Here we report the use of a processor with programmable superconducting qubits(2-7)

296 toward proof-of-concept quantum sensors and processors with high inherent structural precision.

297 could pave the way for superconducting qubit processors with multiplexed on-chip signal processing an

298 signed for 64 bit Linux, OS X, or Windows on processors with SSE2, SSE41, or AVX2.

299 tivity is an important property of a quantum processor, with an ideal processor having random access-

300 consecutive fashion by an automated cytology processor without fastidious decontamination precautions