ライフサイエンスコーパス: graphics

1 We call such graphical idioms "domain graphics".

2 as for the synthesis of images (for computer graphics).

3 ips and allows export of publication quality graphics.

4 ially understanding airway pressure and flow graphics.

5 P may be used to produce publication quality graphics.

6 ineable, with many new selection filters and graphics.

7 e browser as text, tables and interactive 3D graphics.

8 nment was used for statistical computing and graphics.

9 with a suite of existing tools for molecular graphics.

10 to output data files or publication-quality graphics.

11 products of a gene with the help of dynamic graphics.

12 The results are displayed in interactive graphics.

13 nvectors and depicted with three-dimensional graphics.

14 ive) and/or quantitative nature with quality graphics.

15 ts, none of which aligns with the reverse of graphics.

16 nced reference lists, and new protein domain graphics.

17 erades as a dead leaf with those of computer graphics.

18 ion of trajectories with publication quality graphics.

19 gnition to production of publication-quality graphics.

20 gh-resolution stereoscopic three-dimensional graphics.

21 llows for the convenient creation of various graphics.

22 data, as well as create publication quality graphics.

23 ers of interactivity that are behind bigPint graphics.

24 Curve for making decision curves and related graphics.

25 nd may promote widespread use of interactive graphics.

26 raries for web-based visualization using SVG graphics.

27 and their interactions in three-dimensional graphics.

28 stream analysis of results and visualization graphics.

29 oral honey types, particularly when using 3D graphics.

30 amework, which aims to facilitate the use of graphics accelerators for computational models of large-

31 th the choice of uniform or analytic heatmap graphics according to the local geometry.

32 Custom Node Graphics allow an image to be projected onto a node, inc

33 By using molecular graphics analysis, chimeric complementarity-determining

34 corporated in a draft brochure that included graphics and a glossary of terms.

35 Results were analyzed by using statistical graphics and analysis of variance.

36 duces two powerful new features--Custom Node Graphics and Attribute Equations--which can be used join

37 The mutants were characterized by molecular graphics and CD and found to have a minimum of structura

38 rt how computer artists, experts in computer graphics and cell biologists have collaborated to produc

39 High-performance graphics and data management allows users to simultaneou

40 cans using symbolic representation, improved graphics and fonts for web displays, improvements in the

41 ace with intuitive controls, high-resolution graphics and fully customizable appearance.

42 Here, we introduce u-shape3D, a computer graphics and machine-learning pipeline to probe molecula

43 lizations or can be exported as high-quality graphics and numerical tables which can be imported into

44 and link to the ALA spatial portal, improve graphics and provide the novel ability to analyze enviro

45 Also, it uses different R packages for graphics and R-markdown for generating progress reports.

46 d summaries are reported within a variety of graphics and reports, providing a simple way to do data

47 t that can be imported in the majority of 3D graphics and software packages.

48 ion strategies, and a rich set of exportable graphics and statistical reports.

49 application shows in a dashboard a series of graphics and tables designed to help researchers formula

50 manipulation of clones and sets of clones in graphics and tables provides a high level of interaction

51 The ability to display graphics and texts on a transparent screen can enable ma

52 The web interface, graphics and underlying codebase have also been refactor

53 Using algebra, graphics, and examples, we show that positive interactio

54 ions such as numerical integration, computer graphics, and finance.

55 ts linked with app-derived analytical tools, graphics, and tables.

56 ability, readability, message length, use of graphics, and verbal discussion.

57 Various guiding graphics are generated to help diagnose the performance

58 repetitive elements and other features; the graphics are linked to other World Wide Web pages, provi

59 This work suggests inverse graphics as a multiarea neural algorithm implemented wit

60 re environment for statistical computing and graphics available for most platforms.

61 principal component (PC), three-dimensional graphics based on virtual reality modeling language and

62 bly, this correspondence to the reverse of a graphics-based generative model also holds across the bo

63 sing methods, and, in a single user-friendly graphics-based package, takes raw data through the entir

64 We had previously developed a molecular graphics-based working model of the luciferase active si

65 hat simulate rich physics in video games and graphics, but that uses approximate, probabilistic simul

66 We believe that the principles of Trellis graphics can be adapted to provide useful visualizations

67 e web interface has powerful data mining and graphics capabilities for inter-genomic comparative anal

68 mparable computational improvement without a graphics card would require a large compute-cluster, an

69 type, and we expect the speed to increase as graphics cards continue to improve.

70 f state-of-the-art multi-core processors and graphics cards, and is available as open-source software

71 llaboratively developed CHARMM INterface and Graphics (CHARMMing) web user interface.

72 derstood, although the effectiveness of some graphics clearly depends on the relative numeracy of an

73 alable computational tools from the computer graphics community, we demonstrate 3D reconstruction of

74 nces include the development of a grammar of graphics, deeper understanding of human perception and i

75 kZ that can be compiled into scalable vector graphics described in a model.

76 ple sequence alignment editor to a molecular graphics display.

77 e viewed in a web browser or imported into a graphics-editing program.

78 bined into composite wide-angle images using graphics-editing software.

79 th native SVG rendering support or in vector graphics editors.

80 Genome browser styled graphics embedded in these reports help visualize the ge

81 In computer graphics, raster graphics encodes images on a single-pixel level, conferr

82 expense of large file sizes, whereas vector graphics encrypts shape information into vectors that al

83 tures a real-time high-performance molecular graphics engine, based on modern OpenGL, optimized for t

84 ProMOL is a plugin for the PyMOL molecular graphics environment that can be used to create active s

85 Interactive computer graphics examination of the AAV2 VP3 atomic coordinates

86 e mouse, rat, and human brain flatmap vector graphics files (Adobe Reader/Acrobat viewable and Adobe

87 s of local problems, as downloadable PDB and graphics files, and most notably as informative, manipul

88 ic scores, as lists, as downloadable PDB and graphics files, and most notably as informative, manipul

89 ve, highly customizable, publication-quality graphics focused on annotating each gene fusion at the t

90 ing highly customizable, publication-quality graphics focused on cohort level genome analyses.

91 icular existing gene feature formats meaning graphics for any existing datasets can easily be created

92 SBML2TikZ supports automatic generation of graphics for biochemical models in the popular TeX types

93 compound classes, and can export raw data or graphics for off-line use.

94 onstrates how dynamic alternatives to static graphics for small sample size studies allow for additio

95 stered heatmaps are the most frequently used graphics for visualization of molecular profiling data i

96 aphics, rastered images and in-line streamed graphics for webpages.

97 Networks can be saved as a Scalable Vector Graphics format.

98 d tool enables authors to create interactive graphics from data obtained with repeated independent ex

99 Concluding the work with analysis of graphics from the Blast2go program.

100 A variety of graphics functions are implemented to easily plot numeri

101 , reading speed (g = - 0.82, p = 0.0001) and graphics gesture (g = - 0.59, p = 0.0001).

102 A concise text html-linked to interactive graphics guides the reader through the main features of

103 es original fluorescence intensity values on graphics hardware, a crucial feature that allows graphic

104 Ceiba exploits recent improvements in graphics hardware, OpenGL toolkits and many standard hig

105 , and we provide a fast implementation using graphics hardware.

106 Additionally, in-line graphics have been developed for specific analysis types

107 Further, the output tables and graphics have been improved based on user feedback and n

108 These graphics have detected normalization issues, differentia

109 Interactive graphics have the potential to transform scientific publ

110 gs and scenes that can be rendered as raster-graphics images, allowing for easy generation of publica

111 terative contour smoothing and generation of graphics in a easy to use graphical user interface.

112 terative contour smoothing and generation of graphics in an easy to use graphical user interface with

113 role of principal components and statistical graphics in the generation of pattern claims and hypothe

114 s then allow for live customisation of these graphics, including on-the-fly selection of visualisatio

115 g expertise to create customized interactive graphics, including univariate scatterplots, box plots,

116 HyperText Markup Language (HTML) and/or the Graphics Interchange Format (GIF), which are returned to

117 of investigations and visualizations from a graphics interface.

118 ession analyses by incorporating statistical graphics into their usual analysis pipelines, 2) develop

119 drawing, which can be a mixture of text and graphics, into the HyperText Markup Language (HTML) and/

120 ange in the way that the role of statistical graphics is thought of within science-as a dynamic partn

121 script of TeX macro commands for the vector graphics languages PGF/TikZ that can be compiled into sc

122 tion utilizing Standard Widget Toolkit/Swing graphics libraries and a SQLite database for performing

123 JavaScript; Web technology: Scalable Vector Graphics; Libraries: D3.js.

124 ap, an efficient BAM file viewer utilizing a graphics library and BAM indexing.

125 al resource on nuclear receptors termed the 'Graphics Library'.

126 omputer vision, machine perception, computer graphics, machine learning, and simulation.

127 en the proteins was generated using computer graphics methods.

128 information to both the alignment editor and graphics model in the form of visual cues (color, shape)

129 lts are placed in the context of a molecular graphics model of the TM domain of rhodopsin, which incl

130 as realistic 3D animations using a computer-graphics model.

131 onserved residues were analyzed by molecular graphics modeling to demonstrate their intramolecular in

132 By molecular graphics modeling, we show that the diphosphate group of

133 A population of 100 graphics models of the human 5-HT6 serotonin receptor wa

134 Using computer graphics models of the human TrkA and TrkC immunoglobuli

135 The user can also use the graphics module to visualize QGRS distribution patterns

136 re parametrically generated using a computer graphics morphing system that allowed precise control ov

137 s software available to generate linkage map graphics, none are freely available, produce publication

138 of DSSR and Jmol/JSmol brings the molecular graphics of 3D RNA structures to a similar level as that

139 Lithophane graphics of Fischer-Spier esterification reactions and e

140 Kinetic parameters were determined from graphics of linear Michaelis-Menten equation, and it was

141 ed input files to display pathways in vector graphics on any web-page providing flexible layout optio

142 evidence supports use of human stick figure graphics or faces for single probabilities and vertical

143 on, and is part of the widely used molecular graphics package UCSF CHIMERA (University of California,

144 CHOIRBM is built on the popular R graphics package, ggplot2, which facilitates further dev

145 of the protein structure, and in a molecular graphics package, integrated for interactive viewing.

146 ion is available that allows users to modify graphics parameters and produces a LaTeX output.

147 Using a unique computer graphics platform that combines generative grammars with

148 ate of new cases in a stable period, and the graphics plotted with the significant governmental decis

149 es at their disposal, and recent advances in graphics processing unit (GPU) computing have added a pr

150 Graphics processing unit (GPU) computing is an affordabl

151 A Graphics Processing Unit (GPU) implementation and downsa

152 aster than qcprot and 3x faster than current graphics processing unit (GPU) implementations.

153 ice for fast MicroRNA-Seq data analysis in a graphics processing unit (GPU) infrastructure.

154 urden between multiple processor cores and a graphics processing unit (GPU) simultaneously.

155 image classification network, relative to a graphics processing unit (GPU) that uses a comparable 12

156 ents those methods in a parallel manner on a graphics processing unit (GPU) using CUDA platform.

157 Using a general-purpose graphics processing unit (GPU), we have developed GPU-BL

158 multicore architecture of a modern consumer graphics processing unit (GPU), we report a 92x increase

159 arallelism present in modern traditional and graphics processing unit (GPU)-accelerated machines, fro

160 Here the graphics processing unit (GPU)-accelerated MMseqs2 deliv

161 With graphics processing unit (GPU)-based CUDA C/C++ implemen

162 cence lifetimes, Stokes shifts, and extended graphics processing unit (GPU)-based quantum mechanics/m

163 thm for parallel execution on an NVIDIA V100 graphics processing unit (GPU).

164 lculation of ESP and (ii) its mapping onto a graphics processing unit (GPU).

165 emerging and readily available in the recent graphics processing unit (GPU).

166 Efficiently harnessing graphics processing unit acceleration along with systema

167 to-use Python software package and leverages graphics processing unit acceleration when available.

168 ffects, stochastic variational inference and graphics processing unit acceleration.

169 l cardiac cine series took 610 msec with the graphics processing unit and 5.6 seconds with central pr

170 The mass production of the graphics processing unit and the coronavirus disease 201

171 Practical benefits varied across different graphics processing unit architectures, with more distin

172 Our graphics processing unit based software delivers haploty

173 erates optimized central processing unit and graphics processing unit code variations, learning and p

174 -dimensional image-based registration with a graphics processing unit enhances processing speed 10- t

175 The Graphics Processing Unit implementation of the algorithm

176 oth in the central processing unit (CPU) and Graphics processing unit processor markets, enabling mas

177 Implementation of these algorithms for the graphics processing unit results in dramatic speedup of

178 tic model: the Bayesian network algorithm, a graphics processing unit version of the Bayesian network

179 rallel computational power of a programmable graphics processing unit with the flexibility of the dyn

180 MEDUSA uses GPU (graphics processing unit) accelerated hardware and a par

181 Our theoretical model is implemented in GPU (Graphics Processing Unit) accelerated software which can

182 < .001); inference run time of 0.99 second (graphics processing unit) and 2.27 seconds (central proc

183 PU threads and multiple GPU (general-purpose graphics processing unit) devices.

184 the rapid development of massively parallel Graphics Processing Unit, i.e. the GPU computing technol

185 iology, we previously developed emClarity, a graphics processing unit-accelerated image-processing so

186 dial fluctuations (SRRF), provided as a fast graphics processing unit-enabled ImageJ plugin.

187 method, we parallelized the computation on a graphics processing unit.

188 odestly powered computers lacking a discrete graphics processing unit.

189 ,000 structures per day on a server with one graphics processing unit.

190 20 x 1,080 pixels on a single consumer-grade graphics processing unit.

191 tems in approximately one second on a single graphics processing unit.

192 ut losing calculation precision on an NVIDIA graphics processing unit.

193 st possible greedy algorithms accelerated on Graphics Processing Units (GPU), scaled magnetic version

194 ultiple target hardware platforms, including Graphics Processing Units (GPUs) and Field Programmable

195 rt all BLS parameters that take advantage of graphics processing units (GPUs) and result in many fold

196 Graphics processing units (GPUs) are capable of efficien

197 e algorithm is implemented on ATI and nVidia graphics processing units (GPUs) for maximal speed.

198 new software tool STOCHSIMGPU that exploits graphics processing units (GPUs) for parallel stochastic

199 f traditional CPU computing infrastructures, Graphics Processing Units (GPUs) offer opportunities to

200 Graphics processing units (GPUs) provide an inexpensive

201 Although graphics processing units (GPUs) provide high performanc

202 paper is adding a full support for multiple graphics processing units (GPUs) support, which makes it

203 By using graphics processing units (GPUs) the time needed to buil

204 on with [Formula: see text], we use multiple graphics processing units (GPUs) to compute the real fre

205 ed code via multiple threads in parallel, on graphics processing units (GPUs) using NVidia Compute Un

206 lel computing hardware including inexpensive graphics processing units (GPUs), it has remained infeas

207 r arbitrary molecular evolutionary models on graphics processing units (GPUs), making use of the larg

208 eneral-purpose libraries for computing using graphics processing units (GPUs), such as PyTorch and Te

209 Graphics processing units (GPUs), the hardware responsib

210 Thanks to a very intensive use of graphics processing units (GPUs), we have been able to r

211 t multiple CPU cores but also one or several graphics processing units (GPUs).

212 ons using consumer or high performance grade graphics processing units (GPUs).

213 We developed deoxyribozyme-based graphics processing units able to monitor nucleic acids

214 mpute Unified Device Architecture-compatible graphics processing units and deep learning techniques s

215 to parallel computing architectures, such as graphics processing units by illustrating its utility fo

216 Our novel, efficient algorithm using graphics processing units can accurately characterize bo

217 we demonstrate that parallel computation on graphics processing units can reduce the processing time

218 ning read-outs of molecular states that uses graphics processing units made from molecular circuits.

219 entional general-purpose processors, such as graphics processing units or central processing units.

220 These molecular graphics processing units provide insight for the constr

221 d with CPU + GPU (Central Processing Units + Graphics Processing Units) heterogeneous parallel comput

222 ness the computational power of NVIDIA GPUs (Graphics Processing Units) to greatly reduce processing

223 fits regularized regression across multiple Graphics Processing Units.

224 tate-of-the-art digital counterparts such as graphics processing units.

225 ined and a coarse-grained parallelization on Graphics Processing Units.

226 it is now possible to exploit the power of a graphics-processing unit (GPU) from a browser without an

227 -time data processing being accelerated by a graphics-processing unit.

228 nitude greater than that of state-of-the-art graphics-processing units, and is shown to be scalable t

229 hics hardware, a crucial feature that allows graphics-processing-unit (GPU)-based processing for inte

230 a combination of accelerated calculations on graphics processor units and distributed computing to si

231 e RELION image processing software that uses graphics processors (GPUs) to address the most computati

232 Using two graphics processors simultaneously, a typical 6D docking

233 ased protein docking server to be powered by graphics processors.

234 It is accompanied by an Excel-based graphics program.

235 e files, for subsequent visualization with a graphics program.

236 Views can be exported to vector graphics programs to generate high-quality figures for p

237 l intervention in three-dimensional computer graphics programs(1,2).

238 oach that combines state-of-the-art computer graphics, psychophysics and vision science, cultural psy

239 ly, requirements for constructing a computer graphics quantitative intrahippocampal flatmap, with acc

240 In computer graphics, raster graphics encodes images on a single-pix

241 used to generate publication-quality vector graphics, rastered images and in-line streamed graphics

242 show how the separation between physics and graphics relies on a natural division of labor in any co

243 It serves high-quality protein graphics rendered with UCSF Chimera molecular visualizat

244 wser's performance, with improved scripting, graphics rendering, and painting performance.

245 rch tools for organism communities, improved graphics rendering, faster performance and re-designed g

246 cessability, eighth-grade reading level, and graphics resulted in significantly greater gist and verb

247 lications in image-based rendering, computer graphics, robotics, photo interpretation, image retrieva

248 In addition, shinyGEO supports customized graphics, sample selection, data export and R code gener

249 cture annotations containing formatted text, graphics, sequence data, and interactive molecular views

250 We emphasize that interactive graphics should be an indispensable component of modern

251 ably as informative, manipulable 3D kinemage graphics shown on-line in the KiNG viewer.

252 ably as informative, manipulable 3D kinemage graphics shown online in the KiNG viewer.

253 T is compatible with commonly used molecular graphics software packages such as UCSF Chimera and VMD.

254 n the MATLAB and R statistical computing and graphics software platforms.

255 tic equiaxed grain structures using computer graphics software to explore the relationship between va

256 By using common graphics software, e.g., CorelDRAW or AutoCAD, the proto

257 alised on a protein using existing molecular graphics software.

258 bodies as a case study, we show that inverse graphics spontaneously emerges in inference networks tra

259 chapter traces the evolution of statistical graphics starting with its departure from the common nou

260 and many standard high-performance computer graphics strategies, such as texture compression, level

261 developing new web pages, export formats and graphics styles.

262 enerates not only certain useful distinctive graphics such as the plate-well series plot, plate image

263 By providing interactive graphics support to software containers, our modular pla

264 ard input format (SBGN), high-quality output graphics (SVG format) convenient for both interpretation

265 allows users to generate high-quality vector graphics (SVG) and integrate it into web pages.

266 Pedigree output in scalable vector graphics (SVG) format can be viewed in browsers with nat

267 Scalable Vector Graphics (SVG) format is a modern and flexible open stan

268 ic, which can be exported in Scalable Vector Graphics (SVG) format.

269 ic images or high-resolution Scalable Vector Graphics (SVG).

270 nion web application built on the grammar of graphics system.

271 Hand tremor was quantified with a graphics tablet in three different labs, an acceleromete

272 Interactive graphics techniques were used to orient the TCR on the D

273 e steps can be operationalized, using simple graphics that articulate how populations are defined, sa

274 am creates an output file as scalable vector graphics that can then be viewed in a web browser or imp

275 be three-dimensionally printed into tactile graphics that glow with video-like resolution via the li

276 ncourage authors to avoid bar graphs and use graphics that show the data distribution; however, they

277 algorithm, along with programs that generate graphics that visually present alignment information.

278 nal perspective on the early use of computer graphics to communicate the intricacies, interactions, a

279 Researchers can apply bigPint graphics to their data by following recommended pipeline

280 ithm to compute synteny blocks and Web-based graphics to visualize the results.

281 p, bar-graph and colored secondary structure graphics; to leverage these data to generate secondary s

282 esentations of object shape, uses a computer graphics toolkit and a human hand simulator to map from

283 gging behind; for example, current molecular graphics tools lack built-in support even for base pairs

284 and integrated with DNA design and molecular graphics tools.

285 ization with 5 standard and high-dimensional graphics tools.

286 radigm shift currently under way in computer graphics towards the use of more realistic global illumi

287 SurreyFBA includes JyMet, a graphics user interface allowing spreadsheet-based model

288 The Web-based graphics uses Java for a highly interactive display that

289 web pages that include interactive molecular graphics using the freely-available applet, Jmol, for il

290 ructure/sequence alignment via the molecular graphics viewer Cn3D.

291 The service uses the Cn3D molecular graphics viewer to present a 3-D view of the known struc

292 be indicated and visualized by Java-based 3D graphics viewers and the structural and evolutionary pro

293 Molecular graphics views of homology models for the separate CR2 S

294 mponents are routinely featured in molecular graphics visualizations.

295 Using computer graphics, we generated stimuli that varied along two phy

296 In order to illustrate the power of such graphics, we have built a reusable interface based on th

297 re environment for statistical computing and graphics, we introduce an integrated solution for the an

298 are reported in various web-based tables and graphics, with automated viewing of the structure-sequen

299 ask software program and a three-dimensional graphics workstation, CT scans were analyzed to define t

300 CT lung densitometry and a three-dimensional graphics workstation.