ライフサイエンスコーパス: optical component

1 eeform optic and a metasurface into a single optical component.

2 rove probe handling and protect the internal optical components.

3 d can be implemented with low loss using few optical components.

4 d cradle held the smartphone integrated with optical components.

5 performed using free-space optics with bulky optical components.

6 pathogen detection with low-cost and compact optical components.

7 ution laser polarimeter built from commodity optical components.

8 ifically the table-top fabrication of planar optical components.

9 e miniaturization and integration of THz and optical components.

10 lasmon polaritons and two-dimensional chiral optical components.

11 , tunable plasmonic tweezers, and integrated optical components.

12 e, a tiny magnetic stirrer and a few passive optical components.

13 er and assembled with commercially available optical components.

14 ing to more compact, efficient and versatile optical components.

15 etic modes can be exploited to build compact optical components.

16 ound light, and differential transmission of optical components.

17 icant impact on the quality of laser written optical components.

18 o isolate and stabilize different chip-scale optical components.

19 orders of magnitude using only conventional optical components.

20 elationship and relative strength of the two optical components.

21 r forming inexpensive, monolithic integrated optical components.

22 tion to integrating silicon electronics with optical components.

23 rom the dimensions of commercially available optical components.

24 deep brain structures is to insert miniature optical components.

25 device is composed of affordable commercial optical components and a smartphone.

26 with respect to SPR in the tolerance of the optical components and alignment, the low material usage

27 is based on off-the-shelf, easy-to-assemble optical components and an ImageJ plugin library for OPT

28 ronic approach eliminates the need for bulky optical components and cameras for monitoring.

29 SPEED microscopy does not depend on complex optical components and can be implemented onto a standar

30 iSCAT microscope from commercially available optical components and demonstrate its compatibility wit

31 commercially-available parts (plus standard optical components and extra-cavity accessories) as well

32 remained a challenge for metasurfaces-based optical components and imagers.

33 ons of visual acuity, refractive errors, and optical components and measurement of choroidal thicknes

34 field of optics by reducing the thickness of optical components and merging multiple functionalities

35 expanded rapidly with advances in miniature optical components and molecular engineering.

36 imaging enables both new physical layouts of optical components and new algorithms to be implemented.

37 atform allows for further miniaturization of optical components and offers a scalable route toward im

38 potential for use in the design of new soft optical components and organic sunscreens.

39 ting the resolution limits of the individual optical components and resulting design aspects are disc

40 easing detection channels requires expensive optical components and/or critically increases imaging t

41 erry Pi cameras and computers, off-the-shelf optical components, and 3D-printed parts to make a batte

42 ty, refractive error, characteristics of the optical components, and features of the fovea were compa

43 Visual acuities, optical components, and macular thicknesses were measure

44 Best-corrected visual acuity, optical components, and optical coherence tomography fin

45 nanophotonics for the development of on-chip optical components, and solutions incorporating direct-b

46 s, collimators for light sources, integrated optical components, and spectrometers.

47 amplification, lack of reliance on expensive optical components, and the ability to sequence long fra

48 s, and mobile cameras, requires creating new optical component architectures.

49 r potential advantages in replacing existing optical components are discussed.

50 roles of vertical misalignment of the eye's optical components are explained in the following findin

51 Conventional optical components are limited to size scales much large

52 al horopter, is less relevant when the eye's optical components are misaligned.

53 Human eyes' optical components are misaligned.

54 with double-sided adhesive tape) and all the optical components are mounted on a 10cmx10cm portable p

55 system consisting of expensive detectors and optical components are needed.

56 r-friendly experience; alignments of on-chip optical components are predetermined during fabrication

57 lace of conventional materials for improving optical components as well as realizing new optical func

58 f Ag nanowires with other active and passive optical components, as well as Ag nanowire based optical

59 a highly promising platform for the passive optical components, but integrated light sources are lim

60 es on recent developments on flat, ultrathin optical components dubbed 'metasurfaces' that produce ab

61 nd nonlinear material is isolated from other optical components, efficiently avoiding thermal damage

62 nabled the increasing performance demands of optical components fabricated from glass-based optical m

63 multiplexed identification while minimizing optical components for affordable POC use.

64 The use of small optical components for both thermocycling and multiplexe

65 ving high-precision metrology, inspection of optical components for EUV lithography, and microscopy a

66 gh-performance preconcentration elements and optical components for fluorescence measurement of speci

67 urement sciences, but precise fabrication of optical components for high-performance biosensing has n

68 Nanoantennas are key optical components for light harvesting; photodiodes con

69 or increasing information density of compact optical components from the degree of freedom of angle.

70 rong push for chip-scale integration of such optical components has necessitated ultracompact, planar

71 anoantennas is of interest for subwavelength optical components in nano-optical circuits and metasurf

72 interest in developing silicon-based active optical components in order to leverage the infrastructu

73 r lens thickness are the main changes in the optical components in these patients.

74 However, these optical components inherently exhibit chromatic behavior

75 Integration of optical components into microfluidic devices can enhance

76 ectrical and photonic integration of quantum optical components is crucial for scalable solid-state q

77 pes of imaging systems that replace standard optical components like lenses with cleverly designed co

78 Optical components made fully or partially from reconfig

79 sers, and integration and miniaturization of optical components, makes the search for an easy-to-craf

80 on of the spectrograph to incorporate larger optical components, making it a costly and cumbersome op

81 asurements are realized with a single set of optical components mounted on a goniometer.

82 roscopy platform designed to accommodate the optical components necessary for an mmTIRFM.

83 ) offers a geometrical approach in designing optical components of any shapes.

84 al hypoplasia and the characteristics of the optical components of the eye in patients with familial

85 res accurate alignment of photoreceptive and optical components on a curved surface.

86 optoelectronic catheter system incorporating optical components on the probe, encapsulated by soft bi

87 vices, which integrate thousands of distinct optical components on-chip, are carefully tailored to ac

88 This platform is independent of the complex optical components or cavities that tend to constrain fu

89 Flat optical components, or metasurfaces, have transformed op

90 Micro-scale optical components play a crucial role in imaging and di

91 olithic platform by involving a multitude of optical components ranging from lasers to modulators, to

92 Conventional optical components rely on gradual phase shifts accumula

93 The design of achromatic optical components requires materials with high transpar

94 With the push towards miniaturization of optical components, static metasurfaces are used as comp

95 ization, and it doesn't require any external optical components such as external lenses and filters.

96 re measured using sequential arrangements of optical components such as lenses, filters, and beam spl

97 Conventional optical components such as lenses, waveplates and hologr

98 fic frequency involving addition of only few optical components such as liquid crystal polarizers to

99 structure consists of commercially available optical components such as polarizers and mirrors, and t

100 components are continually becoming smaller, optical components suitable for integration--such as LED

101 cs have produced ultrathin, so-called 'flat' optical components that beget abrupt changes in these pr

102 Metasurfaces are versatile optical components that can distribute the optical power

103 The McMOA has improved optical components that integrate 405 nm laser excitatio

104 benign, inexpensive, and scalable to produce optical components that will find uses in efficiency-lim

105 he metamaterial can be integrated with other optical components this work opens up the intriguing pos

106 vel familiarity with laser beam steering and optical components, this protocol can be completed in a

107 ireball model of GRBs, we attribute this new optical component to internal shocks driven into the bur

108 ot require any lenses, lasers or other bulky optical components to achieve phase and amplitude imagin

109 alyte, thereby reducing the need of multiple optical components to capture the entire frequency range

110 t by using GRIN lenses in cascade with other optical components to enable extra functionality in comm

111 erimental setup based on diffraction-limited optical components to launch and collect a broad angular

112 film interference filters, gratings or other optical components used for spectral multiplexing/demult

113 eliminate the need for bulky mechanical and optical components used in traditional spectrometers and

114 At telecom wavelengths, miniaturization of optical components via photonic integration has pushed t

115 nd this behavior, the light path through the optical components was simulated with consideration of t

116 ce between metasurfaces and traditional flat optical components, we employ arrays of Au pillar-suppor

117 um beams are generated using free-space bulk optical components where the fastest reconfiguration of

118 gnetometry at ambient conditions without any optical components, which brings it one step closer to a

119 s are employed to enhance the performance of optical components while minimizing their size.

120 ntegration of silicon-based electronics with optical components will therefore require optically acti

121 tensity modulation, by integrating thin-film optical components with delta waveguides using microfabr

122 serve as a promising platform for versatile optical components with desirable properties and functio

123 hus enabling lithographically patterned flat optical components with functionalities controlled by de

124 tly interface diffraction-limited dielectric optical components with nanophotonic structures.

125 e-scale penetration will require lightweight optical components with small aberrations.

126 s, and provide a strategy for designing nano-optical components with unique functionalities.

127 The presented approach precisely combines optical components within 3D space to achieve thin lens