ライフサイエンスコーパス: hyperspectral imaging

1 This can be achieved by hyperspectral imaging.

2 rated fatty acids can be detected using CARS hyperspectral imaging.

3 r spatial inhomogeneity with the help of the hyperspectral imaging.

4 root and shoot, as indicated by optical and hyperspectral imaging.

5 ings has been determined using near infrared hyperspectral imaging.

6 elopment, principles and applications of NIR hyperspectral imaging.

7 salmon fillets using near-infrared (Vis-NIR) hyperspectral imaging.

8 ks were identified using cathodoluminescence hyperspectral imaging.

9 ates the impact of algorithmic processing of hyperspectral imaging acquisitions on the sensitivity an

10 lueberry (Bluecrop, Jersey, and Liberty) for hyperspectral imaging analysis, firmness measurement, an

11 Thus, near infrared hyperspectral imaging arises as an attractive strategy f

12 Near infrared hyperspectral imaging arises as an attractive strategy f

13 ure simultaneously dissolved iron and DRP by hyperspectral imaging at a submillimeter resolution.

14 Hyperspectral imaging can be adapted to measure and map

15 Here, secondary electron hyperspectral imaging can be exploited for direct imagin

16 a combination of plasmonic dimer probes and hyperspectral imaging can be used to detect and quantify

17 Hyperspectral imaging can be used to distinguish signals

18 The generalization ability of hyperspectral imaging combined with neural networks (NN)

19 Visible-reflectance hyperspectral imaging demonstrates (1) a significant dec

20 enhanced dark-field microscopy combined with hyperspectral imaging (DF-HSI).

21 ded images at near video rate, time-resolved hyperspectral imaging facilitates monitoring renal blood

22 els by using intravital bright-field images, hyperspectral imaging, fluorescence recordings of direct

23 Near infrared hyperspectral imaging has been applied to grape seeds in

24 Hyperspectral imaging has been used to classify red grap

25 Our results show that hyperspectral imaging holds promise as a reliable and ra

26 Hyperspectral imaging (HSI) combines Near-infrared (NIR)

27 ransmission optical microscope fitted with a hyperspectral imaging (HSI) spectrometer.

28 Two lab-scale hyperspectral imaging (HSI) systems were employed for mo

29 Hyperspectral imaging (HSI) techniques are useful for ob

30 Here we take advantage of hyperspectral imaging (HSI), which records full-spectrum

31 It was demonstrated that hyperspectral imaging is a potential tool for determinin

32 Electron paramagnetic resonance (EPR) hyperspectral imaging is a powerful technique able to ch

33 hemia, evaluated by laser Doppler as well as hyperspectral imaging, limited blood flow and lowered ti

34 da) imaging system that leverages a snapshot hyperspectral imaging method, image mapping spectrometry

35 ed an intuitive color-coding scheme based on hyperspectral imaging methods to generate a single overv

36 A multivariate hyperspectral imaging (MHI) instrument has been designed

37 We used medical hyperspectral imaging (MHSI) to investigate the haemoglo

38 istration of the data cubes from these three hyperspectral imaging modalities enabled the comparison

39 Here we study ground hyperspectral imaging of artificial light sources as a c

40 , verified and used high-definition infrared hyperspectral imaging of cartilage sections at physiolog

41 We performed ~40-nanometer-resolution hyperspectral imaging of indium phosphide nanowires via

42 NIR hyperspectral imaging provides NIR spectral data as a se

43 Alternatively, application of a novel, hyperspectral imaging scanner and multivariate curve res

44 new ultra-compact spectrometers and low-cost hyperspectral imaging sensors in mid-infrared region.

45 pose of this study was to develop and test a hyperspectral imaging system (900-1700 nm) to predict in

46 corded at harvest time using a near infrared hyperspectral imaging system (900-1700 nm).

47 ripening were recorded using a near infrared hyperspectral imaging system (900-1700 nm).

48 rm is a novel combination of a near-infrared hyperspectral imaging system coupled with a conventional

49 We characterize a visible reflectance hyperspectral imaging system for noninvasive, in vivo, q

50 eloped a pushbroom visible and near-infrared hyperspectral imaging system in the wavelength range of

51 We report use of a novel hyperspectral imaging system utilizing digital light pro

52 ing back-reflected light from tissues to the hyperspectral imaging system.

53 re imaged with a fundus camera attached to a hyperspectral imaging system.

54 This study aimed to use the hyperspectral imaging technique as a non-destructive too

55 The results showed that Vis-NIR hyperspectral imaging technique combined with PLSR calib

56 ce a novel noninvasive, visible-reflectance, hyperspectral imaging technique for quantifying the perc

57 In this study a near-infrared (NIR) hyperspectral imaging technique was investigated for non

58 Hyperspectral imaging techniques such as matrix-assisted

59 the utility of persistent synoptic longwave hyperspectral imaging to study the ongoing leakage of re

60 the far-field, e.g., for classification and hyperspectral imaging, to nanoscale PTIR spectra.

61 The present study demonstrated that hyperspectral imaging was a useful tool for non-destruct

62 NIR hyperspectral imaging was evaluated to classify maize ke

63 The results obtained with hyperspectral imaging were compared with known experimen

64 DLP Hyperspectral Imaging with active spectral illumination

65 de dermoscope that combines polarization and hyperspectral imaging with an efficient analytical model

66 Hyperspectral imaging with enhanced darkfield microscopy

67 IR throughput considerably, making nanoscale hyperspectral imaging within a reasonable time frame pos