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Journal articles on the topic 'Holographic imaging'

Author: Grafiati
Published: 4 June 2021
Last updated: 6 February 2022

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1

Shang, Guanyu, Zhuochao Wang, Haoyu Li, Kuang Zhang, Qun Wu, Shah Burokur, and Xumin Ding. "Metasurface Holography in the Microwave Regime." Photonics 8, no. 5 (April 22, 2021): 135. http://dx.doi.org/10.3390/photonics8050135.

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Hologram technology has attracted a great deal of interest in a wide range of optical fields owing to its potential use in future optical applications, such as holographic imaging and optical data storage. Although there have been considerable efforts to develop holographic technologies using conventional optics, critical issues still hinder their future development. A metasurface, as an emerging multifunctional device, can manipulate the phase, magnitude, polarization and resonance properties of electromagnetic fields within a sub-wavelength scale, opening up an alternative for a compact holographic structure and high imaging quality. In this review paper, we first introduce the development history of holographic imaging and metasurfaces, and demonstrate some applications of metasurface holography in the field of optics. We then summarize the latest developments in holographic imaging in the microwave regime. These functionalities include phase- and amplitude-based design, polarization multiplexing, wavelength multiplexing, spatial asymmetric propagation, and a reconfigurable mechanism. Finally, we conclude briefly on this rapidly developing research field and present some outlooks for the near future.
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2

Do, Cuong Manh, and Bahram Javidi. "Three-dimensional computational holographic imaging and recognition using independent component analysis." Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 464, no. 2090 (November 27, 2007): 409–22. http://dx.doi.org/10.1098/rspa.2007.0167.

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We present computational holographic three-dimensional imaging and automated object recognition based on independent component analysis (ICA). Three-dimensional sensing of the scene is performed by computational holographic imaging of the objects using phase-shifting digital holography. We used principal components analysis to reduce data dimension and ICA to recognize the three-dimensional objects. In this paper, kurtosis maximization-based algorithm is used. To the best of our knowledge, this paper is the first to report using ICA in three-dimensional imaging technology.
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Zong, Hua, He Zhang, and Jinghui Qiu. "Accurate Imaging of Wide Beam Active Millimeter Wave Based on Angular Spectrum Theory and Simulation Verification." Photonics 8, no. 9 (September 17, 2021): 397. http://dx.doi.org/10.3390/photonics8090397.

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Due to the fact that a millimeter-wave (MMW) has a strong ability to penetrate clothing, MMW holographic imaging technology can conduct a non-contact inspection of the human body’s surface. In recent years, personnel surveillance systems utilizing MMW holographic imaging technology has achieved rapid progress. However, limited by MMW holographic imaging’s image quality, the existing imaging technology cannot accurately detect whether the human body carries hidden objects. Additionally, real-time inspection requirements cannot be practically satisfied, and the system cost is relatively high. In this paper, a reconstruction algorithm with enhanced imaging quality, which can solve the problem of spherical wave attenuation with distance, making imaging results more accurate. The sampling conditions and imaging resolution are simulated and analyzed, which verify the azimuth resolution. Furthermore, the antenna beam’s holographic imaging simulation is optimized, effectively improving the quality of the reconstructed image. The proposed scheme provides theoretical support for determining antenna step and scanning aperture size in engineering and have theoretical guiding significance for improving the image quality of millimeter-wave holography and reducing system cost.
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4

Itoh, K., and Y. Ohtsuka. "Holographic spectral imaging." Journal of the Optical Society of America A 3, no. 8 (August 1, 1986): 1239. http://dx.doi.org/10.1364/josaa.3.001239.

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5

Anderson, M. F. "Holography in Medical Imaging-A Novel Holographic Camera/Viewer." Journal of Photographic Science 37, no. 3-4 (May 1989): 149–50. http://dx.doi.org/10.1080/00223638.1989.11737033.

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6

Qiu, Tianhui, Lixin Xia, Hongyang Ma, Chunhong Zheng, and Libo Chen. "Electromagnetically induced holographic imaging." Optics Communications 358 (January 2016): 20–23. http://dx.doi.org/10.1016/j.optcom.2015.09.018.

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7

Gölzhäuser, A., B. Völkel, B. Jäger, M. Zharnikov, H. J. Kreuzer, and M. Grunze. "Holographic imaging of macromolecules." Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films 16, no. 5 (September 1998): 3025–28. http://dx.doi.org/10.1116/1.581454.

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8

Liu, Wenhai, George Barbastathis, and Demetri Psaltis. "Volume Holographic Hyperspectral Imaging." Applied Optics 43, no. 18 (2004): 3581. http://dx.doi.org/10.1364/ao.43.003581.

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9

Sinha, Arnab, and George Barbastathis. "Broadband volume holographic imaging." Applied Optics 43, no. 27 (September 20, 2004): 5214. http://dx.doi.org/10.1364/ao.43.005214.

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10

Heimbeck, Martin S., and Henry O. Everitt. "Terahertz digital holographic imaging." Advances in Optics and Photonics 12, no. 1 (February 5, 2020): 1. http://dx.doi.org/10.1364/aop.12.000001.

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11

Sun, Wenyang, and George Barbastathis. "Rainbow volume holographic imaging." Optics Letters 30, no. 9 (May 1, 2005): 976. http://dx.doi.org/10.1364/ol.30.000976.

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12

McCartney, M. R. "Electron Holographic Imaging of Magnetic Materials at Nanometer Scale Resolution." Microscopy and Microanalysis 3, S2 (August 1997): 519–20. http://dx.doi.org/10.1017/s143192760000948x.

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Traditional electron microscopy techniques for imaging magnetic microstructure include out-of-focus Fresnel or Lorentz imaging, Foucault imaging and differential phase contrast (DPC). Off-axis electron holography provides access to both the amplitude and phase of the electron wave which has passed through the sample and therefore can provide direct, quantitative information about the in-plane component of the magnetic induction. The Philips CM200-FEG microscope which was used for the holography described here is equipped with a powerful mini-lens below the specimen enabling 2nm spatial resolution and only a small residual field at the sample. The combination of high coherence and increased magnification enable quantitative mapping of magnetic induction at the nanometer scale.Electrostatic or magnetic potentials give rise to phase shifts in the holographic interference fringes which can be quantified following reconstruction. In the presence of a magnetic field, the phase equation (for constant composition and neglecting diffraction effects) becomes:
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13

Zhang, Tong, Ichirou Yamaguchi, and Hywel Morgan. "Digital Holographic Microscopy." Microscopy and Microanalysis 5, S2 (August 1999): 362–63. http://dx.doi.org/10.1017/s1431927600015130.

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We applied phase-shifting digital holography to microscopy in this paper. At first lensless microscopy is proposed, in which no optical adjustment is necessary. Then, the method is applied to relax the limitation of focal depth in traditional optical microscopy. A theory for image formation and experimental verification using a few specimens are described.keywords: microscopy, digital holography, phase shiftingDue to the finite focal depth of an imaging lens, a limitation to normal optical microscopy-is that, only the 2-dimensional (2-D) information of an object can be obtained at one time. Besides, it is not convenient for quantitative analysis the observed image. Optical sectioning microscopy (OSM) and scanning confocal microscopy (SCM) which use opto-electronic detection have been proposed for quantitative analysis of a 3-D object. However, the former requires critical mechanical adjustment, while the latter uses timeconsuming mechanical 3-D scanning. Holographic microscopy can solve these problems because it can record 3-D information at one time. But, the chemical processing of holograms and the mechanical focusing at the reconstructed images cause more or less trouble. A 3-D imaging technique without use of photographic recording called optical scanning holography has recently been reported. However, there are also some trouble owing to the twin-image noise.
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14

Yukun Zhu, Yukun Zhu, Minghui Yang Minghui Yang, Liang Wu Liang Wu, Yun Sun Yun Sun, and and Xiaowei Sun and Xiaowei Sun. "Practical millimeter-wave holographic imaging system with good robustness." Chinese Optics Letters 14, no. 10 (2016): 101101–5. http://dx.doi.org/10.3788/col201614.101101.

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15

Nicolas, Jan-David, Marten Bernhardt, Martin Krenkel, Claudia Richter, Stefan Luther, and Tim Salditt. "Combined scanning X-ray diffraction and holographic imaging of cardiomyocytes." Journal of Applied Crystallography 50, no. 2 (March 29, 2017): 612–20. http://dx.doi.org/10.1107/s1600576717003351.

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This article presents scanning small-angle X-ray scattering (SAXS) experiments on the actomyosin assemblies in freeze-dried neo-natal rat cardiac muscle cells. By scanning the cells through a sub-micrometre focused beam, the local structure and filament orientation can be probed and quantified. To this end, SAXS data were recorded and analyzed directly in reciprocal space to generate maps of different structural parameters (scanning SAXS). The scanning SAXS experiments were complemented by full-field holographic imaging of the projected electron density, following a slight rearrangement of the instrumental setup. It is shown that X-ray holography is ideally suited to complete missing scattering data at low momentum transfer in the structure factor, extending the covered range of spatial frequencies by two orders of magnitude. Regions of interest for scanning can be easily selected on the basis of the electron density maps. Finally, the combination of scanning SAXS and holography allows for a direct verification of possible radiation-induced structural changes in the cell.
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16

Zhai, Xiaomin, Wei-Tang Lin, Hsi-Hsun Chen, Po-Hao Wang, Li-Hao Yeh, Jui-Chang Tsai, Vijay Raj Singh, and Yuan Luo. "In-line digital holographic imaging in volume holographic microscopy." Optics Letters 40, no. 23 (November 23, 2015): 5542. http://dx.doi.org/10.1364/ol.40.005542.

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17

Kim, You Seok, and Taegeun Kim. "Binocular Holographic Three-Dimensional Imaging System Using Optical Scanning Holography." Korean Journal of Optics and Photonics 26, no. 5 (October 25, 2015): 249–54. http://dx.doi.org/10.3807/kjop.2015.26.5.249.

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18

QUAN, Xiangyu, Manoj KUMAR, Yasuhiro AWATSUJI, and Osamu MATOBA. "Multimodal Digital Holographic Imaging for Cell Imaging." Review of Laser Engineering 47, no. 5 (2019): 253. http://dx.doi.org/10.2184/lsj.47.5_253.

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19

Habeck, Martina. "Holographic imaging of live tumours." Drug Discovery Today 7, no. 14 (July 2002): 744–45. http://dx.doi.org/10.1016/s1359-6446(02)02373-5.

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20

Pouey, M. "Imaging properties of holographic gratings." Physica Scripta 41, no. 6 (June 1, 1990): 765–68. http://dx.doi.org/10.1088/0031-8949/41/6/008.

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21

Yang, G. G., H. S. Chen, and E. N. Leith. "Volume reflection holographic confocal imaging." Applied Optics 39, no. 23 (August 10, 2000): 4076. http://dx.doi.org/10.1364/ao.39.004076.

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22

Rabal, H. J., M. Trivi, E. E. Sicre, and M. Garavaglia. "Stereo enhancement in holographic imaging." Applied Optics 25, no. 8 (April 15, 1986): 1259. http://dx.doi.org/10.1364/ao.25.001259.

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23

Ylitalo, J., E. Alasaarela, and J. Koivukangas. "Ultrasound holographic B-scan imaging." IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control 36, no. 3 (May 1989): 376–83. http://dx.doi.org/10.1109/58.19178.

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24

ISHIHARA, Chiaki, Takashi AOKI, Norio ISHII, Osamu TAKANO, Yukinobu SANADA, and Yasutaka TAMURA. "Underwater imaging with holographic method." Journal of the Visualization Society of Japan 13, Supplement1 (1993): 123–26. http://dx.doi.org/10.3154/jvs.13.supplement1_123.

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25

Hunt, John, Jonah Gollub, Tom Driscoll, Guy Lipworth, Alex Mrozack, Matthew S. Reynolds, David J. Brady, and David R. Smith. "Metamaterial microwave holographic imaging system." Journal of the Optical Society of America A 31, no. 10 (September 4, 2014): 2109. http://dx.doi.org/10.1364/josaa.31.002109.

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26

Wan, Weiwei, Jie Gao, and Xiaodong Yang. "Metasurface Holograms for Holographic Imaging." Advanced Optical Materials 5, no. 21 (September 27, 2017): 1700541. http://dx.doi.org/10.1002/adom.201700541.

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27

Kou, Shan S., and Colin J. Sheppard. "Imaging in digital holographic microscopy." Optics Express 15, no. 21 (2007): 13640. http://dx.doi.org/10.1364/oe.15.013640.

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28

Castro, J. M., P. J. Gelsinger-Austin, J. K. Barton, and R. K. Kostuk. "Confocal Rainbow Volume Holographic Imaging." Optics and Photonics News 22, no. 12 (December 1, 2011): 52. http://dx.doi.org/10.1364/opn.22.12.000052.

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29

Sinha, Arnab, and George Barbastathis. "N-ocular volume holographic imaging." Applied Optics 43, no. 31 (November 1, 2004): 5784. http://dx.doi.org/10.1364/ao.43.005784.

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30

Qiu, Tian-Hui, Min Xie, Hong-Yang Ma, Chun-Hong Zheng, and Li-Bo Chen. "Electromagnetically Induced Quantum Holographic Imaging." International Journal of Theoretical Physics 55, no. 5 (November 21, 2015): 2335–41. http://dx.doi.org/10.1007/s10773-015-2871-0.

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31

Gizon, Laurent, Damien Fournier, Dan Yang, Aaron C. Birch, and Hélène Barucq. "Signal and noise in helioseismic holography." Astronomy & Astrophysics 620 (December 2018): A136. http://dx.doi.org/10.1051/0004-6361/201833825.

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Context. Helioseismic holography is an imaging technique used to study heterogeneities and flows in the solar interior from observations of solar oscillations at the surface. Holographic images contain noise due to the stochastic nature of solar oscillations. Aims. We aim to provide a theoretical framework for modeling signal and noise in Porter–Bojarski helioseismic holography. Methods. The wave equation may be recast into a Helmholtz-like equation, so as to connect with the acoustics literature and define the holography Green’s function in a meaningful way. Sources of wave excitation are assumed to be stationary, horizontally homogeneous, and spatially uncorrelated. Using the first Born approximation we calculated holographic images in the presence of perturbations in sound-speed, density, flows, and source covariance, as well as the noise level as a function of position. This work is a direct extension of the methods used in time-distance helioseismology to model signal and noise. Results. To illustrate the theory, we compute the holographic image intensity numerically for a buried sound-speed perturbation at different depths in the solar interior. The reference Green’s function is obtained for a spherically-symmetric solar model using a finite-element solver in the frequency domain. Below the pupil area on the surface, we find that the spatial resolution of the holographic image intensity is very close to half the local wavelength. For a sound-speed perturbation of size comparable to the local spatial resolution, the signal-to-noise ratio is approximately constant with depth. Averaging the image intensity over a number N of frequencies above 3 mHz increases the signal-to-noise ratio by a factor nearly equal to the square root of N. This may not be the case at lower frequencies, where large variations in the holographic signal are due to the contributions from the long-lived modes of oscillation.
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32

Shimizu, Isao, Yoshinori Saikawa, Katsuhiro Uno, Hideaki Kano, and Seishi Shimizu. "Contrast-tuneable microscopy for single-shot real-time imaging." European Physical Journal Applied Physics 91, no. 3 (September 2020): 30701. http://dx.doi.org/10.1051/epjap/2020200101.

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A novel real image in-line laser holography has enabled a tuneable image contrast, edge sharpness, and visualization of sub-wavelength structures, using a simple pair of filters and large-diameter lenses that can incorporate higher-order scattered beams. Demonstrated also are the accuracy in object sizing and the ease of imaging along the focal depth, based on a single-shot imaging via holographic principle. In addition, the use of broad, collimated laser beam for irradiation has led to a wider field of view, making it particularly useful for an extensive monitoring of, and sweeping search for, cells and microbial colonies and for the real-time imaging of cancer-cell dynamics.
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33

Wang, Jian Gang, Zhan Jun Yan, and Wen Qiang Li. "Optical Design of Waveguide Holographic Binocular Display for Machine Vision." Applied Mechanics and Materials 427-429 (September 2013): 763–69. http://dx.doi.org/10.4028/www.scientific.net/amm.427-429.763.

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A binocular display can satisfy competition mechanism of biological vision system and improve display precision. A binocular optical system is designed with waveguide holography (WGH) for small size and light weight. A superimposed holographic volume grating can split the image bearing lights into two equal intensity light beams. The out-coupling waveguide holographic gratings for the left and right eyes can implement image extension and imaging display. The simulation and experimental results reveal that excellent optical performances can be achieved for little distortion of less than 0.05%(nearly zero), light weight of about only 32g, and compact size. The display information can also be overlaid the outside scenes in eyeglass augmented reality and Machine Vision Display applications.
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34

Lv, Yanlu, Jiulou Zhang, Fei Liu, Junwei Shi, Huizhi Guang, Jing Bai, and Jianwen Luo. "Spectral selective fluorescence molecular imaging with volume holographic imaging system." Journal of Innovative Optical Health Sciences 09, no. 02 (March 2016): 1650010. http://dx.doi.org/10.1142/s1793545816500103.

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A compact volume holographic imaging (VHI) method that can detect fluorescence objects located in diffusive medium in spectral selective imaging manner is presented. The enlargement of lateral field of view of the VHI system is realized by using broadband illumination and demagnification optics. Each target spectrum of fluorescence emitting from a diffusive medium is probed by tuning the inclination angle of the transmission volume holographic grating (VHG). With the use of the single transmission VHG, fluorescence images with different spectrum are obtained sequentially and precise three-dimensional (3D) information of deep fluorescent objects located in a diffusive medium can be reconstructed from these images. The results of phantom experiments demonstrate that two fluorescent objects with a sub-millimeter distance can be resolved by spectral selective imaging.
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35

Brunnhofer, Georg, and Alexander Bergmann. "Modelling a Holographic Particle Counter." Proceedings 2, no. 13 (November 30, 2018): 967. http://dx.doi.org/10.3390/proceedings2130967.

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In order to design an imaging unit of a novel holographic particle counter an aerosol particle model was developed to generate a virtual hologram plane of an aerosol volume of interest. The herein presented model combines the three essential components to help dimensioning a target detection unit: (i) an In-Line holography model with a reference light source and a basic transfer function of an imager to take into account imager size, pixel pitch and exposure time; (ii) an aerosol particle model with particles of variable count, size and spatial distribution; and (iii) the possibility to import fluid dynamics simulation data to simulate the particle flow in an arbitrary sampling volume.
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36

Kelly, Damien P., David S. Monaghan, Nitesh Pandey, Tomasz Kozacki, Aneta Michałkiewicz, Grzegorz Finke, Bryan M. Hennelly, and Malgorzata Kujawinska. "Digital Holographic Capture and Optoelectronic Reconstruction for 3D Displays." International Journal of Digital Multimedia Broadcasting 2010 (2010): 1–14. http://dx.doi.org/10.1155/2010/759323.

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The application of digital holography as a viable solution to 3D capture and display technology is examined. A review of the current state of the field is presented in which some of the major challenges involved in a digital holographic solution are highlighted. These challenges include (i) the removal of the DC and conjugate image terms, which are features of the holographic recording process, (ii) the reduction of speckle noise, a characteristic of a coherent imaging process, (iii) increasing the angular range of perspective of digital holograms (iv) and replaying captured and/or processed digital holograms using spatial light modulators. Each of these challenges are examined theoretically and several solutions are put forward. Experimental results are presented that demonstrate the validity of the theoretical solutions.
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37

Suzuki, A., A. Hashimoto, M. Nojima, M. Owari, and Y. Nihei. "Holographic imaging of TiO2(110) surface structure by differential photoelectron holography." Surface and Interface Analysis 40, no. 13 (December 2008): 1627–30. http://dx.doi.org/10.1002/sia.2941.

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38

Cowley, J. M., and M. A. Gribelyuk. "High-resolution coherent imaging in STEM." Proceedings, annual meeting, Electron Microscopy Society of America 51 (August 1, 1993): 1082–83. http://dx.doi.org/10.1017/s0424820100151246.

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The ultimate aim of high resolution electron microscopy is the accurate determination of the positions and types of the atoms in a specimen. The coherent imaging theory for STEM is reviewed with the emphasis on its potential for achieving this aim by holographic methods. The STEM modes of holography are in many respects equivalent to the corresponding TEM modes, but have the advantage that, because with a FEG electron source the focussed probes have sub-nanometer diameter, a strong signal is obtained from the illuminated region and the problem of shot-noise is much less important.The original proposal for holography by Gabor envisaged the use of a reconstruction process on the recorded hologram to correct for the lens aberrations and hence improve the image resolution. The more general and more challenging problem is to reconstruct the aberration-free wave function at the exit face of the specimen (with its real and imaginary, or amplitude and phase, components) and then to invert the dynamical diffraction process and derive the projected potential distribution of the object.
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39

PARK, Jung-Hoon, Kyoohyun KIM, and YongKeun PARK. "Holographic Optical Imaging and Manipulation Techniques." Physics and High Technology 26, no. 3 (March 31, 2017): 7–14. http://dx.doi.org/10.3938/phit.26.008.

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40

Tan, Shi Zhe, and Sheng Xu Wang. "Digital Holographic Imaging of Marine Plankton." Applied Mechanics and Materials 198-199 (September 2012): 314–19. http://dx.doi.org/10.4028/www.scientific.net/amm.198-199.314.

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Designing an advanced method to sensing marine plankton effectively is highly demanded for acquiring critical marine plankton information data. The goal of this paper is to use digital holographic imaging for sensing marine plankton in recording sampling volume with several advantages such as non-intrusive and non-destructive interrogation of the recording sampling volume. So, by capturing hologram of marine plankton and reconstructing hologram, the recorded optical field of marine plankton is retrieved.
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41

Wang, Lulu, Ray Simpkin, and A. M. Al-Jumaily. "Holographic microwave imaging for medical applications." Journal of Biomedical Science and Engineering 06, no. 08 (2013): 823–33. http://dx.doi.org/10.4236/jbise.2013.68100.

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42

Wang Hua-Ying, Liu Fei-Fei, Liao Wei, Song Xiu-Fa, Yu Meng-Jie, and Liu Zuo-Qiang. "Optimized digital micro-holographic imaging system." Acta Physica Sinica 62, no. 5 (2013): 054208. http://dx.doi.org/10.7498/aps.62.054208.

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Hamed, Abdallah Mohamed, and Mohamed Aly Saudy. "Holographic Imaging of Argon Plasma Images." Optics and Photonics Journal 04, no. 06 (2014): 136–42. http://dx.doi.org/10.4236/opj.2014.46014.

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44

Barbastathis, George, and Arnab Sinha. "Information content of volume holographic imaging." Trends in Biotechnology 19, no. 10 (October 2001): 383–92. http://dx.doi.org/10.1016/s0167-7799(01)01743-7.

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45

Gutierrez, D., H. Chiang, T. Bhowmick, A. D. Volodchenkov, M. Ranjbar, G. Liu, C. Jiang, et al. "Magnonic holographic imaging of magnetic microstructures." Journal of Magnetism and Magnetic Materials 428 (April 2017): 348–56. http://dx.doi.org/10.1016/j.jmmm.2016.12.022.

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46

Widmayer, C. Clay, Melinda R. Nickels, and David Milam. "Nonlinear holographic imaging of phase errors." Applied Optics 37, no. 21 (July 20, 1998): 4801. http://dx.doi.org/10.1364/ao.37.004801.

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47

POUEY, M. "STIGMATIC XUV IMAGING WITH HOLOGRAPHIC GRATINGS." Le Journal de Physique Colloques 49, no. C7 (December 1988): C7–23—C7–29. http://dx.doi.org/10.1051/jphyscol:1988703.

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48

Chan, K. T., T. P. Leung, and Y. J. Li. "Holographic imaging of side-scattering particles." Optics & Laser Technology 28, no. 8 (November 1996): 565–71. http://dx.doi.org/10.1016/s0030-3992(96)00026-6.

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49

Tang, Jie, Yang Ming, Wei Hu, and Yan-qing Lu. "Spiral holographic imaging through quantum interference." Applied Physics Letters 111, no. 1 (July 3, 2017): 011105. http://dx.doi.org/10.1063/1.4991365.

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50

Liu, Xue, Alexander Heifetz, Shih C. Tseng, and M. S. Shahriar. "High-speed inline holographic Stokesmeter imaging." Applied Optics 48, no. 19 (July 1, 2009): 3803. http://dx.doi.org/10.1364/ao.48.003803.

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