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Laser & Optoelectronics Progress, Volume. 59, Issue 20, 2011001(2022)

Review of Holographic Near-Eye Displays for Visual Comfort

Chenliang Chang1...2,*, Bo Dai1,2, Jun Xia3, Dawei Zhang1,2,**, and Songlin Zhuang12 |Show fewer author(s)
Author Affiliations
  • 1Shanghai Key Laboratory of Modern Optics System, School of Optical-Electrical and Computer Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
  • 2Engineering Research Center of Optical Instrument and System, Ministry of Education, School of Optical-Electrical and Computer Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
  • 3Joint International Research Laboratory of Information Display and Visualization, School of Electronic Science and Engineering, Southeast University, Nanjing 210096, Jiangsu, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (13)
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    References (98)
    Cited By (5)
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    Figures & Tables(13)
    Iterative perceptual process of human visual system[11]

    Fig. 1. Iterative perceptual process of human visual system[11]

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    Content perception of human visual system at different field angles[12]

    Fig. 2. Content perception of human visual system at different field angles[12]

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    Holographic near-eye display based on Fourier and Fresnel holography and their corresponded eyebox illustration. (a) Holographic near-eye display based on Fourier; (b) holographic near-eye display based on Fresnel holography

    Fig. 3. Holographic near-eye display based on Fourier and Fresnel holography and their corresponded eyebox illustration. (a) Holographic near-eye display based on Fourier; (b) holographic near-eye display based on Fresnel holography

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    Eyebox expansion. (a) Spatial multiplexing[17]; (b) temporal multiplexing based on multiple illumination and spatial tiling[18]; (c) temporal multiplexing based on phase shifting and pupil tracking[19]

    Fig. 4. Eyebox expansion. (a) Spatial multiplexing[17]; (b) temporal multiplexing based on multiple illumination and spatial tiling[18]; (c) temporal multiplexing based on phase shifting and pupil tracking[19]

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    FOV expansion. (a) FOV enlargement through conjugate imaging; (b) FOV enlargement through off-axis holographic lens[20]

    Fig. 5. FOV expansion. (a) FOV enlargement through conjugate imaging; (b) FOV enlargement through off-axis holographic lens[20]

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    Spatial bandwidth product expansion based on non-period wavefront modulation. (a) Using holographic scattering media[40]; (b) using non-period photon sieve[41]

    Fig. 6. Spatial bandwidth product expansion based on non-period wavefront modulation. (a) Using holographic scattering media[40]; (b) using non-period photon sieve[41]

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    Speckle noise suppression. (a) Time average method[43]; (b) double-phase based complex amplitude modulation[50]; (c) partially coherent illumination[51]

    Fig. 7. Speckle noise suppression. (a) Time average method[43]; (b) double-phase based complex amplitude modulation[50]; (c) partially coherent illumination[51]

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    Optimization of hologram from feedback of optical captured image. (a) Camera-in-the-loop optimization for 2D holographic display[65]; (b) camera-in-the-loop optimization for 3D holographic display[66]

    Fig. 8. Optimization of hologram from feedback of optical captured image. (a) Camera-in-the-loop optimization for 2D holographic display[65]; (b) camera-in-the-loop optimization for 3D holographic display[66]

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    CGH generation based on geometry models. (a) Point-cloud based CGH algorithm accelerated by wavefront recording plane[73]; (b) local coordinates of polygon based algorithm[74]

    Fig. 9. CGH generation based on geometry models. (a) Point-cloud based CGH algorithm accelerated by wavefront recording plane[73]; (b) local coordinates of polygon based algorithm[74]

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    CGH generation based on image models. (a) Hologram calculation and display of multi plane model[44]; (b)hologram calculation and display of light field model[77]

    Fig. 10. CGH generation based on image models. (a) Hologram calculation and display of multi plane model[44]; (b)hologram calculation and display of light field model[77]

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    Full-color holographic near-eye display based on temporal multiplexing. (a) Temporal multiplexed full-color holographic AR display by using high frame rate DMD[47]; (b) temporal multiplexed full-color holographic AR display combined with complex amplitude modulation optics[87]

    Fig. 11. Full-color holographic near-eye display based on temporal multiplexing. (a) Temporal multiplexed full-color holographic AR display by using high frame rate DMD[47]; (b) temporal multiplexed full-color holographic AR display combined with complex amplitude modulation optics[87]

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    Full-color holographic near-eye display based on spatial multiplexing through. (a) Frequency filtering[89]; (b) waveguide metasurface hologram[90]

    Fig. 12. Full-color holographic near-eye display based on spatial multiplexing through. (a) Frequency filtering[89]; (b) waveguide metasurface hologram[90]

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    Compact prototype of holographic AR glass and its potential applications[60]

    Fig. 13. Compact prototype of holographic AR glass and its potential applications[60]

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    Chenliang Chang, Bo Dai, Jun Xia, Dawei Zhang, Songlin Zhuang. Review of Holographic Near-Eye Displays for Visual Comfort[J]. Laser & Optoelectronics Progress, 2022, 59(20): 2011001

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    Paper Information

    Category: Imaging Systems

    Received: Jun. 29, 2022

    Accepted: Aug. 20, 2022

    Published Online: Oct. 13, 2022

    The Author Email: Chang Chenliang (changchenliang@hotmail.com), Zhang Dawei (dwzhang@usst.edu.cn)

    DOI:10.3788/LOP202259.2011001

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology