Full-color holographic display with increased-viewing-angle [Invited]

Zeng, Zhenxiang; Zheng, Huadong; Yu, Yingjie; Asundi, Anand Krishna; Valyukh, Sergiy

doi:10.1364/ao.56.00f112

Cited by 55 publications

(15 citation statements)

References 34 publications

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“…The dotted lines indicate the calculated values of δ λ with (11). The simulation results presented in Figure 10 prove good accuracy of the developed measures given by (11) and (12).…”

Section: Image Blursupporting

confidence: 55%

“…Such large distances are selected to illustrate the accuracy of the formulas more precisely. The left plots, using solid lines, present the intensity distributions calculated with the simulation, while the dotted lines indicate values of image blur calculated with (12). The plots on the right present distributions of the spectra, which correspond to the reconstructions showed on the left.…”

Section: Image Blurmentioning

confidence: 99%

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Visual perception of Fourier rainbow holographic display

2019

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The rainbow hologram provides views of reconstruction with rainbow color within a large viewing zone. In our recent paper, a Fourier rainbow holographic display using diffraction grating and a white‐light LED source was introduced. In this technique, the rainbow effect is realized by the dispersion of white‐light source on diffraction grating, while the slit is implemented numerically by reducing the demands of the space‐bandwidth product of the display. This paper presents a novel analysis on the visual perception of the Fourier rainbow holographic display using Wigner distribution. The view‐dependent appearance of the image, including multispectral field of view and viewing zone, is investigated considering the observer and the display parameters. The resolution of the holographic view is also investigated. For this, a new quantitative assessment for image blur is introduced using Wigner distribution analysis. The analysis is supported with numerical simulations and experimentally captured optical reconstructions for the holograms of the computer model and real object generated with different slit size, reconstruction distance, and different observation conditions.

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“…The dotted lines indicate the calculated values of δ λ with (11). The simulation results presented in Figure 10 prove good accuracy of the developed measures given by (11) and (12).…”

Section: Image Blursupporting

confidence: 55%

Section: Image Blurmentioning

confidence: 99%

Visual perception of Fourier rainbow holographic display

2019

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“…As shown in Figure 6, there are two SLMs tiled in a curved configuration with tiled angle α in order to ensure accurate tiling. When α is smaller than θ, the viewing angle is increased to θ+α in this case [23], otherwise, the reconstructed image is not seen continuously. Under ideal conditions, i.e., α = θ, the dependence of the viewing angle on the pixel pitch of SLMs is as shown in Figure 7a.…”

Section: Binocular Systemmentioning

confidence: 99%

Holographic Three-Dimensional Virtual Reality and Augmented Reality Display Based on 4K-Spatial Light Modulators

Gao

Liu

et al. 2019

Applied Sciences

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In this paper, we propose a holographic three-dimensional (3D) head-mounted display based on 4K-spatial light modulators (SLMs). This work is to overcome the limitation of stereoscopic 3D virtual reality and augmented reality head-mounted display. We build and compare two systems using 2K and 4K SLMs with pixel pitches 8.1 μm and 3.74 μm, respectively. One is a monocular system for each eye, and the other is a binocular system using two tiled SLMs for two eyes. The viewing angle of the holographic head-mounted 3D display is enlarged from 3.8 ∘ to 16.4 ∘ by SLM tiling, which demonstrates potential applications of true 3D displays in virtual reality and augmented reality.

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“…There are four major issues for holographic display applications: (1) the slow liquid crystal response time; (2) the small field of view (FoV); (3) the laser speckle effect degrading the image quality when using lasers as a backlight unit; and (4) a reduction in the frame rate for achieving field-sequential color displays [25]. There are many studies where the aforementioned issues have been addressed, such as: (1) 3-4 ms phase-only panel response time of thin cell gap at λ = 633 nm to reduce the dynamic reconstruction holographic image blur [26]; (2) the time-division multiplexing method to increase the FoV [27]; and (3) reduction of the speckle effect in image projection using temporal averaging techniques [28].…”

Section: Switching Time For Phase Modulationmentioning

confidence: 99%

Pursuing High Quality Phase-Only Liquid Crystal on Silicon (LCoS) Devices

et al. 2018

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Fine pixel size and high-resolution liquid crystal on silicon (LCoS) backplanes have been developed by various companies and research groups since 1973. The development of LCoS is not only beneficial for full high definition displays but also to spatial light modulation. The high-quality and well-calibrated panels can project computer generated hologram (CGH) designs faithfully for phase-only holography, which can be widely utilized in 2D/3D holographic video projectors and components for optical telecommunications. As a result, we start by summarizing the current status of high-resolution panels, followed by addressing issues related to the driving frequency (i.e., liquid crystal response time and hardware interface). LCoS panel qualities were evaluated based on the following four characteristics: phase linearity control, phase precision, phase stability, and phase accuracy.A phase-only spatial light modulator can be used as a key optical element for displays, adaptive optics for sensing, lithography, and telecommunication, as shown in Figure 2. The linearity of phase modulation, response time, phase precision, and phase stability are key characteristics for appraising or selecting phase-only LCoS-SLM panels for the applications designed. However, it is difficult to obtain a single LCoS possessing all the desired features for all applications. Their specification and performance optimization are application-driven. For example, response time is the current limitation in a holographic display. It may be more important than phase stability,

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Full-color holographic display with increased-viewing-angle [Invited]

Cited by 55 publications

References 34 publications

Visual perception of Fourier rainbow holographic display

Visual perception of Fourier rainbow holographic display

Holographic Three-Dimensional Virtual Reality and Augmented Reality Display Based on 4K-Spatial Light Modulators

Pursuing High Quality Phase-Only Liquid Crystal on Silicon (LCoS) Devices

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