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    This study presents a tabletop holographic display system capable of delivering 3.2-inch, 360-degree 3D holographic images to multiple viewers simultaneously. The system utilizes synchronized digital micro-mirror displays and specialized optics for a wide, distortion-free viewing experience.

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    Area of Science:

    • Optics and Photonics
    • Display Technology
    • Computer Vision

    Background:

    • Traditional holographic displays often face limitations in size, viewing angle, and simultaneous multi-user support.
    • Achieving continuous parallax and a full 360-degree view for multiple observers remains a significant challenge in holographic display technology.

    Purpose of the Study:

    • To develop a compact, tabletop holographic display system capable of presenting large-format, 360-degree 3D holographic content to multiple users concurrently.
    • To overcome the limitations of existing systems by enabling continuous parallax and a wide, oblique viewing circumference without visual distortion.

    Main Methods:

    • A novel optical configuration using four synchronized high-speed digital micro-mirror displays (DMDs) in a 2x2 multi-vision panel for image enlargement and time-division multiplexing.
    • Integration of a specialized optical image delivery sub-system, including parabolic mirrors and an aspheric lens, to achieve a 3.2-inch holographic image and a 45-degree oblique viewing angle.
    • Generation of localized viewing windows on the 360-degree viewing circumference to facilitate simultaneous multi-observer access.

    Main Results:

    • Demonstration of a tabletop holographic display system successfully serving continuous parallax 3.2-inch 360-degree 3D holographic content.
    • Simultaneous viewing by multiple observers was achieved at a 45-degree oblique viewing circumference.
    • The system effectively enlarged the holographic image and provided a wide viewing angle without introducing visual distortion.

    Conclusions:

    • The proposed system offers a viable solution for multi-user, large-format 3D holographic displays in a compact form factor.
    • The integration of synchronized DMDs and specialized optics successfully addresses key challenges in holographic display performance.
    • This advancement paves the way for more immersive and interactive holographic experiences in various applications.