Projection-type see-through holographic three-dimensional display

Multiplane displays are capable of displaying 3D scenes with correct focus cues by creating multilayer 2D images in the display volume. Hence, such a 3D display technique could effectively address the accommodation‐vergence conflict (AVC) problem, which is prevalent in augmented reality (AR) displays. In this paper, we review the recent progress on multiplane AR displays based on liquid crystals (LCs) for AR applications. The working principle of multiplane AR displays is illustrated, the electro‐optical properties of the tunable LC devices are investigated and display prototypes are demonstrated. Finally, we discuss the prospects and challenges of multiplane AR displays based on LCs.

Section: Introductionmentioning

confidence: 99%

Multiplane displays based on liquid crystals for AR applications

Liu

2020

“…The holographic technology can fully reproduce the parallax of the real world. But it requires complicated coherent source‐based hardware and works strongly depending on wavelengths, thereby leading to challenges in achieving sufficient spatial resolution, full‐color, real‐time capability, etc …”

Section: Introductionmentioning

confidence: 99%

“…But it requires complicated coherent source-based hardware and works strongly depending on wavelengths, thereby leading to challenges in achieving sufficient spatial resolution, full-color, real-time capability, etc. [15][16][17] In this manner, in addition to the display technologies discussed above, light field displays (LFDs) have gained increasing attention these years. [18][19][20] LFDs refer to a type of display that is capable of presenting plenoptic functions to provide VAC-free 3D content and can be implemented using various technologies, eg, the integral imaging (InIm), [20][21][22][23] layered directional backlights (eg, the Tensor Displays 24 ), arrayed projectors.…”

Section: Introductionmentioning

confidence: 99%

Image formation modeling and analysis of near‐eye light field displays

Qin

Chou

et al. 2019

Near‐eye light field displays based on integral imaging through a microlens array provide attractive features like ultra‐compact volume and freedom of the vergence‐accommodation conflict to head‐mounted displays with virtual or augmented reality functions. To enable optimal design and analysis of such systems, it is desirable to have a physical model that incorporates all factors that affect the image formation, including diffraction, aberration, defocusing, and pixel size. Therefore, in this study, using the fundamental Huygens‐Fresnel principle and the Arizona eye model with adjustable accommodation, we develop an image formation model that can numerically calculate the retinal light field image with near‐perfect accuracy, and experimentally verify it with a prototype system. Next, based on this model, the visual resolution is analyzed for different field of views (FOVs). As a result, a rapid resolution decay with respect to FOV caused by off‐axis aberration is demonstrated. Finally, resolution variations as a function of image depth are analyzed based on systems with different central depth planes. Significantly, the resolution decay is revealed to plateau when the image depth is large enough, which is different from real‐image type light field displays.

“…3 To realize a comfortable AR display without visual fatigue, true 3D display methods, rather than stereoscopic display technique, should be employed in HMDs. Recently, a number of true 3D display approaches, such as light-field display, 4 holographic display, 5,6 and multi-plane display, 7,8 have been proposed for optical see-through AR displays.…”

Section: Introductionmentioning

confidence: 99%

Full‐color multi‐plane optical see‐through head‐mounted display for augmented reality applications

Liu

Zhou

et al. 2018

Based on fast‐response polymer‐stabilized liquid crystal scattering shutters, we designed a full‐color multi‐plane optical see‐through head‐mounted display for augmented reality applications. Red, green, and blue light‐emitting diodes (LEDs) are used to illuminate a digital micromirror device in time sequence to create a full‐color 3D scene. A quasi‐collimated image projection source, with a large depth of focus, was designed, in order to ensure sharp pictures projected on different polymer‐stabilized liquid crystal films at different depth. Our system provides high‐quality full‐color images with correct depth information and thus solves the accommodation–vergence conflict problem. A proof‐of‐concept binocular full‐color two‐plane optical see‐through head‐mounted display prototype is demonstrated.