阅读说明：本技术 全息显示器和全息图像形成方法 (Holographic display and holographic image forming method ) 是由 米克·维亚切斯拉沃维奇·波波夫 斯坦尼斯拉夫·亚历山德罗维奇·什特科夫 谢尔盖·亚历山德罗维奇· 于 2018-11-28 设计创作，主要内容包括：公开了一种全息显示器以及由所述全息显示器执行的形成全息图像的方法。全息显示器包括电可寻址空间光调制器(EASLM)；在EASLM上布置的衍射光学元件(DOE)掩模阵列；以及控制器,被配置为操作全息显示器以形成全息图像,其中,所述控制器还被配置为：寻址EASLM,以通过打开对应的EASLM像素来对形成全息图像体素集合所需的DOE掩模阵列进行背光照明。(A holographic display includes an electrically addressable spatial light modulator (EAS L M), a Diffractive Optical Element (DOE) mask array disposed on EAS L M, and a controller configured to operate the holographic display to form a holographic image, wherein the controller is further configured to address EAS L M to backlight the DOE mask array required to form a set of holographic image voxels by turning on corresponding EAS L M pixels.)

1. A holographic display, comprising:

an electrically addressable spatial light modulator EAS L M;

a Diffractive Optical Element (DOE) mask array disposed on the EAS L M, and

a controller configured to operate the holographic display to form a holographic image,

wherein the controller is further configured to address the EAS L M to backlight the DOE mask array required to form a set of holographic image voxels by turning on the corresponding EAS L M pixels.

2. The holographic display of claim 1, in which the EAS L M is a non-coherent EAS L M.

3. Holographic display of claim 2, further comprising an optically addressable spatial light modulator OAS L M and a backlight unit,

wherein the EAS L M, the DOE mask array, and the OAS L M are integrated into a single unit.

4. The holographic display of claim 3, in which the OAS L M includes a photosensitive layer and a liquid crystal layer, and

the controller is further configured to operate the OAS L M and the backlight unit such that a light intensity distribution formed after the DOE mask array forms a charge distribution in the photosensitive layer of the OAS L M and causes phase modulation in the liquid crystal layer of the OAS L M to form a phase hologram.

5. The holographic display of claim 4, in which the backlight unit is configured to form a holographic image by backlighting the phase hologram formed on the liquid crystal layer of the OAS L M.

6. The holographic display of claim 1, in which the EAS L M is coherent EAS L M.

7. The holographic display of any of claims 1 to 6, in which the array of DOE masks comprises a plurality of arrays of DOE masks stacked as multiple layers.

8. The holographic display of any of claims 1 to 6, further comprising an adaptive multi-lens array,

wherein the controller is further configured to operate the adaptive multi-lens array.

9. The holographic display of any of claims 1 to 6, wherein the holographic display is configured to switch between a three-dimensional (3D) mode and a two-dimensional (2D) mode.

10. The holographic display of any of claims 1 to 6, wherein the holographic display is further configured to form a color hologram.

11. The holographic display of any of claims 1 to 6, further comprising field optics and/or filters capable of spectrally filtering and spatially and/or angularly filtering the holographic image voxels.

12. The holographic display of any of claims 1 to 6, in which the DOE mask array is pre-calculated and manufactured to have a permanent structure and to provide specific features.

13. The holographic display of any of claims 1 to 6, in which the array of DOE masks is addressable, and the controller is further configured to address the array of DOE masks.

14. The holographic display of any of claims 1 to 6, in which the DOE mask array comprises sub-lenses, positive lenses or transmissive lenses.

15. A method of forming a holographic image performed by the holographic display of any of claims 1 to 6, the method comprising:

receiving holographic image data input by a controller;

generating control signals to backlight a diffractive optical element, DOE, mask that must form a set of holographic image voxels based on input data by turning on/off corresponding electrically addressable spatial light modulator, EAS L M, pixels, and

forming a holographic image by the EAS L M and the DOE mask array according to a control signal of the controller.

Technical Field

The present disclosure relates to formation of a holographic image, and more particularly, to a holographic display and a method of forming a holographic image performed by the holographic display.

Background

The formation of three-dimensional (3D) holographic images (holograms) has great potential in many application areas, such as telecommunications, medicine, entertainment, military equipment, etc. However, there are a number of problems with large area implementations using this technique.

Currently available holographic displays have a large size due to the high quality optical systems required for digital hologram reconstruction displayed on an electrically addressable spatial light modulator (EAS L M.) this increases the size of the holographic image and makes it nearly impossible to integrate the holographic image into wearable smart devices (watches, phones, tablets, etc.).

Current holographic displays cannot provide sufficiently small pixel (< 1 μ M) density to ensure a sufficiently wide field of view of holograms displayed on efficient coherent and incoherent spatial light modulators (S L M), e.g., laser backlights and liquid crystal displays (L CD), Digital Micromirror Devices (DMD), liquid crystal on silicon (L CoS) organic light emitting diode (O L ED) displays (organic light emitting diodes, organic L ED), μ light emitting diodes (μ -L ED), etc.

Furthermore, when playing holograms with good 3D object depth using currently widely used incoherent S L M (based on smartphones, smartwatches, televisions, etc.), optically addressable spatial light modulator (OAS L M) technology is used to convert the incoherent light distribution into a phase distribution (phase hologram) which is then reconstructed into a coherent light source.

Digital hologram operation requires a very high operating load on the processor and many resources (power, time, storage capacity, storage speed, etc.) due to the high resolution required to obtain the desired field of view, and the larger the holographic image, resolution and field of view, the greater the operating load.

In currently available large and medium (at least 1 inch) size display devices based on L CD technology according to the related art, the pixel size is typically 40 μm to 300 μm in such displays, a special coherent light source (laser) is required for backlighting, this solution is hardly suitable for digital holography due to its low resolution and narrow field of view and high operation load required for hologram operation (causing reduction in individual operation time of the individual devices and reduction in battery life), and the need to use coherent backlighting for bandwidth and hologram recording and reproduction.

Microdisplays currently available (less than 1 inch) typically have pixel sizes of 3 to 40 μm, require special coherent light sources (fiber-optic output laser or L ED) to reconstruct holograms in these displays, unlike large and medium displays, which lack scalability, microdisplays are typically based on L CD, L CoS or DMD technology and are suitable for digital holography applications due to small screen size, insufficient resolution, high operational load required for hologram operation (resulting in shorter autonomous operation time and shorter battery life of the individual devices), larger storage capacity and wider bandwidth, and the need for hologram recording and playback using coherent backlighting.

The main problem with currently available displays is that the field of view (FoV) is small-the viewing angle is proportional to 2 arcsin (λ/2), where λ is the wavelength of light and p is the S L M pixel size-in the case of current displays with pixel sizes from 3 μ M to 250 μ M, the viewing angle is about 5 ° ± 0.06 °. to provide a viewing angle of 30 °, a pixel size of about 1 μ M or less is required, which is not available to the consumer at the current state of the art.

Furthermore, holographic displays can typically operate in a 3D mode and cannot be switched to a two-dimensional (2D) mode.

The compact holographic display disclosed in US 8400695B 2 comprises an O L ED array (O L ED microdisplay) recording digital holograms on OAS L M, where the O L ED microdisplay and OAS L M form adjacent layers, the phase hologram is encoded on OAS L M according to the light intensity modulation on the O L ED microdisplay, and then the hologram is reconstructed when OAS L M is backlit.

Another apparatus in the related art is disclosed in US 8982438B 2, which includes a recording light source emitting a recording light beam, an EAS L M configured to sequentially modulate the recording light beam emitted from the recording light source according to hologram information corresponding to a 3D image spatially divided into a plurality of parts, an OAS L M configured to form a hologram by switching each of the plurality of divided parts of the 3D image and an image corresponding to the corresponding part using the modulated recording light beam, a scanning optical unit configured to reduce and reproduce a hologram formed by the recording light beam sequentially modulated by the EAS L M and transmit the hologram to an OAS L M region corresponding to the part, and a reproducing light source configured to irradiate a surface of the OAS L M.

Disclosure of Invention

Technical problem

Example embodiments provide a compact holographic display.

Example embodiments provide a method of forming a holographic image performed by a holographic display.

Solution to the problem

According to an embodiment, a holographic display may comprise:

an electrically addressable spatial light modulator (EAS L M);

a Diffractive Optical Element (DOE) mask array disposed on the EAS L M, and

a controller configured to operate the holographic display to form a holographic image,

wherein the controller is further configured to address EAS L M to backlight the DOE mask array required to form the set of holographic image voxels by turning on the corresponding EAS L M pixels.

EAS L M may be incoherent EAS L M.

The holographic display may also include an optically addressable spatial light modulator (OAS L M) and a backlight unit, and the EAS L M, DOE mask array and OAS L M may be integrated into a single unit.

The OAS L M may include a photosensitive layer and a liquid crystal layer, and the controller may be further configured to operate the OAS L M and the backlight unit so that the light intensity distribution formed after the DOE mask array may form a charge distribution in the photosensitive layer of the OAS L M and cause phase modulation in the liquid crystal layer of the OAS L M to form a phase hologram.

The backlight unit may be configured to form a hologram image by backlighting a phase hologram formed on the liquid crystal layer of the OAS L M.

EAS L M may be coherent EAS L M.

The DOE mask array may include multiple arrays of DOE masks stacked as multiple layers.

The holographic display may further comprise an adaptive multi-lens array, and the controller may be further configured to operate the adaptive multi-lens array.

The holographic display may be configured to switch between three-dimensional (3D) and two-dimensional (2D) modes.

The holographic display may also be configured to form a color hologram.

The holographic display may further comprise field optics and/or filters capable of spectrally filtering and spatially and/or angularly filtering the holographic image voxels.

The DOE mask array can be pre-computed and fabricated to have a permanent structure and provide specific features.

The array of DOE masks may be addressable, and the controller may be further configured to address the array of DOE masks.

The DOE mask array may include sub-lenses, positive lenses, or transmissive lenses.

According to an embodiment, a method of forming a holographic image performed by a holographic display may include:

receiving holographic image data input by a controller;

generating control signals to backlight a DOE mask that must form a holographic image voxel set based on input data by turning on/off corresponding EAS L M pixels, and

the holographic image is formed by the EAS L M and the DOE mask array according to a control signal of the controller.

Advantageous effects of the disclosure

According to example embodiments, a holographic display capable of a modulation scale (the scale) with a pixel size of 1 μm or less and at most half of a wavelength of a reading light may be provided according to example embodiments.

Drawings

Fig. 1 illustrates the principle of forming three-dimensional (3D) voxels according to an exemplary embodiment;

FIG. 2 illustrates the principle of forming a set of 3D voxels at different distances by an array of Diffractive Optical Element (DOE) masks each having different characteristics, according to an example embodiment;

FIG. 3 shows an example of forming a monochrome 3D hologram with eight depth levels;

fig. 4A and 4B illustrate operation of a holographic display in a 3D mode according to an example embodiment;

FIG. 4C illustrates operation of a holographic display in a two-dimensional (2D) mode according to an example embodiment;

FIG. 5 shows an example of an arrangement of a DOE mask configured to form a color holographic image of a holographic display, according to an example embodiment;

FIG. 6 illustrates an embodiment of stacking multiple controller operated DOE mask arrays into multiple layers;

FIG. 7 shows an embodiment of an integrated holographic display structure according to an embodiment;

FIG. 8 is a flow chart illustrating an algorithm of operation of the holographic display according to the embodiment of FIG. 7;

FIG. 9 shows another embodiment of a holographic display according to an example embodiment; and

FIG. 10 shows another embodiment of a holographic display according to an example embodiment.

Detailed Description

Example embodiments are not limited to those described in this disclosure and will be apparent to those of ordinary skill in the art based on information provided by those of ordinary skill in the art and the field of technology without departing from the spirit and scope of this disclosure. Reference to an element in the singular does not exclude the plural unless otherwise indicated.

Fig. 1 illustrates a principle of forming a three-dimensional (3D) voxel according to an example embodiment.

Each low-resolution spatial light modulator (S L M) pixel (display pixel) operates with a corresponding high-resolution Diffractive Optical Element (DOE) mask (typically an area with a DOE) disposed over the S L M pixel (see fig. 1) to produce a single holographic voxel when the S L M pixel is turned on, light from the S L M pixel illuminates the corresponding DOE mask to form a holographic voxel at a given distance.

Fig. 2 illustrates the principle of forming a set of 3D voxels at different distances by an array of DOE masks each having different characteristics, according to an example embodiment.

When using a high resolution DOE mask array arranged on S L M, the field of view (FoV) may be increased and the 3D voxel set (the entire hologram) may be reconstructed in space without using a large amount of computational resources (see fig. 2).

The DOE may be configured by various types and techniques, such as thin gratings, volume gratings, liquid crystal (L C) based switchable, optically and/or electronically addressable (phase) zone plates, and so forth.

For example, a typical pixel size of currently available EAS L M (microdisplay, display) may be 3 μ M to 250 μ M, and the hologram resolution may be, for example, 0.3 μ M (1/2 λ, where λ is, for example, 0.6 μ M), thus, the resolution of the hologram (DOE mask) may be higher than (3/0.3)²＝100。

According to an exemplary embodiment, since the DOE mask is already calculated, the digital hologram processing speed may be increased because the DOE mask DOEs not need to be recalculated every time.

The DOE mask may be pre-calculated and provide predetermined characteristics determined by the wavelength of the reference (reading, reconstruction) light and the wave surface, and may also be manufactured to provide characteristics of the object (hologram) to be reconstructed, such as object type (point, geometric circle, etc.), distance to the object, depth of the object, etc.

According to an embodiment, the DOE mask may be of an amplitude type or a phase type.

In this case, the active layer may or may not exhibit DOE characteristics, and may be transparent and weakly scattering, in response to appropriate control signals with respect to the active layer with the DOE mask.

According to example embodiments, a holographic display may be provided having a reduced thickness, increased hologram resolution, and field of view.

According to example embodiments, the amount of data used for hologram formation/processing/storage/transmission may be reduced.

According to an example embodiment, a holographic display may be provided using a high resolution arrangement of a DOE mask, which is a basic hologram of a basic 3D object, whose wavelength-sized elements are organized into a set to encode and reconstruct three-dimensional voxels (3D voxels) of the hologram at different distances. A basic hologram of a basic 3D object means that a basic 3D object (voxel, geometric circle (circle, square, etc.) or icon or other similar 3D object including a two-dimensional (2D) object at a specified distance from the screen) can be encoded by a corresponding hologram, i.e. a hologram is to be understood not only as a displayed 3D image but also as a corresponding encoded and manufactured result-DOE mask.

Fig. 3 shows an embodiment of the formation of a monochrome 3D hologram with eight depth levels.

Referring to fig. 3, a hologram forming apparatus (holographic display) may include a low resolution S L M, DOE mask array and auxiliary elements (field lenses, filters, etc.) the DOE mask array may include a set of DOE masks including eight DOE masks having different characteristics, and each DOE mask may be pre-fabricated and may be fabricated to allow voxels to be formed at a particular distance corresponding to one of eight depth levels.

In the embodiment shown in fig. 3 and in the following embodiments, the low resolution S L M is EAS L M (controller addressable), however, a "static" holographic display (e.g., a "holographic picture" of a museum) may be alternatively formed with static unaddressable S L M, further, a low resolution static amplitude light modulator illuminated by a coherent backlight, or the like, may be used as S L M.

To form a hologram, a 2D image luminance map and a 2D depth map may be used as input data. The 2D luminance map represents the luminance of each image pixel characterized by x and y coordinates.

In this embodiment, each pixel of the input 3D image corresponds to a set of eight EAS L M pixels corresponding to eight depth levels and a pixel for 2D mode operation of the display (a voxel, e.g., a light diffuser, as the pixel corresponding to a region in the DOE mask). thus, in the case of a black and white display, the number of EAS L M pixels corresponding to the input image pixels should be n + 1.

The controller determines whether the eight DOE masks contained in each DOE mask set should be illuminated by low resolution S L M pixels (EAS L M in FIG. 3) to form the desired voxels at a given distance based on the depth map data, and the controller specifies the brightness of the low resolution S L M pixels corresponding to the specified DOE mask based on the brightness map to form the desired voxels.

Fig. 4A and 4B are diagrams illustrating an operation of a holographic display in a 3D mode according to an example embodiment. Fig. 4C illustrates an operation of the holographic display in the 2D mode according to an example embodiment.

In 3D mode, the voxels of the holographic image may be formed behind (fig. 4A) or in front (fig. 4B) of the holographic display screen with respect to the viewer. For example, a DOE mask with a sub (diverging) lens (see fig. 4A) may be used and a "virtual" holographic voxel may be formed behind the screen with respect to the viewer, and in a positive (converging) lens (see fig. 4B) a "real" holographic voxel may be formed in front of the screen with respect to the viewer. Thus, according to an example embodiment, the hologram gives the impression that the imaged subject is behind or in front of the screen.

To achieve this, transparent (or diverging) regions of the DOE mask, such as transparent lenses (without DOEs or encoded light diffusers), may be used, and light passing through EAS L M pixels of a set of transparent (or diverging) DOE mask regions may form a planar 2D image for a viewer.

In this case, according to example embodiments, the holographic display controller may operate the low resolution S L M and switch between 2D and 3D modes by turning on/off each EAS L M pixel and the corresponding DOE mask.

According to an embodiment, the holographic display may form a colored 3D holographic image (see fig. 5).

Figure 5 shows an embodiment of a DOE mask arrangement comprising a set of DOE masks forming voxels of three different colors and three depth levels. In an embodiment, GD1, GD2, and GD3 elements of one set of DOE masks may be designed to produce green voxels at different depths. BD1, BD2, and BD3 elements of one DOE mask set may be designed to produce blue voxels at different depths. The RD1, RD2, and RD3 elements of one DOE mask set may be designed to produce red voxels at different depths. The numbers "1, 2 and 3" in the name of the DOE mask element indicate the depth level. In this case, the resolution of the obtained color hologram image is Nc times lower than that of the monochrome image. Here, Nc is the number of colors of the formed voxels.

The combined effect of the various elements described above may be used to form voxels of other colors from the RGB color model by a controller addressing the low resolution EAS L M, and the EAS L M pixels are turned on by corresponding DOE masks with intensities proportional to R, G and the B intensities in the intensity map of the input 3D image.

In a similar approach, the DOE mask, EAS L M light wavelength, and controller may be configured to operate using a basic color model other than RGB, such as YUV or otherwise.

Fig. 6 shows an embodiment with multiple DOE mask arrays stacked as multiple layers, where each layer can be addressable (active layer using L C technology) or static, i.e. the DOE mask can have a permanent structure.

To increase the resolution of the holographic image, the DOE mask array may be stacked in multiple layers (see fig. 6.) display resolution may be increased due to the increased number of voxels formed by modifying the EAS L M optical properties (polarization, wavelength of light, etc.) or activating the corresponding DOE mask layer by an input signal to the controller.

Also, each DOE mask array stacked as multiple layers may be used to form voxels of one particular color, i.e., several layers of the DOE mask array may be used to form a color holographic image while maintaining the resolution of the reconstructed image.

In this case, each next layer may be displaced relative to the adjacent layer in a horizontal or vertical direction by a spacing proportional to the size of one DOE mask and inversely proportional to the number of DOE layers to increase the resolution of the displayed hologram. Furthermore, each layer may be optically and/or electronically addressable.

FIG. 7 illustrates an embodiment of an integrated holographic display structure according to an embodiment.

The present disclosure may find application in a compact holographic display including an incoherent S L M, DOE mask array and a light addressable spatial light modulator (OAS L M) according to the embodiment shown in FIG. 7 the holographic display shown in FIG. 7 includes a low resolution incoherent EAS L M, DOE amplitude mask array, OAS L M and a backlight unit in this embodiment OAS L M may include several layers arranged in the order Indium Tin Oxide (ITO), a photosensitive layer, a dichroic mirror layer, a liquid crystal (L C) layer, ITO and a substrate toward the backlight unit.

ITO is a ternary composition of indium, tin, and oxygen in various proportions. In this embodiment, the ITO may be a transparent and thin (nanoscale) coating that is evaporated as an electrode.

In this case, a light intensity distribution may be formed on the photosensitive layer after the DOE mask array, a charge distribution may be induced in the photosensitive layer, and a phase modulation may be induced in the L C layer of OAS L M.Next, a phase hologram formed on the L C layer is reconstructed by coherent light of a backlight unit (requiring the controller signal to operate OAS L M in a record/read mode), which passes through an angle filter (active or passive) to filter out unwanted diffraction orders, passes through a spectral filter (active or passive) to filter out L M light, and passes through a field lens (optional) to form an eye viewing area of the reconstructed hologram (3D image). The eye viewing area of the phase hologram L C layer is a charge distribution phase area, which is a phase change area of the charge distribution on the phase hologram (EAS 6725), which is determined by the phase change of the charge distribution on the controlled holographic layer, and the phase change of the charge distribution in the liquid crystal holographic reconstruction area, which is displayed in proportion to the phase change of the charge distribution in the photosensitive layer (3D image).

In view of the above, operation using a typical incoherent display requires OAS L M on the photosensitive layer, where the light intensity distribution should be provided after the DOE mask to induce charge distribution in the photosensitive layer, and phase modulation in OAS L M L C layer to represent that the phase hologram is to be reconstructed by a coherent backlight.

FIG. 8 is a flow chart illustrating an algorithm of operation of the holographic display according to the embodiment shown in FIG. 7.

In operation S1, 2D or 3D image data or pre-computed 2D or 3D image data from a 2D/3D camera or other image source is applied to the holographic display controller. Depending on the mode of operation of the display, the data may be in the following form. The data may be in the form of a 2D luminance map (for 2D mode) or a 2D luminance map and a 2D depth map (for 3D mode).

In operation S2, the controller generates control signals for the low resolution EAS L M and the designated high resolution DOE mask array (when using the addressable set of high resolution DOE mask arrays to further increase the resolution of the reconstructed hologram, as shown in FIG. 6) based on the 2D intensity map and 2D depth map data representing the 3D (or 2D) image data, using the low resolution EAS L M pixels that are designated and correspond to the intensity/intensity of the voxels, thereby forming all the voxels.

At this time (operation S3), the controller may transmit a control signal to the OAS L M to write the intensity distribution formed in the photosensitive layer to the phase distribution on the OAS L M L C layer, and the charge distribution in the photosensitive layer may cause the refractive index modulation in the PAS L M L C layer according to the high resolution hologram of the active DOE mask element illuminated by the low resolution EAS L M.

In operation S4, the backlight unit generates a backlight (illumination) for the reflection-type OAS L M, and in operation S5, the diffracted light of the currently displayed hologram (written in the OAS L M) reconstructs the hologram.

A field optical system (one or more lens sets) is required to form the hologram viewing area at a specified distance in the display. The filters may perform spatial/angular/spectral filtering to improve the quality of the displayed 3D hologram and may be passive or active (addressable).

The field optics, filters (when active elements are used) and backlight unit also operate in response to control signals from the controller.

The integrated structure of the incoherent EAS L M, DOE mask array and the reflective OAS L M can reduce the size (thickness) of the holographic display, due to the reduced size, the display can be applied to mobile electronic devices such as smart phones, tablets, wearable electronic devices, etc. the applicability of the incoherent displays and microdisplays in the present disclosure can be used with currently available displays, organic light emitting diode (O L ED) displays, μ light emitting diode (μ -L ED) displays, liquid crystal displays (L CD), etc.

EAS L M used in the holographic display shown in FIG. 7 may be self-luminous (incoherent L ED/. mu. -L ED, O L ED, etc.) or non-self-luminous, depending on the embodiment, when a non-self-luminous E L ASM (e.g., L CD) is used, an additional incoherent backlight (L ED, lamp, etc.) should be used.

In another embodiment (see fig. 9), coherent S L M (EAS L M in this embodiment) is used instead of incoherent S L M so a reflective OAS L M need not be used and OAS L M (see fig. 9) may be omitted or may be switched to a transmission mode (not shown). coherent EAS L M may be of a self-emitting type (e.g., a laser diode array) or a non-self-emitting type.

When coherent S L M is used without OAS L M, the DOE mask may be of either amplitude or phase type, and phase type is more preferred in terms of increasing DOE efficiency.

In another embodiment of the holographic display shown in FIG. 10, an adaptive multi-lens array (M L A) can be used with an addressable spatial light modulator (AS L M) and a DOE mask array.

In this embodiment, a voxel may be formed at a discrete distance zi specified by the DOE mask relative to each voxel in the (x, y) coordinates. The number of possible discrete distances for forming a voxel may be determined by the number of DOE masks.

The adaptive (active) M L A according to the embodiment shown in FIG. 10 may change its spatial position relative to the EAS L M and DOE mask array accordingly, the (zi) position of the (x, y) voxels may be smoothly changed by changing the focal length of each M L A lens.

Thus, according to the present disclosure, the resolution of the displayed hologram, the viewing angle of the hologram, and the processing speed of the digital hologram may be increased by using the DOE mask array. The mask array is a pre-developed and fabricated collection of gratings with critical functions of wavelength size that can increase the diffraction angle and viewing angle of the displayed hologram, reduce numerical calculations (processor load, storage capacity, data transmission rate), and extend battery life.

Furthermore, due to the integrated structure including the incoherent S L M, DOE mask array and OAS L M, holographic displays according to the present disclosure may have a compact design and may use incoherent displays and micro-displays (L ED, O L ED, L CD + L ED, etc.).

Due to the compact design, the holographic display according to the present disclosure may find application in displaying information and generating holographic user interfaces in mobile and wearable electronic devices.

The present disclosure may extend the battery life of mobile electronic devices including holographic displays and reduce cooling requirements for processors, controllers, etc. due to the reduced computational load during holographic patterning.

The need to use only 2D images as input data for 3D hologram formation may reduce the required data transmission bandwidth.

While example embodiments have been described in detail and shown in the accompanying drawings, such embodiments are merely illustrative and are not intended to limit the broader disclosure, and it is to be understood that the disclosure is not limited to the specific configurations shown and those described herein, as various other modifications will be apparent to those skilled in the art.

Although not particularly mentioned, the description about the storage data, the program, and the like obviously means that a computer-readable storage medium can be used. Examples of computer readable storage media include read-only memory, random-access memory, registers, cache memory, semiconductor memory devices, magnetic media such as internal hard drives and removable disk drives, optical media such as CD-ROMs and Digital Versatile Disks (DVDs), and any other general purpose storage media.

The features described in the various dependent claims and the implementation embodiments disclosed in the various parts of the disclosure may be combined to achieve advantageous effects even if the combined capabilities are not explicitly disclosed.