KR102584129B1 - 5G Interlocking Hologram Image Reconstruction System Based Floating Light-Field - Google Patents

Abstract

The present invention relates to a 5G linked holographic image playback system based on a floating light field, which includes a floating light field 3D display light source 20 inside a case 100 with a floating light field 3D hologram system built in, and the floating light field 3D display light source 20. It is installed on the display light source 20 so that the straight line connecting the center of the floating light field 3D display light source 20 and the center of the special optical element 10 for floating light field reproduction is 90° vertically upward from the horizontal plane. , floating light field holographic image content with a three-dimensional sense of depth appears on the front of the system,
The present invention optimizes the viewing angle (viewing range) of the 3D floating light field hologram content through calibration of the floating light field hologram content with a 3D sense of depth by the floating light field 3D display light source 20 and a simple structure in the form of a kiosk. There is an excellent effect of obtaining a clearer floating light field 3D hologram image.
In addition, it can provide users with more realistic images such as floating light field 3D holographic content and images, and because it has a kiosk shape and a wide viewing angle, it can have a quality higher than that of existing 3D images.
Like existing similar hologram equipment, it has the excellent effect of free and intuitive expression of content as a system and product for users to control interactive content.

Description

5G Interlocking Hologram Image Reconstruction System Based Floating Light-Field}

The present invention relates to a 5G linked holographic image playback system based on a floating light field. More specifically, the present invention relates to a 5G linked holographic image playback system based on a floating light field. More specifically, the present invention relates to a special optical element for playing a floating light field and a high-brightness floating light field based on a light field algorithm. The viewing range of content with 3D volume depth is expanded due to the optical internal structure in which a floating light field 3D holographic image is reproduced on the front of the system by a special optical element for playing 3D volume depth images in the system. By further optimizing it, it is possible to obtain a clearer 3D floating light field hologram image than before, and because it is equipped with an interactive device, the user can directly touch and control the floating light field 3D volume depth hologram image floating on the front. A floating light field-based 5G-linked holographic image playback system that supports resolutions from FHD to 4K, can control depth due to optical internal design, and is equipped with a 5G module to play floating light field 3D holographic images in real time. It's about.

In general, in recent years, there has been a trend of developing holographic systems that allow users to directly engage in realistic interactions with the resolution of images. In particular, direct-view holographic display systems are being developed, and as an example, the prior art is disclosed in an open patent publication. Number 10-2014-0087434 includes an image display panel for displaying two-dimensional or three-dimensional images;

A backlight unit that transmits light to the video display panel;

The backlight unit is,

A three-dimensional image display device has been disclosed, which includes a light source and a diffraction film on which a hologram interference pattern is recorded.

In addition, Patent Publication No. 10-2017-0073119 discloses a display device that includes a bottom portion provided in a lower area;

an image source disposed in an upper area opposite to the bottom portion and projecting a first image onto a transparent screen;

The transparent screen is disposed on the bottom portion and has a plurality of side panels in the shape of a polygonal pyramid or pyramid, thereby generating a hologram of the first image in an internal space; and a transparent display disposed in front of at least one of the plurality of side panels constituting the transparent screen to display a second image, wherein the display device displays a hologram of the first image. A hologram-based three-dimensional image display device has been disclosed, which is configured to display a three-dimensional image by combining the second images.

However, the above-described prior technologies have a narrow viewing range (FOV) of content, the holographic image is located at the rear or inside, and the 3D image is not clear, so it is difficult to provide more realistic content and images to the user, and the viewing angle is narrow. There were drawbacks to the low quality of the 3D images, such as image distortion issues.

Therefore, the present invention was created to solve the above problems. The present invention provides a three-dimensional volume depth sensation expressed and reproduced through a high-brightness floating light field three-dimensional display based on a special optical element for floating hologram reproduction and a light field algorithm. The optical internal structure in which a floating holographic image is played on the front of the system by a special optical element for floating light field playback existing in the system optimizes the viewing range of content with a three-dimensional volume and depth, resulting in a clearer three-dimensional image than before. Floating light field hologram images can be obtained, and since it is equipped with an interactive device, users can directly touch and control the floating light field 3D volume depth hologram image floating on the front, and supports resolutions from FHD to 4K. The goal is to provide a 5G-linked holographic image playback system based on a floating light field that can adjust the sense of depth due to the optical internal design and is equipped with a 5G module to play a floating light field 3D holographic image with a sense of volume depth in real time. .

In addition, it can provide floating light field holographic content and images with a more realistic 3D volume depth to actual users. Floating hologram images based on 3D floating light fields with an optical internal structure and volume depth are observable. Because the range, that is, the viewing angle, is wider than that of existing competing products, it can have a quality higher than existing 3D images, and the deep learning-based content platform allows acquisition and playback of floating light field 3D hologram images, making content expression freer and more intuitive. This is about a 5G-linked hologram video playback system based on an in-floating light field.

The present invention relates to a 5G linked holographic image playback system based on a floating light field, comprising a case (100) with a built-in floating light field hologram system, a special optical element (10) for floating light field playback installed inside, and an internal optical design stand. (11), featuring a floating light field 3D display (20), a 3D volume depth image reproduction optical element (21), and an internal laser light source for the floating light field (40). In addition, on the outside of the case 100, there are wires, a communication line coupler 200, a movable wheel 300, and a power button 400, and the user can directly experience a more realistic sense of volume and depth through the interactive device 30. It has the feature of controlling floating light field 3D holographic image content.

Therefore, the present invention is a special optical element for reproducing a floating hologram and a special optical element for reproducing a floating light field existing in a system that displays and reproduces a 3D volume depth image through a high-brightness floating light field 3D display based on a light field algorithm. Due to the optical internal structure in which the floating light field 3D hologram image is played on the front of the system, the viewing range of content with 3D volume depth can be optimized to obtain a clearer 3D floating light field hologram image than before. Because it is equipped with an interactive device, the user can directly touch and control the floating light field 3D hologram image floating on the front. It supports resolutions from FHD to 4K, and the sense of depth can be adjusted due to the optical internal design. Equipped with a 5G module, it has the excellent effect of playing floating light field 3D volume depth holographic images in real time.

In addition, it can provide floating light field hologram content and images with realistic 3D volume depth to actual users. The floating light field hologram image, which has an optical internal structure and is based on 3D volume depth, has an observation range, that is, Because the viewing angle is wider than that of existing competing products, it can have a quality higher than existing 3D images, and the deep learning-based content platform allows acquisition and playback of floating light field 3D holographic images, providing excellent effects that allow free expression of content and are more intuitive. There is.

Figure 1 is a cross-sectional view of the 5G linked holographic image playback system based on the floating light field of the present invention.
Figure 2 is a hologram image playback concept diagram 1 for the 5G linked hologram image playback system based on the floating light field of the present invention (using a display light source)
Figure 3 is a holographic image playback concept diagram 2 for the 5G linked hologram image playback system based on the floating light field of the present invention (using an internal laser light source for the floating light field)
Figure 4 shows a hologram image playback method through 5G communication of the present invention's floating light field-based 5G linked hologram image playback system.
Figure 5 is a front view rendering of the 5G linked holographic image playback system based on the floating light field of the present invention.
Figure 6 is a rendering side photo of the 5G linked holographic image playback system based on the floating light field of the present invention.
Figure 7 is a diagram showing the attachment form of a lenticular optical sheet for producing 5G-linked 3D holographic images based on a floating light field in the present invention.
Figure 8 is a conceptual diagram of floating light field 3D image content generation in the present invention.
Figure 9 is a content creation algorithm through a floating light field 3D display in the present invention.
Figure 10 is a diagram showing the relationship between pixels of a display panel and a 3D object in a floating light field 3D display according to the present invention.

The present invention relates to a 5G linked holographic image playback system based on a floating light field, and includes a special optical element (10) for floating light field playback inside a case (100) in which the floating light field hologram system is built-in, and an internal optical design stand (11). ), a high-brightness floating light field 3D display (20), a 3D volume depth image playback optical element (21), an interactive device (30), and an internal laser light source for the floating light field (40) are installed to create a special display for floating light field playback. It is characterized in that a floating light field 3D holographic image with a 3D sense of depth appears through the optical element 10.

And the case 100 consists of an external wire, a communication cable coupler 200, a movable wheel 300, and a power button 400, and provides a three-dimensional sense of depth through a special optical element 10 for floating light field reproduction. It is characterized by the appearance of a three-dimensional holographic image with a floating light field.

In addition, since a high-brightness floating light field 3D display 20 through an optical design and an internal laser light source 40 for the floating light field are installed inside the case 100, the user can use the desired light source, which is suitable for use in the surrounding environment. It is characterized in that the user can use it appropriately according to the method of use, installation space, etc.

The present invention will be described in detail with the accompanying drawings as follows.

Figure 1 is a cross-sectional view of a 5G-linked holographic image playback system based on a floating light field of the present invention, Figure 2 is a holographic image playback conceptual diagram 1 (using a display) for a 5G-linked holographic image playback system based on a floating light field of the present invention, and Figure 3 is Holographic image playback concept diagram 2 for the 5G-linked holographic image playback system based on the floating light field of the present invention (using an internal laser light source for the floating light field), Figure 4 shows 5G communication of the 5G-linked holographic image playback system based on the floating light field of the present invention. 5 is a rendering front view of a 5G-linked holographic image playback system based on a floating light field of the present invention, and FIG. 6 is a rendering side view of a 5G-linked holographic image playback system based on a floating light field of the present invention. 7 is a diagram of the attachment form of a lenticular optical sheet for producing 5G-linked 3D holographic images based on a floating light field in the present invention, and Figure 8 is a conceptual diagram of the creation of floating light field 3D image content in the present invention, with a 3D depth. We explain how a floating light field holographic image is correctly displayed as a floating light field 3D holographic image in a floating light field-based 5G interconnected holographic image system. First, a two-dimensional floating hologram image with inverted depth information is needed for the floating light field holographic image with the depth of the two-dimensional plane that is to be expressed. In the next process, a floating light field holographic content image is generated for the 3D floating holographic object image with inverted depth. The floating light field 3D hologram image content created in this way is provided with a floating light field 3D display (20) and a special optical element (10) for floating light field playback through an internal laser light source (40) for the floating light field for effective image playback. 9 is a flowchart explaining the content creation algorithm through a floating light field 3D display in the present invention, and a 3D volume depth image reproduction optical element 21 having a uniform or non-uniform thickness is attached. An example of a method for generating content for a high-brightness floating light field 3D display 20 is shown. The 3D volume depth image reproducing optical element 21 can be attached as shown in FIG. 7, and can be expanded and applied in the form of a 3D volume depth image reproducing optical element 21 or an existing lens array. The steps for acquiring the final floating light field 3D hologram content of the 3D volume depth image reproduction optical element 21 can be seen through the structure of FIG. 10, and the details are as follows. The present invention includes a pixel selection step of selecting a certain pixel; A lens positioning step of determining the position of the 3D volume depth image reproduction optical element 21 corresponding to the selected pixel; A center line calculation step of calculating the center line of the positioned 3D volume depth image reproduction optical element 21; A shortest position calculation step of calculating the coordinates of the point P of the calculated center line that is the shortest distance from the selected pixel; An information acquisition step of acquiring corresponding point information of a 3D object using the selected pixel and point P coordinates; It consists of Then, the pixel selection step and the information acquisition step are repeated for all pixels, and if information is acquired in the information acquisition step for all pixels, the final floating light field 3D holographic image content is obtained after the information acquisition step. Information on a 3D object recorded at the (x, y)th pixel must first find the location of the 3D volume depth image reproducing optical element 21 connected to the (x, y)th pixel. This process is determined in the position determination step of the dimensional volume depth image reproduction optical element 21.

The position k of the 3D volume depth image reproduction optical element 21 is determined by considering the pixel size, position information, and diameter of the 3D volume depth image reproduction optical element 21. For the selected kth 3D volume depth image reproducing optical element 21, distance information from the center line of the 3D volume depth image reproducing optical element 21 is calculated. This process is performed in the centerline calculation step. Through this step, distance information d is calculated. Next, calculate the point P coordinates of the calculated center line, which is the shortest distance from the selected pixel. Lastly, there is an information acquisition step in which information on corresponding points of the 3D object is acquired using the pixels and point P coordinates selected from the conceptual diagram of FIG. 10. Through this, information about the 3D object corresponding to the (x, y)th pixel is recorded.

FIG. 10 is a diagram showing the relationship between pixels of the display light source and a 3D object in the floating light field 3D display light source 20 in the present invention.

The present invention is a 5G-linked holographic image playback system based on a floating light field based on a high-brightness floating light field 3D display (20) in the form of a kiosk with a new concept.

It is a floating light field 3D hologram that can represent a human being capable of walking on two feet in a system with a kiosk or tabletop structure, and is a floating light field hologram image with a high sense of depth in an actual free empty space. And, rather than a 2D hologram image existing inside or behind like existing similar hologram equipment, a floating light field 3D hologram actually floats in front of the user's eyes to express a 3D sense of depth, making it the first step toward realizing Hologram Reality. It can be called a step.

The present invention is a floating light field-based 5G-linked holographic image playback system that allows direct interaction events between customers directly using the system and floating light field 3D hologram content, and is a floating light field 3D hologram with a three-dimensional sense of depth. It has an optical internal and external structure that can reproduce images.

Therefore, it is possible to play a floating light field 3D hologram image with a 3D sense of depth in a spacious space in the air, and provides a high-resolution floating light field 3D hologram image with a small or large sense of depth depending on the design method desired by the customer.

In addition, there is no need for special glasses like existing 3D displays and similar hologram equipment, and users can directly touch the floating light field 3D hologram image through an interactive device. Space Position Detection technology is applied to recognize coordinates in space. It serves as a medium to express realistic, interactive content.

The 5G linked holographic image playback system based on the floating light field of the present invention can provide users with more realistic floating light field holographic content and holographic images with a three-dimensional sense of depth.

It has a kiosk-shaped structure and has a much larger viewing angle compared to existing similar hologram equipment, so it can have a quality higher than that of existing 3D images. As a system and product, the user can directly control the content, making the content more intuitive. It has the advantage of freedom of expression.

The case 100 of the present invention includes a special optical element 10 for reproducing a floating light field inside, an internal optical design stand 11, a high-brightness floating light field 3D display 20, and an optical element for reproducing a 3D volume depth image. (21), the interactive device 30, an internal laser light source 40 for the floating light field is installed and consists of a special optical element 10 for reproducing the floating light field. A floating light field 3D hologram image with a 3D sense of depth appears through the special optical element 10 for reproducing the floating light field.

On the other hand, the case 100 has a kiosk shape and is composed of an electric wire, a communication line coupler 200, a movable wheel 300, and a power button 400 at the rear, and a special optical element for playing a floating light field ( 10) is characterized by the appearance of a floating light field 3D holographic image with a 3D sense of depth.

The special optical element 10 for floating light field reproduction is mainly installed horizontally or inclined from the horizontal plane in the case 100. It is installed at a 45° angle as shown in the drawing, so that the user can observe the floating light field 3D hologram image like a regular monitor screen. It is designed to do so.

Therefore, in the present invention, the floating light field 3D display light source 20 and the special optical element 10 for floating light field reproduction are installed in a right-angled (90 degree) structure with respect to the center line.

As a result, the special optical element 10 for reproducing the floating light field creates a single floating light field 3D holographic content image through the high-brightness floating light field 3D display 20 or the internal laser light source 40 for the floating light field.

The installation relationship between the special optical element 10 for reproducing the floating light field and the high-brightness floating light field 3-dimensional display 20 is the center of the high-brightness floating light field 3-dimensional display 20 and the special optical element 10 for reproducing the floating light field. The straight line connecting the centers is installed at an angle of 90° vertically upward from the horizontal plane. This is due to the depth and resolution of the floating light field 3D holographic content, calibration, and the viewing range of the floating light field 3D holographic content due to the kiosk-type structure. That is, to optimize the viewing angle.

In other words, the present invention sets the central angle of the special optical element 10 for floating light field reproduction and the high-brightness floating light field 3D display 20 to 90 degrees, and the calibration of the floating light field 3D holographic content and the internal and external display due to the kiosk-type structure are provided. This is to optimize the optical design of the structure.
Therefore, the present invention includes a high-brightness floating light field 3-dimensional display (20) inside a case 100 in which a floating light field 3-dimensional hologram system is built; and
A special optical element (10) for floating light field reproduction is installed to correspond to the high-brightness floating light field three-dimensional display (20),
A floating light field three-dimensional hologram image appears on the special optical element 10 for playing the floating light field,
In the case 100, an internal laser light source 40 for a floating light field is installed at the lower corner, and a high-brightness floating light field 3D display 20 composed of a 3D volume depth image reproduction optical element 21 is installed at a height. It is installed horizontally in the middle position, and a special optical element 10 for floating light field reproduction is installed upwardly from the high-brightness floating light field 3D display 20,
The image of the high-brightness floating light field 3D display 20 displays a floating light field 3D hologram content image converted by an algorithm through the 3D volume depth image reproduction optical element 21, and the volume depth image reproduction optical element 21 The element 21 is a lenticular lens, which is stacked and disposed on a high-brightness floating light field 3-dimensional display 20. The high-brightness floating light field 3-dimensional display 20 is transparent so that the beam output from the lower laser light source passes through. ,
The image of the internal laser light source (40) for the floating light field is converted into an algorithm through the 3D volume depth image reproduction optical element (21). A floating light field-based holographic image playback system that displays the floating light field 3D holographic content image. In
The special optical element 10 for playing the floating light field is installed in the case 100 inclined from the horizontal plane at a 45° angle so that the user can observe the floating light field 3D hologram image like a regular monitor screen, The high-brightness floating light field 3D display 20 and the special optical element 10 for reproducing the floating light field are installed in a right-angled structure with respect to the center line, and the special optical element 10 for reproducing the floating light field is One floating light field 3D hologram content image is created through the high-brightness floating light field 3D display 20, and an internal optical design stand 11 is installed below the special optical element 10 for playing the floating light field. , Floating light field 3D hologram content of an object appears on the special optical element 10 for floating light field reproduction,
The optical path of the internal laser light source 40 for the floating light field is such that after the beam output from the laser light source 40 passes through the high-brightness floating light field 3D display 20, the 3D volume depth image reproduction optical element 21 ), the laser light source 40 serves as a backlight light source of the high-brightness floating light field three-dimensional display 20 by being reflected from the special optical element 10 for reproducing the floating light field.

100: case
200: Electric wire, communication line joint
300: mobile wheels
400: Power button
10: Optical element for floating light field reproduction
11: Internal optical design base
20: High brightness floating light field 3D display
21: 3D volume depth image playback optical element
30: Interactive device
40: Internal laser light source for floating light field

Claims (4)

A high-brightness floating light field 3-dimensional display (20) inside a case (100) containing a floating light field 3-dimensional hologram system; and
A special optical element (10) for floating light field reproduction is installed to correspond to the high-brightness floating light field three-dimensional display (20),
A floating light field three-dimensional hologram image appears on the special optical element 10 for playing the floating light field,
In the case 100, an internal laser light source 40 for a floating light field is installed at the lower corner, and a high-brightness floating light field 3D display 20 composed of a 3D volume depth image reproduction optical element 21 is installed at a height. It is installed horizontally in the middle position, and a special optical element 10 for floating light field reproduction is installed upwardly from the high-brightness floating light field 3D display 20,
The image of the high-brightness floating light field 3D display 20 displays a floating light field 3D hologram content image converted by an algorithm through the 3D volume depth image reproduction optical element 21, and the volume depth image reproduction optical element 21 The element 21 is a lenticular lens, which is stacked and disposed on a high-brightness floating light field 3-dimensional display 20. The high-brightness floating light field 3-dimensional display 20 is transparent so that the beam output from the lower laser light source passes through. ,
The image of the internal laser light source (40) for the floating light field is converted into an algorithm through the 3D volume depth image reproduction optical element (21). A floating light field-based holographic image playback system that displays the floating light field 3D holographic content image. In
The special optical element 10 for playing the floating light field is installed in the case 100 inclined from the horizontal plane at a 45° angle so that the user can observe the floating light field 3D holographic image like a regular monitor screen, The high-brightness floating light field 3D display 20 and the special optical element 10 for reproducing the floating light field are installed in a right-angled structure with respect to the center line, and the special optical element 10 for reproducing the floating light field is One floating light field 3D holographic content image is created through the high-brightness floating light field 3D display 20, and an internal optical design stand 11 is installed below the special optical element 10 for playing the floating light field. , Floating light field 3D hologram content of an object appears on the special optical element 10 for floating light field reproduction,
The optical path of the internal laser light source 40 for the floating light field is such that after the beam output from the laser light source 40 passes through the high-brightness floating light field 3D display 20, the 3D volume depth image reproduction optical element 21 ), the laser light source 40 is reflected from the special optical element 10 for reproducing the floating light field, and the laser light source 40 serves as a backlight light source for the high-brightness floating light field three-dimensional display 20. Light field-based holographic image playback system delete delete delete