KR20220069507A - Super Multi-View Three Dimensional Display Based See-through Floating Hologram System - Google Patents

Abstract

The present invention relates to a super multi-view three dimensional display based see-through floating hologram system, in which a display unit (120) is installed on a lower table (110) of a case (100) containing a hologram system, so that a hologram image of an object is displayed on a display of the display unit (120). The present invention can provide more realistic contents and images to a user, has a transmissive structure and high transparency, and thus can be optimized for exhibition and promotion. The present invention can remove a half-mirror and can be used in the form of a table top, thereby providing diversity. The present invention can provide a high-resolution three-dimensional floating hologram image with a large depth and thus eliminates the need for special glasses, enables an observation of three-dimensional floating hologram contents with an accurate depth, and enables a user to perform realistic interaction and the like together with the resolution of an image.

Description

Super Multi-View Three Dimensional Display Based See-through Floating Hologram System

The present invention relates to a transmissive floating hologram system based on a super multi-view three-dimensional display, wherein the display unit 120 is installed on the lower table 110 of the case 100 in which the hologram system is embedded, ) as a three-dimensional floating holographic image of an object appears on the display of

The present invention can provide users with more realistic content and images, and is a product optimized for exhibition and publicity due to its high transmissive structure and high transparency. Because it provides high-resolution images with a large sense of depth, there is no need for special glasses, and content with accurate depth can be observed. It relates to a display-based transmissive floating hologram system.

In general, in recent years, there is a trend to develop a hologram system that enables a user to directly and realistically interact with the resolution of an image. In particular, a transmissive real hologram 3D display system is being developed. Publication No. 10-2016-0116145 discloses a glass through which a real object is transmitted through a user's eyes;

a projector for projecting a 3D hologram onto the glass; and

A hologram display device comprising a; a processor for generating the 3D hologram is disclosed.

In addition, in Patent Registration No. 10-0404161, the first and second substrates disposed to face each other;

a cholesteric liquid crystal color filter formed on the inner surface of the first substrate;

a common electrode formed on the entire surface of the substrate covering the cholesteric liquid crystal color filter;

a thin film transistor formed on the inner surface of the second substrate;

a pixel electrode connected to the thin film transistor;

a liquid crystal layer interposed between the common electrode and the pixel electrode;

a hologram diffusion plate located on an outer surface of the second substrate;

and a condensing backlight positioned on the outer surface of the first substrate, wherein the thin film transistor and the pixel electrode form an array element layer, and the array element layer and the hologram diffusion plate part are formed on different surfaces of the same substrate. A transmissive liquid crystal display device is disclosed.

However, the conventional techniques have disadvantages in that the high-resolution image does not have a deep depth and does not have an accurate sense of depth, so that the contents cannot be observed correctly, and the user cannot have realistic interactions due to the low resolution.

Therefore, the present invention has been devised to solve the above problems, and the present invention can provide immersive content and images to users, and is a product optimized for display and publicity due to its high transmissive structure and high transparency, and removes the half mirror and can be used in tabletop format to provide variety to users This is to provide a transmissive floating hologram system based on a super multi-viewpoint 3D display that enables realistic interactions.

The present invention relates to a transmissive floating hologram system based on a super multi-view three-dimensional display, wherein the display unit 120 is installed on the lower table 110 of the case 100 in which the hologram system is embedded, and the display unit ( 120), characterized in that the holographic image of the object appears on the display.

Therefore, the present invention can provide realistic three-dimensional floating hologram contents and images to users, and is a product optimized for display and publicity due to its high transmissive structure and high transparency. It can provide diversity and provides high-resolution holographic images with a large sense of depth, so there is no need for special glasses, it is possible to observe content with an accurate sense of depth, and the user can have realistic interactions with image resolution. It has an excellent effect.

1 is a perspective view of a transmissive floating hologram system based on a super multi-view three-dimensional display of the present invention;
2 is a cross-sectional view of a transmissive floating hologram system based on a super multi-view three-dimensional display of the present invention;
3 is a reproduction principle diagram of a transmissive floating hologram system based on a super multi-view three-dimensional display of the present invention.
4 is a front view of rendering a transmissive floating hologram system based on a super multi-view three-dimensional display of the present invention.
5 is a side view of rendering a transmissive floating hologram system based on a super multi-view three-dimensional display of the present invention.
6 is a rear view of a transmissive floating hologram system rendering based on a super multi-view three-dimensional display of the present invention.
7 is an attachment form of a lenticular optical sheet for manufacturing a super multi-view three-dimensional display of the present invention;
8 is a conceptual diagram of a super multi-view 3D image content generation of the present invention.
9 is a content creation algorithm through a super multi-view three-dimensional display of the present invention;
10 is a diagram illustrating a relationship between a pixel of a display panel and a 3D object in the super multi-view 3D display of the present invention;

The present invention relates to a transmissive floating hologram system based on a super multi-view three-dimensional display, wherein the display unit 120 is installed on the lower table 110 of the case 100 in which the hologram system is embedded, and the display unit ( 120) is characterized in that the three-dimensional floating holographic image of the object appears on the display.

In addition, the display unit is characterized in that a display, a half mirror (1) and a special optical mirror plate (2) are installed.

In addition, the angle between the half mirror and the mirror plate is characterized in that the acute angle.

In addition, it is characterized in that the angle of the display panel is an acute angle.

In addition, plate-shaped guides 111 are installed vertically upward on both upper sides of the table 210, and a telecommunication line coupling hole 3 through which a power line and a communication line are connected is formed in the guide 111, characterized in that do.

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

1 is a perspective view of a transmissive floating hologram system based on a super multi-view 3D display of the present invention, FIG. 2 is a cross-sectional view of a transmissive floating hologram system based on a super multi-view 3D display of the present invention, and FIG. 3 is a super multi-view 3 of the present invention The reproduction principle diagram of the transmissive floating hologram system based on a dimensional display, FIG. 4 is a front view of the rendering of the transmissive floating hologram system based on the super multi-view 3D display of the present invention, and FIG. 5 is the transmissive type based on the super multi-view 3D display of the present invention A side view of rendering a floating hologram system, FIG. 6 is a rear view of a transmissive floating hologram system rendering based on a super multi-view 3D display of the present invention, and FIG. 7 is an attachment form of a lenticular optical sheet for manufacturing a super multi-view 3D display of the present invention , FIG. 8 is a conceptual diagram of generating super multi-viewpoint three-dimensional image content according to the present invention, and a method for correctly displaying a floating holographic image having a three-dimensional depth as a super multi-viewpoint floating hologram image in a super multi-viewpoint floating hologram system will be described. . First, a 3D image in which depth information for a floating hologram image having a 3D depth to be expressed is inverted is required. In the next process, a super multi-viewpoint floating holographic content image is generated for a three-dimensional floating holographic object image whose depth is inverted. The super multi-viewpoint floating holographic content image generated in this way is displayed on the super multi-viewpoint three-dimensional display panel 121 for image output. , shows an example of a method of generating content for the super multi-view 3D display panel 121 to which the lenticular optical element 122 having a uniform or non-uniform thickness is attached. The lenticular optical element 122 can be attached as shown in FIG. 7 , and can be extended and applied to the lenticular optical element 122 or a lens array form.

The steps for obtaining the final super multi-view 3D floating hologram content of the lenticular optical element 122 are as follows in the structure of FIG. 10 . The present invention provides a pixel selection step of selecting any one pixel; a lens positioning step of determining a position of the lenticular optical element 122 corresponding to the selected pixel; a center line calculation step of calculating a center line of the lenticular optical element 122 whose position is determined; a minimum unit value calculation step of calculating a point P coordinate of the calculated center line that is the shortest distance from the selected pixel; an information acquisition step of acquiring information on a corresponding point of a three-dimensional object using the selected pixel and point P coordinates; is made of Then, for all pixels, the pixel selection step to the information acquisition step are repeated, and when information is obtained in the information acquisition step for all pixels, the final super multi-view 3D content is obtained after the information acquisition step. The information of the 3D object recorded in the (x, y)-th pixel must first find the position of the lenticular optical element 122 connected to the (x, y)-th pixel. This process is determined in the lenticular optical element 122 positioning step.

The position k of the lenticular optical element 122 is determined in consideration of the pixel size, position information, and the diameter of the lenticular optical element 122 . Distance information with respect to the selected k-th lenticular optical element 122 with respect to the center line of the lenticular optical element 122 is calculated. This process is performed in the center line calculation step. Through this step, the distance information d is calculated. Next, the point P coordinate of the calculated center line that is the shortest distance from the selected pixel is calculated. Finally, it is an information acquisition step of acquiring information on a corresponding point of a 3D object using the pixel and point P coordinates selected from the conceptual diagram of FIG. 10 . Through this, information on the 3D object corresponding to the (x, y)-th pixel is recorded.

10 is a diagram illustrating a relationship between a pixel of a display panel and a 3D object in a super multi-view 3D display according to the present invention.

The present invention is a transmissive floating hologram system based on a super multi-view three-dimensional display. It is a super multi-view three-dimensional floating hologram that can express a human who can walk on two legs on a table screen. It is a real holographic image with a real sense of depth in a free space. .

And because the hologram image does not exist inside or on the back, but is actually floating in front of the user's eyes, it is for the realization of hologram reality and constitutes a three-dimensional floating hologram display that can directly interact with the user.

It is a real hologram image structure, and real hologram display is implemented in the free space.

The user can directly touch the 3D floating hologram image without the need for special glasses for the high-resolution 3D floating holographic image with a great sense of depth. do

The present invention super multi-viewpoint three-dimensional display-based transmissive floating hologram system has a special optical mirror plate installed on the table upper surface in the lower frame to display an image projected from the lower super multi-viewpoint three-dimensional display panel, and the lower end of the half-mirror is located at the rear end of the display panel. This is coupled, the half mirror is installed to be inclined forward toward the upper part, the angle between them becomes an acute angle.

Soon, the angle between the half mirror and the special optical mirror plate is an acute angle, especially when the angle of the display panel is set to 67.5 degrees and the acute angle of the display panel is 45 degrees, so content with an accurate sense of depth can be observed. interaction, etc.

In short, it can provide users with realistic three-dimensional floating hologram contents and images, has a transmissive structure, and is highly transparent, so it is an optimized product for exhibition and publicity. It can be used in a format to provide variety to users.

100: case
110: lower table
210: the above table
120: display unit
121: super multi-view 3D display panel
122: lenticular optical element
1: Half mirror
2: Special optical mirror plate
3: Telecommunication line coupling hole
4: Guide
5: Holographic image

Claims (3)

The display unit 120 is installed on the upper part of the lower table 110 of the case 100 in which the hologram system is embedded, so that the object is 3D floating on the super multi-view 3D display panel 121 of the display unit 120 . A transmissive floating hologram system based on a super multi-viewpoint three-dimensional display, characterized in that a holographic image is displayed The transmissive real hologram 3D display system according to claim 1, wherein the display unit 120 includes a super multi-view 3D display panel 121, a half mirror 1, and a special optical mirror plate 2 installed. According to claim 2, wherein the angle between the half mirror (1) and the special optical mirror plate (2) is an acute angle, the super multi-view 3D display panel (121), characterized in that the acute angle of the super multi-view 3D display panel (121). Display-based transmissive floating hologram system

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