KR20220069509A - Super Multi-View Three Dimensional Display Based Direct-View Floating Hologram System - Google Patents

Abstract

The present invention relates to a super multi-view three dimensional display based direct-view floating hologram system. In a case (100) where a super multi-view three-dimensional display and a floating hologram system are accommodated, left and right special optical mirror plates (11, 21) are installed corresponding to left and right super multi-view three-dimensional display panels and left and right super multi-view three-dimensional display panels, so that floating hologram images having a three-dimensional depth can be displayed on the left and right special optical mirror plates (11, 21). The present invention enables calibration of both three-dimensional contents by the left and right special optical mirror plates and optimize the viewing range of three-dimensional floating hologram contents by the simple direct-view structure, thereby obtaining a clear super multi-view three-dimensional floating hologram. In addition, the present invention can provide a user with realistic three-dimensional floating hologram contents and images, and has a novel direct-view structure with a wide viewing angle, thereby providing the quality equal to or higher than that of existing three-dimensional images, and enables the user to adjust directionality, such as horizontal and vertical directionality, using one product, thereby providing excellent effects of free expression and intuitive expression of contents.

Description

{Super Multi-View Three Dimensional Display Based Direct-View Floating Hologram System}

The present invention relates to a direct-view floating hologram system based on a super multi-viewpoint three-dimensional display, and more particularly, to a three-dimensional depth image reproduced on a three-dimensional display expressed through a high-brightness display panel to which a super multi-view optical element is attached. Super multi-view 3D to obtain clear 3D holographic images by further optimizing the viewing range of contents by calibration of both contents by a special optical mirror plate on the left and right sides of the system and a simple structure of direct view structure It relates to a display-based direct-view floating hologram system.

In general, in recent years, there is a trend to develop a hologram system that allows a user to directly and realistically interact with the resolution of an image. In particular, a direct-view type hologram display system is being developed. No. 10-2014-0087434 has an image display panel for displaying a two-dimensional or three-dimensional image;

a backlight unit for irradiating light to the image display panel;

The backlight unit is

There is disclosed a stereoscopic image display device comprising a diffraction film on which a light source and an interference pattern for a hologram are recorded.

In addition, Korean Patent Laid-Open Publication No. 10-2017-0073119 discloses a display device comprising: a bottom portion provided in a lower region;

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

the transparent screen disposed on the bottom portion and configured to have a polygonal pyramid or pyramidal pyramid shape to generate a hologram of the first image in an internal space; and a transparent display disposed in front of at least one of a plurality of side panels constituting the transparent screen to display a second image; the display device is configured to include a hologram of the first image. A hologram-based stereoscopic image display device, characterized in that the second image is combined to display a stereoscopic image, is disclosed.

However, in the prior art, since the viewing range of the content is narrow and the floating hologram is not clear, it is difficult to provide realistic content and images to the user, and the viewing angle is narrow and the quality of the 3D image is low, such as image distortion. .

Therefore, the present invention has been devised to solve the above problems, and the present invention provides a three-dimensional depth image expressed by a development algorithm through a high-brightness display panel to which a super multi-view exclusive optical element is attached to the left and right sides of the system. It aims to provide a direct-view floating hologram system based on a clearer super multi-view 3D display by optimizing the content viewing range by calibrating both contents by a special optical mirror plate and by a simple structure of direct view type.

In addition, as it can provide users with realistic 3D-based content and images, it has a direct-view structure, and the floating holographic image based on the super multi-viewpoint 3D display has a large observation range, that is, the viewing angle, so it is superior to the existing 3D image. It relates to a direct-view floating hologram system based on a super multi-viewpoint 3D display that can have quality and can have a user-desired horizontal and vertical format as a single product, so that the expression of content is free and intuitive.

The present invention relates to a direct-view floating hologram system based on a super multi-view three-dimensional display. Special optical mirror plates 11 and 21 are installed, and super multi-viewpoint three-dimensional floating holographic images are displayed on the left and right special optical mirror plates 11 and 21 .

Therefore, the present invention has an excellent effect of optimizing the content viewing range by the calibration of both content by the left and right special optical mirror plates and the simple structure of the direct view structure to obtain a clearer super multi-view three-dimensional floating hologram image. .

In addition, it can provide users with more realistic 3D content and holographic images, has a direct-view type structure, and has a large observation range (viewing angle), so it can have higher quality than existing 3D images, and as a product, users can As it can have the desired horizontal and vertical format, there is a remarkable effect that the expression of content is free and intuitive.

1 is a cross-sectional view of a direct-view floating hologram system based on a super multi-view three-dimensional display of the present invention;
2 is a conceptual diagram of a three-dimensional hologram by a direct-view floating hologram system based on a super multi-view three-dimensional display of the present invention.
3 is a reproduction principle diagram of a direct-view floating hologram system based on a super multi-viewpoint three-dimensional display of the present invention.
4 is a front view of rendering a direct-view floating hologram system based on a super multi-view three-dimensional display of the present invention.
5 is a side view of rendering a direct-view floating hologram system based on a super multi-view 3D display of the present invention.
6 is a rear view of a direct-view floating hologram system rendering based on a super multi-view 3D 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 direct-view floating hologram system based on a super multi-view three-dimensional display, and each of the left and right super multi-view three-dimensional display panels and the left and right display panels inside the case 100 in which the hologram system is embedded. The left and right special optical mirror plates 11 and 21 are installed so as to correspond, and a holographic image with a three-dimensional sense of depth is displayed on the left and right special optical mirror plates 11 and 21.

In addition, the case 100 includes a left part 10 in which a left super multi-view 3D display panel 12 and a left special optical mirror plate 11 are installed, a right super multi-view 3D display panel 22 and a right It consists of a right part 20 on which a special optical mirror plate 21 is installed, and a three-dimensional floating hologram image of an object is displayed on the left special optical mirror plate 11 and the right special optical mirror plate 21. do.

In addition, the left portion 10 is inclined so that the width becomes smaller toward the center, and the right portion 20 is also inclined so that the width becomes smaller toward the center, so that the horizontal cross section is a triangle, and the left and right special optical mirrors Two super multi-view 3D floating hologram images or one merged super multi-view 3D floating hologram image can be observed by the plates 11 and 21 .

In addition, it is characterized in that a coupler 2 to which a power source or a communication line is connected is formed on one side of the left and right parts 20 .

In addition, each image of the left and right special optical mirror plates 11 and 21 can display content images with different 3D depth due to the super multi-viewpoint 3D display manufacturing method and optical internal design, It is characterized in that it can express the merged super multi-view 3D floating hologram image.

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

1 is a cross-sectional view of a direct-view floating hologram system based on a super multi-view 3D display of the present invention. is a reproduction principle diagram of a direct-view floating hologram system based on a super multi-view three-dimensional display of the present invention, FIG. 4 is a front view of a direct-view floating hologram system rendering based on a super multi-view three-dimensional display of the present invention, and FIG. 5 is a front view of the present invention of the super multi-view 3D display-based direct-view floating hologram system rendering side view, FIG. 6 is a super-multi-view 3D display-based direct-view floating hologram system rendering rear view of the present invention, and FIG. 7 is a super multi-viewpoint view of the present invention Attachment form of a lenticular optical sheet for 3D display production, FIG. 8 is a conceptual diagram of super multi-view 3D image content creation of the present invention, and a floating holographic image having a 3D depth is a super multi-viewpoint in a super multi-view floating hologram system A method of correctly displaying a floating hologram image 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 generated super multi-viewpoint floating holographic content image is displayed on the left and right super multi-view 3D display panels 12 and 22 for image output. This is a description of the algorithm, and a method of generating content for left and right super multi-view 3D display panels 12 and 22 to which left and right lenticular optical elements 13 and 23 having uniform or non-uniform thickness are attached show an example of The left and right lenticular optical elements 13 and 23 can be attached as shown in FIG. 7 , and can be extended and applied to the left and right lenticular optical elements 13 and 23 or in the form of a lens array.

The steps for obtaining the final super multi-view 3D floating hologram content of the left and right lenticular optical elements 13 and 23 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 positions of the left and right lenticular optical elements 13 and 23 corresponding to the selected pixel; a center line calculation step of calculating the center lines of the left and right lenticular optical elements 13 and 23 whose positions are 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 And repeating from the pixel selection step to the information obtaining step for all pixels, and obtaining the information in the information obtaining step for all pixels, the final super multi-view 3D content is obtained after the information obtaining step. For the information of the 3D object recorded in the (x, y)-th pixel, the positions of the left and right lenticular optical elements 13 and 23 connected to the (x, y)-th pixel must be found first. This process is determined in the step of determining the positions of the left and right lenticular optical elements 13 and 23 .

The positions k of the left and right lenticular optical elements 13 and 23 are determined in consideration of the pixel size, position information, and diameters of the left and right lenticular optical elements 13 and 23 . Distance information with respect to the selected k-th left and right lenticular optical elements 13 and 23 with respect to the center line of the left and right lenticular optical elements 13 and 23 is calculated. This process is performed in the centerline 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 direct view floating hologram system based on a new type of super multi-view 3D display with a new concept.

It is a super multi-view 3D floating hologram that can express a human being able to walk on two legs on a table screen, and 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.

In other words, the present invention is a direct-view floating hologram system based on a super multi-viewpoint three-dimensional display that enables a direct interaction event between a user and three-dimensional floating hologram content, and has an image structure capable of displaying a floating hologram with a three-dimensional sense of depth.

Therefore, it is possible to display a floating holographic image with a three-dimensional sense of depth in a spacious space, and provides a high-resolution three-dimensional image image with a great sense of depth.

And since there is no need for special glasses, the user can directly touch the 3D floating hologram image, and the interactive content can be expressed by applying the technology that can recognize coordinates in space.

The direct-view floating hologram system based on the super multi-view three-dimensional display of the present invention can provide more realistic content and a three-dimensional floating hologram image to the user.

It has a direct-view structure and has a very large viewing angle, so it can have a quality that is higher than that of a conventional 3D image. There are advantages to being free.

That is, the case 100 of the present invention includes a left part 10 on which the left super multi-view 3D display panel 12 and the left special optical mirror plate 11 are installed, and the right super multi-view 3D display panel 22 ) and the right side portion 20 on which the right side special optical mirror plate 21 is installed. A three-dimensional floating hologram of an object and content appears on the special optical mirror plate 11 on the left and the special optical mirror plate 21 on the right.

On the other hand, the left portion 10 is inclined so that the width becomes smaller toward the center, and the right portion 20 is also inclined so that the width becomes smaller toward the center, so that the horizontal cross section becomes a triangle. The overall case shape becomes a shape (Degree: 90 degrees) in which the front center is concave to the rear in a rectangular cross section. Therefore, a left super multi-view 3D display panel is installed on the left side of the interior, which becomes a triangular wall surface, on the left side of the system, and a special optical mirror plate 11 on the left side is installed on the interior inclined surface that becomes a triangular wall surface to be inclined with respect to the front. is installed A right super multi-view 3D display panel 22 is installed on the right side of the inside, which becomes a triangular wall, on the right side, and a special optical mirror plate 21 on the right side is installed on the inner inclined surface that becomes a triangular inclined wall, so as to be inclined with respect to the front. is installed

Therefore, in the present invention, the two displays and the left and right special optical mirror plates are installed to form a structure at right angles to each other at 90 degrees.

As a result, two special optical mirror plates create one three-dimensional floating holographic content image through two independent super multi-view three-dimensional display panels.

Each image of the left and right special optical mirror plates displays half and half of the three-dimensional floating hologram content image.

The angle between the left and right mirror plates on the left and right is set to 90 degrees, which is to optimize the content viewing range, that is, the viewing angle due to the calibration of both content and the direct viewing structure.

In other words, the present invention is to optimize the structural optical design due to the calibration of both three-dimensional floating hologram contents and the direct view structure by setting the angle between the left and right special optical mirror plates on the left and right to 90 degrees.

100: case
10: left part
11: Left special optical mirror plate
12: Left super multi-view 3D display panel
13: Left super multi-view lenticular optical element
20: right side
21: right special optical mirror plate
22: Right super multi-view 3D display panel
23: Right super multi-view lenticular optical element
2: Wire, communication line connector

Claims (3)

Left and right super multi-view 3D display panels 12 and 22 and left and right special optical mirror plates ( 11 and 21) are installed, so that a three-dimensional floating hologram image is displayed on the left and right special optical mirror plates 11, 21. A direct-view floating hologram system based on a super multi-viewpoint three-dimensional display According to claim 1, wherein the case 100 is a left super multi-view 3D display panel 12 and a left special optical mirror plate 11 are installed, the left portion 10, and the right super multi-view 3D display panel ( 22) and a right part 20 on which the right special optical mirror plate 21 is installed, and the three-dimensional floating hologram of the object is displayed on the left special optical mirror plate 11 and the right special optical mirror plate 21 Direct view floating hologram system based on super multi-view 3D display, characterized in that [Claim 3] The direct-view type based on a super multi-view 3D display according to claim 2, wherein each image of the left and right special optical mirror plates (11, 21) displays half and half of a three-dimensional floating hologram content image, respectively. Floating Hologram System

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