KR20180128329A - Image system for synthesising in space with separated images - Google Patents

Abstract

The present invention relates to an apparatus for spatially separated images in which one image is separated into a short-range image and a long-range image on two or one image display, wherein the short-range image is disposed on a front side, the long-range image is disposed at a long distance, and a translucent mirror is provided on a front surface of the short-range image so as to synthesize the short-range image and the long-range image while the short-range image and the long-range image are separated from each other by a space distance. Therefore, an effect of viewing a realistic image by a glassless 3D effect being in perspective by a distance separation effect can be generated, and a spatially realistic image in vertical left and front directions, front and rear directions, left and right directions, and one left or right direction can be obtained. Accordingly, the apparatus for spatially separated images can view a spatial 3D image having 4-10 times higher definition without a pair of polarizing glasses.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a space-

The present invention relates to an apparatus for separating an image into a near-field image and a long-distance image, and then separating the respective images from each other and synthesizing them in a space to convert them into a space-realistic image. The present invention relates to a spatial separation imaging apparatus having a feature of sensing stereoscopic realism.

Spatial separation image is a so-called Space Reality effect, which generates spatial spatial sensation by separating an image into a distance and a near spatial unit, and is different from a 3D stereoscopic image.

That is, the stereoscopic spatial image is formed by perspective.

For example, a theater that performs on the stage, a performance by a singer, a game with a sports background, a sports game with a background of the athletic field, and a commercial image promoting a product are classified into a near image with motion such as a singer and an actor, And is configured on the plane screen 2D of the display unit.

 In addition, a conventional general stereoscopic (3D) image has a separate stereoscopic left eye image and a right eye image, respectively, and causes the brain to be misunderstood due to the difference in synthesis. Therefore, it causes dizziness, separates through polarized light, and needs to be watched with polarizing glasses again. Therefore, the brightness suddenly drops to 1/10 or less, resulting in blurred image and fatigue easily.

In addition, the method using such a polarizing plate and polarized glasses can not be used as a commercial image device for people who flow because polarized glasses can not be carried to a specific and unspecified number of people.

 In addition, conventionally, the translucent mirror has a translucent translucent translucent mirror which is made of an opaque material such as aluminum to deposit an opaque material such as aluminum, and thus the reflective surface of the opaque material remains when installed in the space.

 The present invention further improves brightness and sharpness by 4 to 10 times by improving applicant's U.S. Patent No. 8,279,271 and separating the near and far images from the space in a non-polarized glasses structure without polarizing glasses, It has been improved and developed in a new way to match images.

Some of the holographic images composed of the existing inverted pyramid structure are simple images that present one image in many directions, and there is no near or far perspective.

The conventional imaging device such as a transmissive LCD provides an image in the plane of the vertical thin film as shown in FIG. 1 (b), so that it is impossible to form a three-dimensional effect due to the so-called card board phenomenon.

 Korean Patent Application No. 10-1999-0017653 and Korean Patent Application No. 20-2014-0006899 do not disclose a method of detecting a space reality by separating a long distance image and a short distance image and rearranging them together as in the invention.

International Patent Document 1. US PAT NO. 8,279,271 Patent Document 1. Korean Application No. 10-1999-0017653 Patent Document 2. Korean Application No. 20-2014-0006899

In view of the above problems, the present invention proposes a method of obtaining a sense of spatial feeling by a natural perspective, a method of obtaining such perspective reality, and a method of implementing a high-definition image in a non-eyeglass system.

The present invention

   A single image input to the spatial separation apparatus is divided into a near image and a remote image,

    And a periphery of the near vision image is formed as a dark background of a certain brightness so that the far vision image can be transmitted through the near vision image

    The first and second image displays separately displaying the near image and the remote screen,

     The position of the second image display forms an image separation distance from the first image display in order for the near vision and the long-distance image to generate a sense of reality by perspective in the square space

  And a translucent mirror having a transparent structure in a rectangular shape on the front side of the near vision image

   And a translucent light function in which a spatial perspective is generated by the spacing distance and the rectangular space interact with each other organically at the same time, thereby creating a spatial stereoscopic effect due to perspective.

 As another method, one image display is configured to divide the near image and the far image into two

     In order to generate the distance and the distance between the near vision image and the far vision image, a first reflector is formed in a square shape

    A semi-transparent mirror for forming a rectangular space is formed on the front surface of the near vision image.

Another method is to have one observation port in each of the above-mentioned constitution methods, and the black matte surface is provided in one direction of the translucent gauge, so that the black matte surface transmits or reflects the translucent gauge, thereby giving a shadow effect to the near- Take it and make the sharpness increase 2-4 times.

In another method, the structure of either the first or second image display or the structure of the first and second image displays is configured as a projector and a screen to increase the brightness of the near vision image by 20 times.

Another method is to configure the first and second observation ports 2 and 2a at both ends of the semi-transparent mirror in each of the above structures so that the image can be viewed in both right and left directions, And can be viewed in both the left and right directions or in both forward and backward directions along the square direction of the second reflector 5a.

In addition, the structure of the present invention is configured as a vertical type image box

 A large number of video boxes are installed according to the moving direction of the spectators

Installed for continuous display.

In the present invention as described above, a long distance image and a short distance image separated from one image are spaced apart from each other in a space

 A far-field image located on the back side is transmitted through a dark background around the near-vision image, and then synthesized into a single image, thereby creating a spatial sense of feeling by perspective.

  In addition, a sense of reality is generated in a space by synthesizing a perspective space effect (z) and a perspective space effect (B) as shown in FIG.

The first and second observation holes are formed according to the reflection direction and the transmission direction of the semi-transparent mirror to simultaneously view the same image in front, left, right, left, right, right, Respectively.

 The configuration of the black matte plate which is provided in one direction of the translucent mirror and gives a dark shadow effect increases the sharpness of the image 2-8 times.

   Accordingly, unlike the prior art, the present invention separates one image into a long distance image and a short distance image, arranges the respective images at a distance from one another in a short distance and synthesizes them according to viewing direction in a rectangular space (z) The function and action that can be watched interact with each other organically so that the image with a spatial stereoscopic effect can be presented at a high definition of 4 to 10 times or more with no glasses without polarized glasses.

1 (a) is an explanatory diagram for separating one image into a near image and a dark background and a far image
1 (b) is an explanatory view of a transparent LCD image plate
Fig. 2 is a schematic view of a rectangular space z having a square shape of translucent light 3
FIG. 3 (a) is an explanatory diagram of a two-
Fig. 3 (b) is a three-
4 (a), 4 (b), 4 (c) and 4 (d)
5 (a) and 5 (b) show left and right multi-image structure explanatory diagrams
6 (a) and 6 (b) are diagrams for explaining the two-way viewing structure
6 (c) shows left and right two-way viewing structure explanatory diagrams
Fig. 7 is a diagram illustrating the configuration of the projector and the projection screen
8 (a), 8 (b) and 8 (c) illustrate one image display and left and right multi-
FIG. 9 is a view showing one video display and a front and back two-
10 (a), 10 (b), 10 (c) and 10 (d)
FIG. 11 is an explanatory diagram of a multi-
12 (a) and 12 (b) are explanatory diagrams of the exhibition hall structure
Fig. 13 is an explanatory diagram when combined with a desk structure.
FIG. 14 is a block diagram illustrating the configuration of the advertisement device
15 (a) and 15 (b) are explanatory diagrams of the movable guide plate structure

According to the drawings, the structure of the present invention is as follows.

 Generally, in a single image, a short-distance image and a long-distance image are present in a plane (2D) screen. The short-distance image and the long-distance image are displayed on the image display as shown in FIG. 1 (a) (10) and a long-distance image (12) to the remote cameras (9a, 9b).

 For example, a scene in which a singer sings on the stage, for example, a scene in which a singer, who is a close-range video, sings, is a near-distant image 10 located at a close distance with respect to the perspective, and a stage scene is a distant- (12).

 The distance image 10 and the long distance image 12 must have a separation distance B in the space and be synthesized at the separation distance B to form a perspective.

  7, the position of the near-vision image 10 and the position of the far-vision image 12 are the same as those of the observer (see FIGS. 2, 4C, 5A, 6B, 6C, The ratio of the image separation distance B of the long distance image 12 to the viewing position A of the near vision image 10 is A: B = 1: 1.1 times or more and 10 times or less as shown in (c) of FIG. do. In other words, if the spacing ratio of the image separation distance B is less than 1.1 times, a sense of distance separation is lost and a perspective of the present invention can not be obtained. If the distance is 10 times or more, the distance image 12 is too far away, Loses.

 Therefore, the periphery image 10 is processed to have a dark background 10a and the distant image 12 is transmitted to the dark background 10a as shown in FIG. 4 (a).

 The reason why the dark background 10a is formed is that the remote image 12 is blocked when there is another image around the near image 10 or when there is a high image.

 As shown in FIG. 1 (b), a video device such as a transmissive LCD provides an image based on the thin film thickness of an image pixel in a plane of a vertical thin film.

Therefore, as shown in FIG. 2, in order to generate the spatial realism, the present invention is configured such that the distant image 12 is spaced apart from the near vision image 10 by a distance B at which the user can feel the near vicinity.

 Also, a translucent light beam 3 having a transparent structure in which a part of the near vision image 10 is transmitted and a part of which is reflected, and a part of the far vision image 12 is transmitted and part of which is reflected, ) And the long-distance image 12 have the same visual effect as if they were synthesized in space.

  That is, the near-field image 10 transmitted from the back side and the far-field image 12 reflected from the lower side have spatial feeling by the separation distance B in the spatial area of the square of the translucent light beam 3, So that the viewer can see the vertical distance B and the horizontal distance B, respectively.

   More specifically, as shown in FIG. 2, the near vision image 10, which is linearly transmitted or reflected by the semi-transparent mirror 3, is transmitted straight or reflected at a translucent mirror 3 provided at a 45-degree square. When the rectangle is hypothetically formed, the horizontal distance of the horizontal base line, that is, the rectangular space z, is formed, so that a sense of spatial reality such as a prism action is generated.

  That is, the remote screen 12, in which the square of the translucent light beam 3 becomes a hypotenuse of the triangular structure and is reflected in a horizontal form at the position of the base of the triangular structure, Reflection.

  Therefore, the long-distance image 12 and the short-distance image 10 are mutually combined at the position of the translucent light 3 while maintaining the mutual spacing distance B. [

  This translucent light (3, 3a) structure is a transparent reflective material such as titanium oxide (Ti 0 ²), silicon oxide (Si 0 ²), magnesium oxide (MgO), silicon , The entire shape is transparent and has reflection and transmission action.

   Therefore, since the mirror itself is not visible but only the image is displayed, it provides the same spatial feeling as if the image is floating in the air.

 The translucent lens 3 adjusts the reflectance and transmittance by adjusting the thickness of the transparent reflective material.

 The reflectance and transmittance are inversely proportional. That is, when the reflectance is 80%, the transmittance becomes 20%.

  Reflectance: The transmittance is set to 5: 5 and is adjusted between 8: 2 and 2: 8 depending on the application.

For example, when the near-field image 10 needs to be brighter than the far-field image 12, the near-field image 10 is 1.5 times brighter than the far-field image 12 when the transmittance: reflectance is 6: 4.

  Another method of forming the separation distance B is to place the near image 10 on the upper side and the far image 12 on the lower side as shown in Figs. 3 (a) and 3 (b) The first reflector 5 is formed in a square shape and the translucent mirror 3 is formed in a square shape at the front end of the near vision image 10 while the first reflector 5 and the translucent mirror 3 are constituted by a parallel square to be.

  The long distance image 12 is vertically upwardly reflected by the first reflector 5 and then horizontally perpendicularly reflected from the reflection surface of the translucent light 3. The short distance image 10 is transmitted through the translucent light 3, 12) and one image.

    In this case, the position of the long distance image 12 is a distance of 1b + a, and the short distance image 10 becomes a. That is, as shown in FIG. 2 (b), the distance image 12 is formed in the position space spaced apart by 1 b from the near image 10 in the rectangular space z of the translucent lens 3, so that a spatial perspective is formed .

    3 (b), when the image is divided into the near image 10, the intermediate near image 11, and the far image 12, for example, the first reflector 5 is disposed at the front end of the long distance image 12, And a semi-transparent mirror 3 is formed in parallel with the intermediate near-vision image 11 and the near-end image 10, respectively.

 The long distance image 12 is upwardly reflected at a right angle at the first reflector 5 and transmitted through the first translucent light 3a and then perpendicularly reflected at the translucent light 3. The intermediate near- The intermediate near-field image 11 is vertically upwardly reflected and the semi-transparent image 3 is reflected at right angles, and the near-field image 11 is perpendicularly reflected at the semi-transparent mirror 3 again. do.

In this embodiment of the present invention, all of the remaining images except the first reflector (5) constituting the far end of the long distance image (12) are made of translucent light (3, 3a) It is necessary to form the periphery as a dark background 10a to be synthesized into a single image formed by the sense of space reality.

 That is, the position of the long distance image 12 becomes 1b + 2b + a, the position of the intermediate short distance image 11 becomes a + 2b, and the position of the near distance image 10 becomes a.

That is, since each of the images spaced apart from each other by the separation distance B is synthesized in the space formed by the square of the translucent mirror 3, the sense of spatial reality can be felt.

  The configurations of the image displays 9a, 9b, and 9 applied to the present invention are not limited to LCDs, LEDs, QLEDs, micro LEDs, flat displays, curved displays, projectors and screens, Any other known image display such as transparent LCD, tablet image display and the like can be applied.

    The present invention is characterized in that a near image 10 and a far image 12 are displayed on two image displays 9a and 9b as shown in Figs. 4, 5, 6, 7, 10 (b) And generates a 16: 9 image.

However, the aspect ratio in the present invention is not limited to 16: 9. 4: 3, 18: 9 16:10, 2.35: 1.

    8, 9, and 10 (a), the screen of one image display 9 is divided into two to generate a near-field image 10 and a long-distance image 12, respectively, The picture is provided with a picture.

However, the aspect ratio is not limited to 8: 9. 16: 4.5, 4: 1.5, 2: 3 and so on.

 The present invention as described above is characterized in that all the embodiments of the present invention described with reference to the drawings have the above-described operational effects.

This will be described in more detail with reference to the drawings.

    A first image display 9a is provided at the rear end of the image box 200 and a second image display 9b is provided at a right angle with respect to the first image display 9a as shown in FIG. The image display 9b is provided at a position spaced apart by the image separation distance B. [

   4 (a) and 10 (b) are input to the first image display 9a and the second image display 9a, respectively, as shown in FIG. 4 (b). As shown in Fig. 4 (a), the periphery of the image of the near vision image 9a is treated as a dark background 10a.

  The first reflector 3 is provided at a position spaced apart from the front face of the first image display 9a by a distance B as shown in FIG. 4 (c), and a second observing aperture 2a is provided on the front face thereof And a first observation port 2 at a position perpendicular to the second observation port 2a, that is, in the front direction of the first image display 9a.

That is, since the first observation port 2 is configured in a leftward direction and the second observation port 2a is configured in a forward direction, that is, a leftward and a frontward bi-directional right angle structure in a forward direction,

 The structure of the present invention is such that a part of the light amount of the near-

The light is directly transmitted through the translucent lens 3 to be displayed on the second observation port 2a and the light amount of the remaining short-range image 10 is reflected at right angles at the translucent mirror 3 to become a leftward, rightward, And is exposed to the first observation port (2).

 At this time, in the translucent state, the first video display 9a,

Since the left and right images of the display 9b do not coincide with each other, an image of one of the first image display 9a or the second image display 9b is constructed by reversing the left and right direction from left and right to right and left .

A part of the far-end image 12 of the second image display 9b is right-angle-reflected at the translucent mirror 3 and the right and left images are inverted into the images of the left and right directions

And the light amount of the remaining long distance image 12 is expressed by the first observation port 2 after passing straight through the semi-translucency mirror 3.

The image of the first image display 9a is also transmitted and reflected at the translucent mirror 3 with the same logic.

Therefore, the combined image of the near-field image 10 and the long-distance image 12 through the first and second observation ports 2 and 2a formed on the left and right sides of the front surface, do.

 Such a structure may form only one observation port of the first and second observation ports 2 and 2a as necessary.

5 (a) shows the structure of FIG. 4 in which the second and first reflectors 5a

The first observation port 2 and the second observation port 2a are provided at the end of the first image display 9a and at the same angle as the translucency light 3, And the left and right parallel structures.

 That is, some light amount of the long distance image 12 is transmitted straight through the translucent mirror 3

Is reflected by the second reflector (5a) at right angles and is exposed to the first observation port (2).

The remaining light amount of the long distance image 12 is reflected at a right angle by the translucent light 3

And is exposed to the second observation port 2a.

Some light amount of the near vision image 10 is transmitted straight through the translucent mirror 3

Is reflected by the second reflector (5a) at right angles and is exposed to the first observation port (2).

 The remaining amount of light in the near-field image 10 is reflected by the second observation port 2a after being orthogonally reflected by the translucent light 3. [

 The operation, construction, and working principle are the same logic as in FIG. 4 (c), but the other one can view two images as two multi-images.

6 (a) and 6 (b) show the structure of the second reflector 5a in the structure of FIG. 5 (a)

The opposite direction, that is, the front end of the semi-transparent mirror 3 and the inner angle are perpendicular to each other,

Thus, the viewing direction of the first observation port 2 and the second observation port 2a can be viewed in the opposite direction, that is, both forward and backward.

 The operation, construction, and working principle are shown in Fig. 5 (a).

 Such a configuration has an effect that one image can be viewed both before and after.

The structure of FIG. 6 (c) is configured such that only the reflection direction of the structure of the second reflector 5a in the structure of FIGS. 6 (a) and 6 (b)

 Fig. 7 shows the same principle as the structure (c) of Fig. 4

 It is possible to configure either the first image display 9a or the second image display 9b or the structure of both the first image display 9a and the second image display 9b as the projector 25 and the screen 25a Feature.

   The structure of the projector 25 and the screen 25a is advantageous in that the image is made large in size, and the size is easily made by lightening the weight.

 Also, in the present invention as described above, the near-field image 10 is very bright compared to the far-field image 12, so that the effect of the spatial depth effect is increased.

At least the brightness of the near vision image 10 should be at least two times as bright as the brightness of the long distance image 12, and the brightness of the near vision image 10 is ten times bright.

 Therefore, when the image projected on the screen 25a is taken small, it is advantageous to provide a bright image compared to the conventional image display. In case of adopting a high luminance screen, for example, a 20-gain high reflection screen, Bright images can be presented.

Such a configuration can easily implement a large screen on a screen, can form a high-brightness image with high brightness compared to a general image display, and can be applied to all embodiments of the present invention.

 In the present invention, the left and right directions of one of the images of the first and second image displays 9a and 9b should be changed to the right and left directions.

4 (c), the near vision image 10 is partially reflected by the semi-transparent mirror 3 and reflected by the first observation mirror 2, and a part of the long distance image 12 is reflected In the translucent lens 3, the near vision image 10 is reflected at a right angle while passing straight through the first observation port 2, and the left and right image directions are changed to the right and left directions.

A part of the near vision image 10 is transmitted straight through the translucency mirror 3 and the far vision image 12 is reflected at a right angle from the translucency mirror 3 to the second observation mirror 2a. ) The left and right direction of the image changes to the right and left directions.

Therefore, for the above reasons, two image displays such as the first image display 9a or the second image display 9b, such as FIG. 4, FIG. 5, FIG. 6, FIG. 7, In the case of the embodiment of the present invention, one of the video directions should be reversed from left, right to right and left.

 As shown in FIGS. 8A, 8B and 8C, the present invention divides the center of an image of one image display 9 into left and right halves to display the near and far distances 10 and 12 A first mirror 5 is provided on the front face of the long distance image 12 and a translucent mirror 3 is provided on the front face of the near vision image 10 while the first mirror 5 and the translucent mirror 3 are parallel And the first and second observation ports (2, 2a) are all selected as needed, or one of them is selected.

The present invention is characterized in that a part of the light amount of the near vision image 10 displayed on one side of the image display 9 is transmitted straight through the translucency mirror 3 to be exposed to the second observation aperture 2a, The amount of light is perpendicularly reflected by the semitransparent mirror 3, reflected by the second mirror 5a again at right angles, and exposed to the first observation glass 2.

 The distance image 12 displayed on the other side of the image display 9

A part of the light is reflected by the first reflector 5 at right angles and transmitted through the translucent mirror 3 in a straight line and reflected by the second reflector 5a at right angles to the first observation port 2, Is reflected by the second observation aperture 2a by a right angle reflection at the translucent mirror 3. [

 At this time, the long distance image 12 and the short distance image 10 can be observed with a multi effect because the left and right directions are coincident with each other even if the left and right are not reversed.

In this process, the long distance image 12 is separated by the reflection distance of the first reflector 5, that is, B, so that a sense of space reality is generated.

9 is a structure in which only the reflection direction of the second reflector 5a in the configuration of FIG. 8 is reversed and can be viewed both before and after.

 That is, the internal angle 3a is perpendicular to the end of the translucent light 3, and the first observation port 2 is formed at the front end thereof.

 9 is displayed on one side of the image display 9

A part of the light amount of the near vision image 10 is transmitted straight through the translucent mirror 3

 And a part of the light of the remaining short distance image 10 is reflected at a right angle at the semi-transparent mirror 3 and then reflected at a right angle at the second first mirror 2a again in the backward direction, (2).

 A part of the light amount of the long distance image 12 displayed on the other side of the image display 9 is reflected by the first reflector 5 at right angles and transmitted straight through the translucent mirror 3 and then reflected by the second reflector 5a in the backward direction The light is reflected at a right angle to the first observation port 2

A part of the light amount of the remaining long-distance image 12 is reflected by the first reflector 5 at right angles, reflected by the translucent mirror 3, and exposed to the second observation aperture 2a.

 At this time, the long distance image 12 and the short distance image 10 can observe spatial stereoscopic images whose left and right directions coincide without reversing the left and right images.

In such a process, the long distance image 12 is spaced apart from the reflection distance of the first reflector 5, that is, B, so that a spatial stereoscopic effect is generated.

10 (a), the image display 9 is constructed in a vertical shape at the rear end inside the image box 200, and the image is divided into two parts, that is, the upper part and the lower part, (10), and the first mirror (5) is provided on the front surface of the long distance image (12)

  The semi-transparent mirror 3 is arranged in parallel with the first reflector 5 in the same rectangular direction on the front side of the upper near-

 And a black matte surface 5b is provided on the upper surface of the translucent lens 3. [

In this configuration, the near vision image 10 displayed on the upper side of the image display 9 is transmitted through the translucent mirror 3 to the viewer 22

The long distance image 12 displayed on the lower side of the image display 9 is vertically reflected upward at the first reflector 5 and reflected at right angles in the translucent mirror 3 to overlap with the near vision image 10, Lt; / RTI >

At this time, the reflection length of the remote image 12 is a + b + c, and the transmission length of the near vision image 10 is a + c. That is, the position of the long distance image 12 is a distance between the long distance image 12 and the near distance image 10 separated by a distance of B through the dark background 10a around the near image 10, .

In addition, the black matte surface 5b provided on the top surface has a translucency of 3

A black shadow effect is applied to the surface of the local image 10 by a right angle reflection and a straight shadow is transmitted to the long distance image 12 through translucent light and reflected by the first reflector 5 at right angles to provide a black shadow effect, More than 2 times and up to 4 times.

  A first image display 9a is provided at the upper end of the image box 200 and a second image display 9B is provided at the lower end of the image box 200 as shown in FIG. And the remote image 12 is displayed on the second image display 9B.

 A first mirror 5 is disposed at a front end of the long distance image 12 in a rectangular shape so as to vertically reflect the upward direction and a semi-transparent mirror 3 is formed at a front end of the short distance image 10, And a black matte surface 5b is provided on the upper surface of the translucent lens 5. [

In this configuration, the near vision image 10 displayed on the upper side of the image display 9 is transmitted to the viewer 22 through the translucent mirror 3

The long distance image 12 displayed on the lower side of the image display 9 is vertically reflected upward at the first reflector 5 and reflected at right angles in the translucent mirror 3 to overlap with the near vision image 10, Lt; / RTI >

At this time, the reflection length of the long distance image 12 is a + b + c, and the transmission length of the short distance image 10 is a + c. In other words, the position of the long distance image 12 is divided into a long distance image 12 separated by a distance b from the dark background 10a around the short distance image 10 and a short distance image 10, Thereby providing spatial stereoscopic feeling.

In addition, the black matte surface 5b provided on the top surface has a translucency of 3

A black shadow effect is applied to the surface of the short distance image 10, and the light is transmitted straight in the semi-transparent state to be perpendicularly reflected by the first reflector 5 to apply the black shadow effect to the surface of the long distance image 12, It increases by two to four times, respectively.

       The first image display 9a and the second image display 9b are configured as upper and lower ends in the rear stage of the image box 200 as shown in FIG. 10 (c) So that the image of the second image display 9b is reversed to the left and the right direction in the right and left directions, instead of deleting the first reflector structure.

10 (a), 10 (b), and 9c, the black box 5b is provided on the top surface of the image box 200, and the first image display And a second image display 9b on the bottom surface of the image box 200. [

The near image 10 of the first image display 9a transmits the translucent light beam 3 straightly through the viewer 22 in the reflection distance of a + c and the far image 12 of the second image display 9b transmits a + b, and reflects them to the viewer 22 at intervals of c, that is, at intervals of a + b + c.

    That is, since the first image display 9a, which is the near vision image 10, is closer to the second image display 9b than the image of the second image display 9b, it provides a floating spatial sensation.

The present invention is configured such that the black matte surface 5b is formed on one side of the semi-transparent mirror 3 as in the structures (a), (b) and (c) of FIG.

In particular, the display observation device should be clear enough to be installed in a bright place. However, as shown in FIGS. 10A, 10B and 10C, the external light is transmitted through the semi-transparent mirror 3 to be irradiated on the surface of the near-field image 10, thereby hindering the contrast of the near- Reflected from the light (3)

Reflected by the first reflector 5 and irradiated onto the long distance image 12 to reduce the contrast of the long distance image 12 and reduce the sharpness.

 The effect of such a black matte surface 5b has a so-called known black screen effect and is irradiated onto the surface of the near vision 10 in translucent light 3 as shown in Fig. 10 (c) to transmit the translucent light 3 The external light is canceled, and the sharpness is increased by two times or more and four times, respectively.

The black effect transmitted through the translucent lens 3 and reflected from the lower first reflector 5 to the long-distance image 12 compensates for external light emitted from the outside through the reflective surface 5 of the translucent lens 3 It has a sharpness effect of -4 times or more.

 As shown in FIG. 11, the present invention is configured such that a near-field image 10 or a far-field image 12 is separated into a rear screen 11 and a far-field image 12 again, Provided that

It is important.

  Accordingly, the present invention separates the near image 10 and the back image 11 into a long image 12, which is composed of one frame and provides it to one or a plurality of image displays.

That is, the present invention can produce a spatial reality image in multiple layers. The first image display 9a and the second image display 9b are vertically divided into upper and lower two stages. The images are separated into upper and lower images, The first local image 11 and the near local image 10 are input to the image 10a, the upper portion and the upper portion, respectively.

In this configuration, the far-end long-distance image 12 is reflected upward from the first reflector 5 and sequentially transmitted through the first translucent mirror 31a and the second translucent mirror 31b, And refracts and reflects the light onto the viewer 22 from the surface.

The second near-field image 11a is reflected upward from the first translucent mirror 31b on the front face and is refracted and reflected from the surface of the translucent mirror 3 to the viewer 22 position.

The near vision image 10 is transmitted straight through the translucent mirror 3 to the position of the viewer 22.

 Therefore, the viewer 22 can view the long distance image 12 as a + b + b1 + b2 + a and the second short distance image 11a as b1 + b2 + a And the first near-field image 11 is visible at the position b2 + a.

     The structure of the first reflector used in the present invention is composed of a first reflector 5 and a second reflector 5a. However, in the present invention, the thickness of the glass surface of the surface first reflector or the surface on which the reflecting surface is formed is formed as a thin film.

 The second reflector 5a has the function and effect of simultaneously providing the synthesized short-distance image 10 and the long-distance image 12 in the forward, backward, leftward, rightward, .

12 (a) or 12 (b), the image box 200 is configured in the left and right horizontal directions, and several to several hundred exhibition sites 201 ), And the viewer (not shown) is configured to be able to enjoy the video while moving along the copper line.

As shown in Fig. 13, the present invention joins the desk 29 to the structures (a), (b) and (c) of Fig. Such a configuration can provide an augmented reality image effect when used for educational purposes.

 That is, if the contents of the textbook are presented to the long distance image 12 and a part of the images of the long distance image 12 is designated by adjusting with the image controller such as a mouse, the auxiliary image of the long distance image 12 can be provided as the near image 10 .

  For example, if several kinds of dinosaurs appear in the textbook with the remote image (12) and a dinosaur is designated as a mouse among them, the moving image of the dinosaur in the near vision image (10) .

     It can also be used as a cartoon, animation, or image structure that can feel the sense of space reality.

    For example, if a long-distance image 12 is expressed as a background of a cartoon and a near-end image 10 is represented as a subject image, a space-realistic cartoon featuring a sense of spatial reality can be provided.

It can also be applied to game devices. The short-range image 10 may be the main game operation image and the long-distance image 12 may be the background or the stage image.

    However, in any case, the periphery of the near vision image 10 must be treated as a dark background 10a, and the near vision image 10 and the long-distance image 12 should be spaced apart by creating a separation distance B.

      As shown in FIG. 14, the present invention can be configured by combining the structure of the advertisement device 28 capable of placing advertisements on the lower front side of the case 1. In the structure of FIGS. 10A, 10B and 10C, Can be applied.

      The structure of the advertisement board (A) can be constituted by an advertisement frame structure in which the posters are easily opened and closed, and an illuminating plate can be formed on the back of the advertisement board (A), and the film can be mounted on the surface.

  According to the present invention in which the billboard (A) structure is combined, an advertisement effect can be doubled by simultaneously providing a moving image with a space sense and a poster image with a bottom.

     15A and 15B, one image display 9 is divided into three parts in an upward, downward, leftward and rightward direction, or two displays 9a and 9b or three respective displays (10) on the upper screen, a short-distance image (10) on the upper screen, and a short-distance image (10) on the lower screen. , A drawing, and a supplementary advertisement text, and can be installed at a necessary position in combination with the support 29.

   In this case, the first reflector 5 is formed as a square with 45 degrees as the reference and the translucent mirror 3 is provided as the first reflector (not shown) 5) in the same direction.

      In this case, the near-field image 10 is transmitted through the translucent mirror 3, the long-distance image 12 is reflected by the first reflector 5, and is transmitted through the dark background 10a around the near- It matches.

  The viewer 22 can view the long distance image 12 positioned at the image separation distance B spaced by the reflection length of the first reflector 5 and the near vision image 12 such as a car with increased spatial sense due to the action of the square space Z 10) can be observed at the same time, so that the perspective image is generated in the short distance image 10 as the background of the long distance image 12.

   Therefore, in the embodiment of the present invention as described above, the viewer 22 can view various specifications, feature prices, and characters provided in the lower image while viewing the image of the car having the spatial perspective, , The promotion effect is doubled.

   In addition, the embodiment of the present invention can increase the publicity effect by simultaneously providing the logo of the company or the real case such as a smart phone to the outer surface 28 of the surface position of the first reflector 5 at the upper end.

  The present invention can be configured by changing the position of the screen configured in the upper, middle, lower or left and right directions, that is, the positions of the remote image 12, the near vision image 10 and the character auxiliary image 12a.

Even in this case, a dark background 100 should be formed around the near vision 10.

The image display 9 has a configuration in which the near image 10 and the long image 12 are combined into one image and the third image image display for deriving the auxiliary image 12a for displaying the lower character is a touch- Can be configured.

   In this configuration, there are three screens, but one screen may be divided into three screens, or three screens may be composed of three screens or two screens.

 However, in any case, the first reflector 5 is arranged at a 45-degree angle in front of the long-distance image 12, and the semi-transparent mirror 3 is formed at a square angle in the same direction as the first reflector 5, .

   This auxiliary image 12a structure can be applied to all the configurations of the embodiment of the present invention.

   In addition, the present invention can produce a virtual reality image of a long-distance image 12 and a short-distance image 10 at a viewing angle of more than 90 degrees and 360 degrees, rotate a viewing angle with a mouse or the like image control device, or display a gyro sensor, And displays the image in the corresponding direction according to the rotating direction of the image display, so that it can be used as a space separated image for virtual reality.

 Accordingly, the present invention can be applied to a method of generating a single image,

The separated local image 10, the remote image 12,

The near image (10) composed of dark color around the image

The ratio of the distance B between the viewing distance A and the distance image 12 is

 1: minimum 1.1 to maximum 1: 10

 The translucent light (3) is composed of a transparent material, but it is composed of a square to obtain a square space (Z) effect

 (B) distance between the near and far distances in the space, and the various functions of the components,

By creating a spatial sense of space by a natural perspective

The polarizing plate and the polarizing glasses can be viewed with a high-definition image of 4-10 times higher than the conventional one, and the black matte surface 5b provided on one side of the translucent lens 3 can be used as a near- And the effect of casting a shadow on the long-distance image (12), thereby increasing brightness and sharpness by 2-4 times.

 Accordingly, the present invention provides an image with a clear perspective in terms of spatial realism and a high-definition image of 8-40 times higher than that of a conventional polarizing plate.

In addition, this image structure can be viewed both forward and backward bi-directionally left or right bi-directionally, bi-directionally, leftward, right bi-directional, or one-directional multi-view.

Therefore, the present invention can be variously used for various purposes such as an advertisement apparatus, a video apparatus, a game apparatus, a training image apparatus, a display apparatus, and the like.

1. Case 2. 2a. 1st and 2nd observation windows 3. Translucent mirror 3a. cabinet
4. Upper transmission window
5. First reflector 5a. The second reflector 5b.
6. Lower penetration window 7. Fixed frame 8. Fixing device
9. Video Display 9a. First image display 9B. Second image display
9c. Lenticular 91. Display 10. Close-up image 10a.
11. Rear View 12. Remote View 13. Mouse Device
22. Viewers
24. Video Splitter 25. Projector 25a. screen
28. Advertising device 29. Table
27. Left and right rotation means 200. Video box
300. Control device B. Image separation distance Z. Rectangular space

Claims (9)

In a spatial separation imaging apparatus
A single image input to the space division image device is divided into a near image 10 and a far image 12,
The periphery of the near vision image 10 is formed of a darkness background 10a having a high brightness so that the far vision image 12 can be transmitted from the backside of the near vision image 10
First and second image displays 9a and 9b for separately displaying the close range image 10 and the long distance image 12,
The position of the second image display 9b is set such that the position of the second image display 9b is different from that of the first image display 9a so as to generate a sense of reality in the rectangular space z by the perspective image 10 and the long- Forming a distance B
By constructing a translucent mirror 3 having a transparent structure in a rectangular shape on the front surface of the near vision image 10
The functions of the near vision image 10 in which the dark background 10a is formed and the distance image 12 and the spacing distance B and the rectangular space Z and the translucent light beam 3 having a transparent structure are mutually and organically And a spatial spatial sensation due to a sense of perspective is produced by simultaneous action
The black matte surface (5b) transmits or reflects the semi-transparent surface (3) by providing the black matte surface (5b) in one direction of the translucent lens (3) 12) is enhanced by 2-4 times the sharpness by the shadow effect.
The method of claim 1, wherein
One of the first and second image displays 9a and 9b,
Or the structure of the first and second image displays (9a, 9b) is constituted by the projector (25) and the screen (25a)
The spatial separation imaging apparatus according to claim 1, wherein the first and second observation ports (2, 2a) are formed at both ends of the translucent lens (3)
The method according to claim 1, wherein the second reflector (5a) is formed in a rectangular shape so that the internal angle (3a) is perpendicular to both ends of the translucent light (3) A spatial separation imaging apparatus characterized by being capable of observation in both directions
In a spatial separation imaging apparatus
(10) and a remote du image (2), each of which is input to the space division video device
The periphery of the near vision image 10 is formed of a darkness background 10a having a high brightness so that the far vision image 12 can be transmitted from the backside of the near vision image 10
And one image display (9) for dividing the near image (10) and the far image (12) into two parts and displaying
A first reflector 5 is formed in a square shape in front of the long distance image 12 to generate the near distance image 10 and the distance B
(3) of a transparent structure formed by a rectangular space (Z) is formed on the front surface of the near vision image (10)
The distance image 10 on which the dark background 10a is formed and the distance image 12 and the distance B and the translucent light 3 by the square space Z act simultaneously and concurrently, Wherein the spatial separation imaging device
7. The apparatus according to claim 6, characterized in that the first and second observation ports (2, 2a) are formed at both ends of the translucent lens (3)
The method according to claim 6, wherein a second reflector (5a) is formed in a square shape so that the internal angle (3a) is perpendicular to both ends of the translucent light (3), and the second reflector (5a) A spatial separation imaging apparatus characterized by being capable of observation in both directions
The method of claim 6, wherein the black matte surface (5b) is provided in one direction of the translucent lens (3) so that the black matte surface (5b) transmits or reflects the translucent lens (3) 12) is enhanced by 2-4 times the sharpness by the shadow effect.

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