KR102025473B1 - Image system for synthesising in space with separated images - Google Patents

Abstract

According to the present invention, a single image is divided into a near image and a far image on two or one image displays, and a near image is placed in front, a far image is placed at a far distance, and a semi-transparent mirror is provided at the front of the near image. Each of these spaces are separated and synthesized in an isolated state, creating an effect of viewing a realistic image with autostereoscopic effect with perspective by distance separation, right, left, front, front, back, left, right. The present invention relates to a spatially separated image device capable of obtaining a spatially realistic image in one direction of the left and right directions, and to a spatially separated image device capable of viewing 4-10 times high-definition spatial stereoscopic images in both directions without polarized glasses. .

Description

Image system for synthesising in space with separated images}

The present invention relates to a device for separating a single image into a near-field image and a far-field image, and then converting each image position into a space-real image by synthesizing it again in space. The present invention relates to a space-separated imaging device that can sense a three-dimensional reality.

Spatial separation image is a so-called Space Reality effect that separates the image into space units at long distances and near distances to create a spatial stereoscopic sense by perspective, which is different from 3D stereoscopic images.

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

For example, a play on stage, a singer's performance, a game, a sports event with a playground background, and an advertisement video promoting a product include a near-field video with motions such as a singer and an actor, and a long-distance video such as a stage and a background. On the flat screen 2D.

 In addition, a conventional stereoscopic (3D) image is a phenomenon in which the brain causes an illusion due to the difference between the stereoscopic left eye image and the right eye image, respectively. Therefore, it causes dizziness, separates through polarized light, and needs to watch again with polarized glasses, so the brightness is sharply lowered to 1/10 or less, and the image is blurred and easily fatigued.

In addition, the method using the polarizing plate and polarizing glasses is impossible to carry the polarized glasses to a specific, unspecified number one by one, it is impossible to use in the advertising video device targeting the floating people.

 In addition, the conventional semi-transparent mirror has been a visual impediment because the reflective surface of the non-transparent material remains when it is installed in a space as a non-transparent semi-transparent mirror by depositing an opaque material such as aluminum.

 The present invention further improves the brightness and clarity by more than 4 times to 10 times by further improving the US Patent No. 8,279.271 registered by the applicant, and after separating the near and far images in the space without a polarized glasses in the space again in space It has been improved and developed in a new way of matching images.

In addition, some of the holo images composed of the existing inverted pyramid structure are simple images presenting a single image in multiple directions, and there is no near and far perspective.

In addition, since a conventional imaging device such as a transmissive LCD provides an image in a plane of a vertical thin film as shown in FIG. 1B, it is impossible to form a stereoscopic effect due to a so-called cardboard phenomenon.

 In addition, Republic of Korea Application No. 10-1999-0017653 and Republic of Korea Application No. 20-2014-0006899 as described in this invention does not present a spatial realization method that separates the long-distance image and the near-field image and then put them together again.

Overseas Patent Documents 1. US PAT NO. 8,279.271 Patent Documents 1. Republic of Korea Application No. 10-1999-0017653 Patent Document 2. Republic of Korea Application No. 20-2014-0006899

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to propose a method of obtaining a spatial feeling and a high-definition image by a natural perspective using a glasses-free method.

The present invention

   The single image input to the spatial separation imager is separated into a near image and a far image, respectively.

    The periphery of the near image is composed of a dark background of low brightness so that the far image can be transmitted from the near image.

    Comprising a first and a second image display for displaying the near-field image and the far screen separately;

The position of the second video display forms an image separation distance from the first video display.

  It comprises a translucent mirror having a transparent structure in a square on the front of the near image.

   The near image having the dark background, the far image, and the semi-transparent mirror function generating the spatial perspective by the separation distance and the rectangular space simultaneously work together to construct the spatial stereoscopic effect by the perspective.

 In another method, one image display configured to display the near image and the far image by dividing the image into two parts is used.

     In the front of the far image, a first reflector is formed in a square to generate a distance from the near image.

    The translucent mirror for forming a rectangular space on the front of the near image is configured as a square.

Another method is to include one observation port in each configuration method, but having a black matt surface in one direction of the semi-transparent mirror so that the black matt surface transmits or reflects the semi-transparent mirror to shadow the near and far images. Bring in 2-4 times more sharpness.

Another method is configured to increase the brightness of the near image by 20 times by configuring either one of the first and second image displays or both the first and second image displays as a projector and a screen.

Another method is to configure the first and second observation spheres (2, 2a) at both ends of the semi-transparent mirror in each of the above structures so that the image can be viewed at right angles in both directions, or the cabinet is at right angles at one end of the semi-transparent mirror. The second reflector 5a may be configured to be observed in both left and right directions or both front and rear directions according to the rectangular direction of the second reflector 5a.

In addition, the structure of the present invention consists of a vertical image box

 Install multiple video boxes in the direction of the viewer's movement

Use it for installation so that it can be displayed continuously.

In the present invention, a far field image and a near field image separated from one image are spaced apart from each other.

 Spatial three-dimensional effect by perspective is generated by allowing the far-field image located on the back side to penetrate through the dark background around the short-range image.

  In addition, by synthesizing the perspective space effect of the square space (z) effect and the separation distance (B) as shown in FIG.

The first and second viewing ports are formed according to the reflection direction and the transmission direction of the semi-transparent mirror, so that the same image can be simultaneously viewed in the right, left, or both directions, in the right, left, and right directions, or in the left and right directions. Has

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

   Therefore, according to the present invention, a single image is separated into a far image and a near image, and each image is spaced apart according to a near distance and synthesized according to the viewing direction in a rectangular space z of a translucent mirror in both reflection and transmission directions. The function and action that enables viewing are organically interacted, and it is effective to present a spatial stereoscopic image with 4-10 times or more high-definition with no glasses without polarized glasses.

1 (a) is an explanatory diagram for separating a single image into a near image, a dark background, and a far image
Figure 1 (b) is a reference diagram illustrating the transparent LCD image plate
2 is an explanatory diagram of a rectangular space z of the translucent mirror 3 having a rectangular shape.
3 (a) is an explanatory diagram of a two-division image
3B is an explanatory diagram of a three-part image.
4 (a), (b), (c) and (d) are basic explanatory diagrams of the present invention.
5 (a) and 5 (b) are explanatory diagrams of left and right multi-image structure.
6 (a) and 6 (b) are explanatory diagrams of the front and rear interactive viewing structure.
6 (c) is an explanatory diagram of left and right interactive viewing structure
7 is a diagram illustrating the configuration of a projector and a projection screen.
8A, 8B, and 8C illustrate an image display and a left and right multi-image structure
9 is an explanatory diagram of a structure of a video display and a bidirectional viewing structure before and after
(A), (b), (c), and (d) of FIG. 10 are explanatory diagrams of the structure of an exhibition video form.
11 is an explanatory diagram when configuring a multi-multi image having a vertical structure
12 (a) and 12 (b) are explanatory diagrams of the exhibition hall structure.
13 is an explanatory diagram when combined with a desk structure
14 is a diagram illustrating the configuration when combined with an advertisement device;
(A), (b) is explanatory drawing of the structure of a movable guide plate.

Based on the illustrated drawings, the present invention is constructed as follows.

 In general, a single image includes a near image and a far image on a planar (2D) screen, which are displayed on an image display as shown in FIG. 1 (a) or each of the first and second image displays using an image distributor 24. Separately input the short-range image 10 and the long-range image 12 to 9a and 9b.

For example, the scene where the singer sings on the stage, for example, the scene where the singer sings in the near field is a near field image 10 located at a near distance based on a perspective, and the stage scene is a far field image 12 positioned at a far distance. Becomes

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 The near-field image 10 and the far-field image 12 must have a distance B in space and must be synthesized at a distance B to form perspective.

  That is, as shown in FIGS. 2, 4 (c), 5 (a), 6 (b), (c), and 7, the position of the near image 10 and the position of the far image 12 are determined by the observer ( 22) The ratio of the image separation distance B of the far image 12 to the viewing position A of the near image 10 as shown in FIG. 4C is based on A: B = 1: 1.1 times or more and less than 10 times. do. That is, when the interval ratio of the image separation distance (B) is 1.1 times or less, the distance separation is lost and the perspective of the object of the present invention cannot be obtained, and when it is 10 times or more, the position of the far image 12 is unnaturally small. Lose.

 Therefore, as shown in FIG. 4A, the near image 10 is formed as a dark background 10a, and the far image 12 is transmitted through the dark background 10a to be synthesized.

 The reason for forming the dark background 10a is that when the other image or the high brightness image exists near the near image 10, the far image 12 on the back side is blocked.

 As shown in (b) of FIG. 1, an imaging device such as a transmissive LCD provides an image by the thickness of an image pixel in a plane of a vertical thin film, and thus presents only an image such as a card board, and thus no spatial realism is formed.

Therefore, in order to generate such a spatial stereoscopic sense, the present invention is configured to separate the position of the far image 12 from the near image 10 by a distance B that can feel a far distance as shown in FIG. 2.

 In addition, the near image 10 includes a semi-transparent mirror 3 having a transparent structure having a transparent structure in which part of the near image 10 is transmitted and part is reflected, and a part of the far image 12 is transmitted and part is reflected. ) And the far image 12 are configured to have a video effect as if synthesized in space.

  That is, the near-field image 10 transmitted from the rear side and the far-field image 12 reflected from the bottom of the semi-transparent mirror 3 in a space area are synthesized in one viewing direction while having a sense of space by the separation distance B. Since it is observed while reflecting at a right angle to the viewer as if the separation distance (B) in the vertical direction becomes the effect of the separation distance (B) in the horizontal direction.

   In more detail, as shown in FIG. 2, the near-field image 10 that transmits or reflects straight from the semi-transparent mirror 3 is transmitted or reflected straight from the semi-transparent mirror 3 provided by a 45-degree square. When the square is viewed as the hypotenuse, the horizontal distance of the horizontal base, that is, the square space z is formed, thereby creating a sense of space like a prism.

  That is, the far screen 12 that is reflected in a horizontal form at a position where the square of the semi-transparent mirror 3 becomes the hypotenuse of the triangular structure and the base of the semi-transparent mirror 3 is perpendicular to the rectangular space Z of the inclined angle of the semi-transparent mirror 3. Reflect.

  Therefore, the far image 12 and the near image 10 are synthesized with each other at the position of the translucent mirror 3 while maintaining the mutual separation distance B.

  The semi-transparent diameter (3, 3a) structure is a transparent transparent material such as titanium glass (Ti 0²), silicon oxide (Si 0²), magnesium oxide (MgO), silicon on a transparent material surface such as transparent glass, plastic, film By applying or depositing a transparent reflective material, such as the overall shape is a transparent structure and the reflection and transmission effect.

   Therefore, the mirror itself is not visible, only the image, thus providing a sense of space as if the image is floating in the air.

 The translucent mirror 3 adjusts the reflectance and transmittance by adjusting the thickness of the transparent reflective material to be applied.

 Reflectance and transmittance are inversely proportional. In other words, when the reflectance is 80%, the transmittance is 20%.

  Reflectance: Adjust the transmittance between 8: 2 and 2: 8 according to the application based on 5: 5.

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

  Another method of forming the separation distance B is to place the near image 10 at the top and the far image 12 at the bottom as shown in FIGS. 3A and 3B and in front of the far image 12. The first reflector 5 is formed in a square and the translucent mirror 3 is formed in a square in front of the near image 10, but the first reflector 5 and the translucent mirror 3 are formed in a parallel rectangle. to be.

  The far image 12 reflects upwardly at right angles from the first reflector 5, and then reflects back at right angles horizontally to the reflection surface of the translucent mirror 3, and the near image 10 penetrates the semi-transparent mirror 3 so that the far image ( 12) into a single image.

    In this case, the position of the far image 12 becomes 1b + a and the near image 10 becomes a. That is, in the rectangular space z of the translucent mirror 3, as shown in FIG. 2B, the far image 12 is formed in a position space spaced 1 b apart from the near image 10, thereby creating a spatial perspective. .

    As shown in (b) of FIG. 3, when the image is separated 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 far image 12. The intermediate near-field image 11 and the near-field image 10 in front of the translucent mirror 3 is configured in a parallel angle, respectively.

 The far-field image 12 reflects upwardly at a right angle from the first reflector 5, passes through the first semi-transparent mirror 3a, and then reflects at right angles to the semi-transparent mirror 3, and the intermediate near image 11 is a first semi-transparent mirror. In part (3a), a part of the light is transmitted, a part is reflected, and the near-field image 11 reflects upwardly at right angles and then is reflected at right angles in the translucent mirror 3, and the near-field image 11 reflects at right angles in the translucent mirror 3 again. do.

In the present invention as described above, except for the first reflecting mirror 5 configured at the front end of the far image 12 at the lower end, the rest are all composed of translucent mirrors 3 and 3a, but the remaining images except for the far image 12 are The periphery must be formed with a dark background 10a to be synthesized into a single image that creates a sense of space.

 That is, based on the position of the translucent mirror 3, the position of the far image 12 is 1b + 2b + a, the position of the intermediate near field image 11 is a + 2b, and the position of the near image 10 is becomes a.

That is, since each image of each spatial position is spaced differently by the separation distance (B) is synthesized in the space formed by the square of the semi-transparent mirror (3) it is possible to feel the spatial realism.

  The configuration of the image display (9a, 9b, 9) applied to the present invention is LCD, LED, QLED, micro LED, flat panel display, curved display, projector and screen, autostereoscopic display attached to the surface image of the lenticular, All other known image displays may be applied, such as a transparent LCD, a tablet image display, and the like.

    According to the present invention, as shown in FIGS. 4, 5, 6, 7, and 10 (b) and (c), the near image 10 and the far image 12 are respectively displayed on two image displays 9a and 9b. Input is generated and the screen is provided with a 16: 9 picture.

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

    In the present invention, as shown in FIGS. 8, 9, and 10 (a), the screen of one image display 9 is divided into two to input the near image 10 and the far image 12, respectively. The screen is provided as an image.

However, the aspect ratio is not limited to 8: 9. It is applied to various aspect ratios such as 16: 4.5, 4: 1.5, and 2: 3.

 Such the present invention is characterized in that all embodiments of the present invention described by the following drawings have the above-described effects.

This will be described in more detail based on the drawings.

    As shown in FIG. 4C, the first image display 9a is provided at the rear end of the image box 200 and the second image display 9b has a right angle structure with respect to the reference of the first image display 9a. The image display 9b is provided at positions spaced apart by the image separation distance B.

   The near image 10 is input to the first image display 9a as illustrated in FIG. 4A, and the far field image 9b is input to the second image display 9a as illustrated in FIG. 4B. As shown in (a) of FIG. 4, the peripheral area of the near-field image 9a is treated as a dark background 10a.

  As shown in FIG. 4C, the front surface of the first image display 9a is provided with a first reflector 3 in a square at a position spaced apart by the separation distance B, and a second observation port 2a is provided on the front surface thereof. The first observation port 2 is provided at a position perpendicular to the second observation hole 2a, that is, at the front direction of the first image display 9a.

In other words, since the first observation port 2 is configured in the left direction and the second observation port 2a is configured in the front direction, that is, the front direction, that is, the left and the front bidirectional right angle structures, the first observation port 2 can be observed in the left and the front directions.

 The structure of the present invention is that the partial light amount of the near field image 10

After passing straight through the semi-transparent mirror (3) is expressed in the second observation port (2a), the light amount of the remaining near-field image 10 is reflected at right angles from the semi-transparent mirror (3) is inverted to the left, right, right, left image The first observation port 2 is displayed.

 In this case, the second image is compared with the first image display 9a in the translucent mirror.

Since the image of the display 9b does not coincide with the left and right, the image of one of the first image display 9a or the second image display 9b is configured by inverting the left and right directions from left, right to right and left directions. .

A part of the far image 12 of the second image display 9b is inverted into an image of right, left and left and right directions while reflecting at right angles in the translucent mirror 3.

The light amount of the remaining long-distance image 12 is emitted to the second observation port 2a, and the semi-transparent mirror 3 passes through the first observation hole 2 after straight transmission.

The image of the first image display 9a is transmitted and reflected by the translucent mirror 3 in the same logic.

Therefore, through the first and second observation ports 2 and 2a formed at right angles to the front surface, that is, the left and right images, the near and right images can be simultaneously viewed as the same image on the left and right sides. do.

 This structure may form only one observation port of the 1st, 2nd observation ports 2 and 2a as needed.

FIG. 5A shows the second and first reflecting mirrors 5a in the structure of FIG. 4.

It is further provided at the end of the first image display (9a) and configured in parallel at the same angle as the translucent mirror (3), as shown in Fig. 5 (b) the first observation hole 2 and the second observation hole (2a) Is composed of left and right parallel structure.

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

The second reflector 5a reflects at right angles to the first observation port 2.

The remaining amount of light in the far image 12 is reflected at right angles from the translucent mirror 3

It is expressed by the 2nd observation port 2a.

Some light quantity in the near field image 10 is transmitted through the translucent mirror 3 straight

The second reflector 5a reflects at right angles to the first observation port 2.

 The remaining amount of light in the near field image 10 is reflected by the translucent mirror 3 at right angles and then displayed to the second observation port 2a.

 The operation, configuration and principle of operation is the same as the logic of FIG. 4 (c) but the other one can watch one image as two multi images.

6A and 6B illustrate a second reflector 5a in the structure of FIG.

The opposite direction, that is, the front end and the inner angle of the translucent mirror (3) is configured to be perpendicular,

Accordingly, the viewing direction of the first observation port 2 and the second observation port 2a is configured to be viewed in opposite directions in both directions before and after each other.

 Operation, configuration and principle of operation are the same as in FIG.

 Such a configuration has the effect of viewing a single video in both directions.

In FIG. 6C, only the reflection direction of the second reflector 5a in the structures of FIGS. 6A and 6B is configured in the opposite direction so that the left and right directions can be observed in both directions.

 7 is the same principle as the structure (c) of FIG.

 Any one of the first image display 9a and the second image display 9b or the structure of both the first image display 9a and the second image display 9b includes the projector 25 and the screen 25a. It is characteristic.

   The structure of the projector 25 and the screen 25a is advantageous, such as lightening the weight and making it easy to enlarge the size of the image.

 In addition, in the present invention as described above, the near-field image 10 is very bright compared to the far-field image 12 to increase the spatial stereoscopic effect.

At least the brightness of the near image 10 should be at least two times brighter than the distance of the far image 12, and the brightness will be very good when the brightness is about 10 times.

 Therefore, when the projected image on the screen 25a is taken small, it has the advantage of providing a bright image compared to the existing image display, and when a high brightness screen is adopted, for example, a 20-gain high reflection screen, 20 times higher than that of a normal screen image. You can present a bright image.

Such a configuration can easily implement a large screen on the screen, and can configure a high brightness image having a higher brightness than a general image display, and can be applied to all embodiments of the present invention.

 According to the present invention, the left and right directions of one of the first and second image display images 9a and 9b are to be changed to the right and left directions.

For this reason, referring to (c) of FIG. 4 as an example, the near image 10 partially reflects at right angles from the translucent mirror 3 to the first observation hole 2 and a part of the far image 12 In the translucent mirror 3, the near field image 10 reflects at right angles to the first observation port 2 so as to pass straight, and the left and right image directions are changed to the right and left directions.

In addition, a part of the near field image 10 passes straight through the semi-transparent mirror 3 and the far-field image 12 reflects at right angles from the semi-transparent mirror 3 to the second observation hole 2a. The left and right directions of the image are changed to the right and left directions.

Therefore, for the same reason as above, two image displays, such as the first image display 9a or the second image display 9b, such as FIGS. 4, 5, 6, 7, and 10 (b) and (c) are used. In the case of the embodiment of the present invention, one of the image directions should be configured by reversing the left, right, right, and left directions.

 As shown in (a), (B), and (c) of FIG. 8, the present invention divides the image center of one image display 9 left and right to display the near image 10 and the far image 12. A first reflector 5 is provided on the front surface of the far image 12, and a translucent mirror 3 is provided on the front of the near image 10, respectively, but the first reflector 5 and the translucent mirror 3 are parallel to each other in the same square direction. The first and second observation ports 2 and 2a are selected in front of each other or formed by selecting one of them.

According to the present invention, the amount of light of the near field image 10 displayed on one side of the image display 9 is transmitted through the translucent mirror 3 to the second observation port 2a, and the part of the remaining near field image 10 is partially transmitted. The amount of light is reflected by the translucent mirror 3 at right angles and then reflected by the second reflector 5a at right angles to the first observation port 2.

 Of the far image 12 displayed on the other side of the image display 9.

The amount of light is reflected by the first reflector 5 at right angles, then passes through the semi-transparent mirror 3, and then is reflected by the second reflector 5a at right angles to the first observation port 2 and the remaining long distance image 12. A part of light amount is reflected by the translucent mirror 3 at right angles to the second observation port 2a.

 In this case, the far image 12 and the near image 10 may be observed in a multi-effect because the left and right directions coincide without inverting the left and right sides.

In this process, the far image 12 is spaced apart by the reflection distance of the first reflector 5, that is, B, thereby causing a sense of spatial reality.

In FIG. 9, only the reflection direction of the second reflecting mirror 5a is reversed in the configuration of FIG. 8 so that the viewer can watch in both directions.

 That is, it is different from FIG. 8 in that the inside angle 3a is provided at the end of the translucent mirror 3 so that the inside angle 3a may be perpendicular, and the first observation port 2 is formed at the front end thereof.

 The configuration of FIG. 9 is displayed on one side of the image display 9.

Part of the light of the near image 10 is transmitted through the translucent mirror 3 straight

 The light emitted from the second observation port 2a and the partial light amount of the remaining short-range image 10 are reflected at right angles in the semi-transparent mirror 3, and then reflected at right angles in the rearward direction again from the second first reflector 2a. It is expressed as (2).

 Some of the light amount of the far-field image 12 displayed on the other side of the image display 9 is reflected at right angles from the first reflector 5, passes straight through the semi-transparent mirror 3, and then backwards from the second reflector 5a. Reflected at right angles to the first observation port (2)

Some of the light amount of the remaining far image 12 is reflected by the first reflecting mirror 5 at right angles, reflected by the semi-transparent mirror 3, and displayed to the second viewing port 2a.

 In this case, the far image 12 and the near image 10 may observe a spatial stereoscopic image in which left and right directions coincide without inverting left and right.

In this process, the far image 12 is spaced by the reflection distance of the first reflector 5, that is, B, thereby creating a spatial three-dimensional effect.

As shown in (a) of FIG. 10, the image display 9 is vertically formed at the rear end of the image box 200, and the image is divided into two parts, the upper part and the lower part. (10) to the front and the far image 12 is provided with a square to reflect the first reflector (5) upward

  The translucent mirror 3 is parallel to the first near mirror 5 in the same direction as the first reflecting mirror 5.

 A black matt surface 5b is provided on the top surface of the translucent mirror 3.

In this configuration, the near field image 10 displayed on the top of the image display 9 passes through the translucent mirror 3 and is provided to the viewer 22.

The far image 12 displayed at the bottom of the image display 9 is reflected upward from the first reflecting mirror 5 at right angles and then reflected at right angles from the translucent mirror 3 to overlap the near image 10 with the viewer 22. Is provided to.

In this case, the reflection length of the far image 12 is a + b + c, and the transmission length of the near image 10 is a + c. That is, the position of the far image 12 is separated from the far image 12 and the near image 10 at a distance as far as the B distance through the dark background 10a around the near image 10. Will be provided.

In addition, the black matt surface 5b provided on the upper surface is the translucent mirror 3

By reflecting at right angles, a black shadow effect is applied to the surface of the near image 10, and the far image 12 is transmitted through a semi-transparent mirror, and is reflected at a right angle with the first reflector 5 to apply a black shadow effect, respectively. Increases 2 times or more to 4 times.

  As shown in FIG. 10B, the first image display 9a is provided at the upper end of the image box 200, and the second image display 9B is disposed at the lower end of the image box 200, and the near image 10 is provided at the first image display 9a. In the second image display 9B, the far image 12 is displayed.

 The front end of the far image 12 is composed of a square to reflect the first reflector 5 upward at right angles, and the front end of the near image 10 is a semi-transparent mirror 3 having a square in the same direction as the lower first reflector 5. In parallel, the upper surface of the translucent mirror 5 is provided with a black matt surface 5b.

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

The far image 12 displayed at the bottom of the image display 9 is reflected upward from the first reflecting mirror 5 at right angles and then reflected at right angles from the translucent mirror 3 to overlap the near image 10 with the viewer 22. Is provided to.

In this case, the reflection length of the far image 12 is a + b + c, and the transmission length of the near image 10 is a + c. That is, the position of the far image 12 is separated from the far image 12 and the near image 10, which are far apart and separated by a distance b, through the dark background 10a around the near image 10. It provides a sense of space.

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       As shown in (c) of FIG. 10, the first image display 9a and the second image display 9b are configured in the upper and lower stages at the rear end of the image box 200, but the second image display 9B is a + b. Instead of the first reflector structure and delete the first reflector structure, the image of the second image display 9b is configured by inverting the left and right directions in the right and left directions.

10 (a), 10 (b) and 9c have the black matte surface 5b on the upper surface of the image box 200 and display the first image in the vertical direction at the rear end of the image box 200 in front of the image box 200. 9a, the second image display 9b is provided on the bottom surface of the image box 200.

The near field image 10 of the first image display 9a passes through the translucent mirror 3 to the viewer 22 at a reflection distance of a + c, and the far field image 12 of the second image display 9b is a at the interval of + b and at the translucent mirror 3 and at the interval of c, i.e. at the interval of a + b + c, to the viewer 22.

    That is, the first image display 9a image, which is the near image 10, appears to be as close as b distances as compared to the second image display 9b image, thereby providing a floating spatial stereoscopic feeling.

In the present invention, the black matt surface 5b is formed on one surface of the semi-transparent mirror 3 as in the structures (a), (b) and (c) of FIG.

In particular, the exhibition observing device should have a clear image as installed in a bright place. However, as shown in (a), (b), and (c) of FIG. 10, external external light penetrates the translucent mirror 3 and is irradiated onto the surface of the near image 10, thereby inhibiting contrast of the near image 10 and semitransparent. Reflected from the mirror (3)

Reflected by the first reflector 5 and irradiated to the far image 12, the contrast of the far image 12 is inhibited to reduce the sharpness.

 The effect of the black matt surface 5b has a so-called well-known black screen effect and is irradiated to the near image 10 surface from the translucent mirror 3 as shown in FIG. 10C to transmit the translucent mirror 3. It offsets the external light and improves the sharpness by 2 to 4 times.

In addition, the black effect transmitted through the translucent mirror 3 and reflected from the lower first reflector 5 to the far image 12 is canceled by canceling external light irradiated through the reflective surface 5 of the translucent mirror 3 from the outside. -4 times more sharpness effect.

 As shown in FIG. 11, the present invention separates the short-range image 10 or the long-range image 12 into the rear screen 11 and the long-range image 12, but separates the separated images into one frame simultaneously. Being offered

It is important.

  Accordingly, in the present invention, the near image 10 and the rear screen 11 are separated into the far image 12, respectively, but are configured as one frame and provided to one or more image displays.

That is, the present invention can create a spatial reality image in multiple layers. The first image display 9a and the second image display 9b are composed of two stages, vertically and vertically, respectively, and the image is divided up and down, respectively. An image 10a, a second near image 11 at the top thereof, and a near image 10 at the top thereof are respectively input.

In this configuration, the far end image of the far end 12 is upwardly reflected by the first reflector 5 to sequentially pass through the first semi-transparent mirror 31a and the second semi-transparent mirror 31b, and then the translucent mirror 3 of the upper end. Reflects refraction to the viewer 22 from the surface.

The second near image 11a is upwardly reflected by the first translucent mirror 31b on the front surface and refracted by the viewer 22 position on the surface of the translucent mirror 3.

The near field image 10 passes straight through the translucent mirror 3 and passes through the viewer 22.

 Accordingly, the viewer 22 may view the far image 12 relative to the position of the near image 10 as a + b + b1 + b2 + a and the second near image 11a as b1 + b2 + a as shown in FIG. 11. And the first near field image 11 is visible at the position b2 + a.

     The structure of the 1st reflector used for this invention consists of the 1st reflector 5 and the 2nd reflector 5a. However, in the present invention, the thickness of the surface first reflecting mirror or the surface of the glass surface on which the reflecting surface is formed is a thin film.

 In addition, the second reflector 5a provides a function and effect of simultaneously providing the synthesized near image 10 and the far image 12 in the forward, backward, left, right, or left and right directions according to the reflection direction. It is characteristic to have.

Such an embodiment of the present invention configures the image box 200 in the left and right horizontal directions as shown in FIG. 12 (a) or FIG. 12 (b), and from several to hundreds of exhibition places 201 as shown in FIG. ), And visitors (not shown) can be configured to enjoy the video while moving along the line.

As shown in FIG. 13, the present invention couples the desk 29 to the structures (a), (b) and (c) of FIG. 10. Such a configuration can obtain augmented reality video effects when used for educational purposes.

 That is, a textbook content may be presented to the far image 12, and if a part of the image of the far image 12 is designated by controlling with an image controller such as a mouse, the auxiliary image of the corresponding image may be provided as the near image 10. .

  For example, when various dinosaurs appear in textbook content as a long distance image (12), and one of the dinosaurs is designated as a mouse, the moving image of the dinosaur is shown in the near field image (10) to enhance the educational effect. Can be.

     In addition, it can be used as a cartoon, animation, or video structure to feel the reality of space.

    For example, if the far-field image 12 is expressed as a background of a cartoon and the near-field image 10 is expressed as a subject picture, it is possible to provide a space-realistic cartoon that feels a sense of space.

It can also be applied to game devices. The near field image 10 may be a main game motion image, and the far field image 12 may be a background or stage image.

    In any case, however, the periphery of the near image 10 should be treated as a dark background 10a, and the near image 10 and the far image 12 should form a separation distance B to form a separation space.

      As shown in FIG. 14, the present invention may be configured by combining a structure of an advertisement device 28 that can place advertisements on the lower surface of the case 1, and the structures (a), (b), and (c) of FIG. Can be applied.

      Such a billboard (A) structure can be configured as an advertising frame structure of the opening and closing structure that is easy to insert the poster, it is possible to configure the lighting plate on the back of the billboard (A) and to mount the film on the surface.

  The present invention combined with such a billboard (A) structure can double the effect of advertising by simultaneously providing a video of the reality of the space at the top and a video such as a poster at the bottom.

     As described above, according to the present invention, as shown in FIG. 15 (a) (b), one image display 9 is divided into three directions in the up, down, left and right directions, or two displays 9a and 9b or three respective displays. (9, 9a, 9b) consists of three screens in the up, down, left, and right directions, the upper screen has a far image 12, the middle screen has a near image (10), and the lower characters Composed of the structure to provide drawings, auxiliary advertising stationery, and can be installed to move to the required position by combining with the support (29).

   In this case, as shown in (a) of FIG. 15, the first reflecting mirror 5 is composed of a square with a 45 ° reference on the front end of the far image 12, and the semi-transparent mirror 3 is disposed on the short reflecting image 10 in the first reflecting mirror ( It consists of a square in the same direction as 5).

      In this case, the near image 10 is transmitted through the translucent mirror 3, and the far image 12 is reflected by the first reflector 5, and is transmitted through the dark background 10a around the near image 10 to produce a single image. To coincide.

  The viewer 22 may include a far-field image 12 located at an image separation distance B spaced by the reflection length of the first reflector 5 and a near-field image such as a car having an increased spatial three-dimensional effect due to the action of the rectangular space Z. Since 10) can be observed at the same time, the near field image 10 generates a perspective based on the far image 12.

   Therefore, in the embodiment of the present invention as described above, the viewer 22 can see various specifications, feature prices, and characters provided by the lower image while viewing the image of the car having a spatial perspective, and can display the touch screen to control the image. , Publicity effect doubles.

   In addition, the embodiment of the present invention can increase the publicity effect by simultaneously providing the real thing in the case of the company logo or smart phone on the outer surface 28 of the upper surface of the first reflector 5, the upper portion.

  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 far image 12, the near image 10 and the position of each character auxiliary image 12a.

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

In addition, the configuration of the video display 9 includes the near image 10 and the far image 12 as one, and the third video image display for deriving the auxiliary image 12a representing the lower characters is a touch type video display. Can be configured.

   This configuration has three screens, but can be divided into three screens in one video display, three screens in two video displays, or three screens in three video displays.

 In any case, however, the first reflector 5 is formed in a quadrangle at the front of the far image 12, and the translucent mirror 3 is formed in the near image 10 in the same direction as the first reflector 5. Consists of.

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

   In addition, the present invention is to produce a virtual reality image of the remote image 12 and the near-field image 10 and the viewing angle of more than 90 degrees 360 degrees to rotate the viewing angle with an image control device such as a mouse, or a gyro sensor, a position sensor, etc. in the image display It can be used as a space-separated image for virtual reality by combining and displaying the image in the corresponding direction according to the direction in which the image display is rotated.

 Therefore, the present invention in one image as described above

Separate near field image (10) and far field image (12)

The near image (10) composed of dark areas

The distance (B) ratio of the near distance (10) viewing distance A and the far image (12) is

 Min 1: 1.1 to max 1: 10

 Translucent mirror (3) is composed of transparent material, but composed of squares to derive the square space (Z) effect

 The sense of separation by the separation distance (B) of the near image and the far image in space and the various functional functions of the components

By creating a spatial stereoscopic sense of natural perspective

Without the polarizing plate and polarizing glasses, it is possible to watch a three-dimensional image with a clear distance of view with 4-10 times higher resolution than the conventional one, and the black matt surface 5b provided on one side of the translucent mirror 3 is a near field image (10). Induces the effect of casting a shadow on the long-range image (12) to increase the brightness and sharpness 2-4 times.

 Therefore, the present invention provides a clear image of perspective so as to realize the spatial reality as a high-definition image of 8-40 times compared to the image of the conventional polarizer structure.

In addition, the image structure is characterized by being able to watch in front, rear bidirectional left, right bidirectional or right and left bidirectional, or one-way multi-image.

Therefore, the present invention can be used for various purposes, such as advertising devices, video devices, game devices, educational video devices, exhibition devices.

1. Case 2. 2a. 1st, 2nd observation window 3. Translucent mirror 3a. cabinet
4. Top transmission window
5. First reflector 5a. 2nd reflector 5b.
6. Lower penetration window 7. Fixing frame 8. Fixing device
9. Video Display 9a. First Image Display 9B. 2nd video display
9c. Lenticular 91. Display 10. Close-up image 10a. Dark background
11. Rear view 12. Remote video 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 unit B. Image separation distance Z. Square space

Claims (9)

In space-separated imaging device
One image input to the spatial separation imaging apparatus is configured to be separated into a near image (10) and a far image (12), respectively
The periphery of the near image 10 is composed of a low-brightness dark background 10a so that the far image 12 can be transmitted from the back side of the near image 10.
First and second image displays 9a and 9b for separately displaying the near image 10 and the far image 12, respectively.
The position of the second image display 9b is spaced apart from the first image display 9a so that the near image 10 and the far image 12 generate a sense of reality in perspective in a rectangular space z. Form a distance (B)
By forming a translucent mirror 3 of transparent structure in a square on the front of the near image (10)
The near-field image 10 having the dark background 10a, the far-field image 12, the separation distance B, the rectangular space Z, and the function of the translucent mirror 3 having a transparent structure are mutually organic. Spatial separation imaging device, characterized in that it simultaneously works to demonstrate spatial three-dimensional effect by perspective
The black matt surface 5b transmits or reflects the semi-transparent mirror 3 so that the black matt surface 5b is provided in one direction of the semi-transparent mirror 3 so that the near image 10 and the far-field image ( 12) Spatial separation imaging device characterized by increasing the sharpness by 2-4 times by applying the shadow effect
The method of claim 1
Any one of the first and second image displays 9a and 9b;
Alternatively, the first and second image displays 9a and 9b may be configured by the projector 25 and the screen 25a.
The spatially separated imaging apparatus according to claim 1, wherein the first and second observation spheres (2, 2a) are formed at both ends of the semi-transparent mirror (3) so that images can be viewed at right angles in both directions.
According to claim 1, wherein the second reflecting mirror 5a is formed in a square so that the inside angle 3a is perpendicular to one end of the semi-transparent mirror 3, and the left, right bidirectional or the front, according to the rectangular direction of the second reflecting mirror 5a, Spatial separation imaging device characterized by being able to observe in both directions afterwards
In space-separated imaging device
One image input to the spatial separation imaging apparatus is configured to be separated into a near image (10) and a far image (12), respectively
The periphery of the near image 10 is composed of a low-brightness dark background 10a so that the far image 12 can be transmitted from the back side of the near image 10.
A single image display 9 for dividing the near image 10 and the far image 12 into two segments and configuring the same;
In front of the far image 12, the first reflector 5 is formed in a quadrangle to generate the short distance B from the near image 10.
By forming a translucent mirror (3) of the transparent structure by the rectangular space (Z) on the front of the near image (10);
The near image 10 having the dark background 10a, the far image 12, and the semi-transparent mirror 3 by the separation distance B and the rectangular space Z are simultaneously organically acted on the perspective. Spatial separation imaging device, characterized in that to exhibit a spatial three-dimensional effect
The space-separated imaging device according to claim 6, wherein the first and second observation spheres (2, 2a) are formed at both ends of the semi-transparent mirror (3), so that images can be viewed at right angles in both directions.
According to claim 6, wherein the second reflecting mirror (5a) is formed in a square so that the inside angle (3a) is at a right angle to one end of the semi-transparent mirror (3), left, right or front, or Spatial separation imaging device characterized by being able to observe in both directions after
The black matt surface 5b transmits or reflects the translucent mirror 3 in one direction of the translucent mirror 3 so that the near image 10 and the far image ( 12) Spatial separation imaging device characterized by increasing the sharpness by 2-4 times

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