KR102014973B1 - Holographic device - Google Patents

Abstract

The present invention provides a holographic device, which comprises: a first light processing unit for displaying a first image at a first position on a first optical axis; and a second light processing unit for displaying a second image at a second position on the first optical axis. The first light processing unit passes light input from the second position, and the first light processing unit and the second light processing unit provides a composite image of the first image and the second image to the first light processing unit side. The composite image may be assigned a depth in accordance with a physical distance difference between a first position and the second position.

Description

Holographic device {HOLOGRAPHIC DEVICE}

The present invention relates to a holographic device that provides a three-dimensional stereoscopic image to which an actual depth is applied.

Screens for projecting 3D stereoscopic images commercially available in movie theaters and the like are functionally the same as 2D image screens. However, since the image projected by the projector for 3D stereoscopic image projection is composed of two polarized light, when the polarized glasses are worn, a three-dimensional image is created by using parallax of both eyes. In this case, since polarization glasses are required, it causes a lot of inconvenience when watching, and thus, it is not a direct three-dimensional image screen.

Techniques have also been proposed for arranging the lenses on a transparent glass surface and for the light projected from the projector to pass through the lenses to form a three dimensional image near the glass surface. These technologies are called true 3D imaging techniques because the depth of focus and viewing angle of the image information are limited due to the focal length of the glass surface lenses. It is hard to see.

Korean Patent Publication No. 1665238 shows a device for forming a 3D holographic image using a scattering layer.

Korean Registered Patent Publication No. 1665238

The present invention is to provide a holographic device for outputting a three-dimensional stereoscopic image to which the actual depth (depth) is applied.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

The holographic device of the present invention comprises: a first light processing unit for displaying a first image at a first position on a first optical axis; A second light processing unit displaying a second image at a second position on the first optical axis, wherein the first light processing unit passes light input from the second position, and the first light processing unit And the second light processing unit provides a composite image of the first image and the second image to the first light processing unit, and the composite image has a depth according to a physical distance difference between a first position and the second position. (depth) can be given.

The holographic device of the present invention may output a composite image in which a second image is displayed after the first image. In this case, since the first image and the second image are displayed at physically spaced positions, a 3D stereoscopic image to which an actual depth is applied may be provided. Therefore, the holographic device of the present invention can provide an image in which the actual reality is felt.

1 is a schematic diagram illustrating a holographic device of the present invention.
2 is a schematic view showing an image projected through the display means.
3 is a schematic diagram illustrating distortion of an image due to a first mirror.
4 is a block diagram showing display means.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the contents throughout the specification.

1 is a schematic diagram illustrating a holographic device of the present invention.

The holographic device shown in FIG. 1 may include a first light processing unit and a second light processing unit.

The first light processing unit may display the first image i1 at a first position a on the first optical axis ①.

The second light processing unit may display the second image i2 at a second position b on the first optical axis ①.

The first light processing unit disposed at the first position a may pass light input from the second position b. Therefore, the second image i2 displayed on the second light processing unit disposed at the second position b may pass through the first light processing unit and be displayed on the first light processing unit together with the first image i1.

The first light processing unit and the second light processing unit may provide a composite image i _t of the first image i1 and the second image i2 to the first light processing unit.

The composite image i _t may be given an actual depth according to the physical distance difference d between the first position a and the second position b. The composite image i _t including the second image i2 to which the actual depth is given to the first image i1 may form a realistic and physical three-dimensional stereoscopic image.

The holographic device of the present invention may include a case 190 for blocking the introduction of external light.

The case 190 may surround the first light processing unit and the second light processing unit to block the inflow of external light. For example, the case 190 may include a box in which the first light processing unit and the second light processing unit are accommodated. An opening 199 may be formed on one surface of the first light processing unit side from the case 190 to the first light processing unit to optically look at the first light processing unit from the outside. The opening 199 may be an outlet through which a composite image i _t obtained by combining the first image i1 and the second image i2 is output.

The second light processing unit may be spaced apart from the first light processing unit with respect to the opening 199 and disposed behind the first light processing unit.

The first light processing unit may comprise a transparent organic light emitting diode (OLED) display disposed at a first position a such that the first image i1 is displayed and at the same time a second image i2 shown later is passed.

The second light processing unit may comprise a display disposed at the second position b and in which the second image i2 is displayed.

If a total of two displays are added, since the reality is lowered in terms of cost, a method of using the existing display means 150 such as a projector may be prepared.

For example, the first light processing unit may include a translucent first mirror 110 disposed at a first position a. The second light processing unit may include a second mirror 120 disposed at the second position b.

A third position c on the first optical axis ① where the eye looking at the composite image it is located is defined. The third position c may face the second position b with the first position a interposed therebetween. The second position b, the first position a, and the third position c may be disposed in order on the same first optical axis ① and spaced apart from each other.

The second mirror 120 may reflect the second image i2 projected by the display means 150 toward the third position c.

The semi-transparent first mirror 110 may reflect the first image i1 projected by the display means 150 toward the third position c. In addition, the first mirror 110 may pass the second image reflected from the second mirror 120 toward the third position c. For example, the first mirror 110 may include a digital single-lens translucent (DSLT) mirror.

The first image i1 output from the display means 150 installed at a position escaped from the first optical axis may travel along the second optical axis ② and be reflected by the first mirror 110 toward the first optical axis ①. The second image i2 output from the display means 150 may travel along the third optical axis ③ and be reflected toward the first optical axis ① by the second mirror 120. A separation plate 180 may be provided between the second optical axis ② and the third optical axis ③ to distinguish the optical propagation path of the first image i1 from the optical propagation path of the second image i2.

One display means 150 may be provided. The display means 150 may be fixed to the case 190 or may be detachably installed. A method of simultaneously providing the first image i1 and the second image i2 using one display means 150 may be provided.

2 is a schematic view showing an image projected through the display means 150.

As shown in FIG. 2A, one display means 150 may have one projection area L output through a single barrel.

The display means 150 may divide one projection area L into a first area L1 and a second area L2. The display means 150 may project the first image i1 in the first area L1 and the second image i2 in the second area L2.

The adjusting means 170 may be provided between the first mirror 110 and the display means 150 or between the second mirror 120 and the display means 150.

The adjusting unit 170 may adjust the light path of the first image i1 projected on the first area L1 toward the first mirror 110. The adjusting means 170 may adjust the light path of the second image i2 projected on the second area L2 toward the second mirror 120. As an example, the adjusting means 170 may comprise one or more reflective mirrors. Meanwhile, in order to align each image to each of the first mirror 110 or the second mirror 120 separately, a moving means 160 for moving the adjusting means 170 may be provided. The movement means 160 is controlled by the adjustment button 191 exposed on the outer surface of the case 190 and may move the adjustment means 170.

The first image i1 and the second image i2 separated and projected to each mirror by the adjusting unit 170 may form a composite image i _t merged into one in the first mirror 110. The composite image i _t disclosed herein may be different from a typical composite image in which two image files are combined into one file. The first image i1 and the second image i2 of the present invention may be elements displayed independently of each other. However, the positions to be displayed or projected have a common point via the common first mirror 110. When viewed from the third position c, the first image i1 and the second image i2 via the common first mirror 110 may be displayed together on one screen as shown in FIG. . In this specification, an image in which the separate first images i1 and the second images i2 that are spaced apart from each other when viewed from the third position c may be referred to as a composite image i _t .

3 is a schematic diagram illustrating a distortion phenomenon of an image due to the first mirror 110.

The first image i1 may be projected on the first mirror 110 along the second optical axis ② inclined to the first optical axis ①.

The first mirror 110 may be inclined at the first optical axis ① so that the first image i1 projected along the second optical axis ② is reflected toward the third position c.

Due to the inclination of the first mirror 110 with respect to the first optical axis, a first distortion f (t) may be generated in the first image i1 based on the third position c. For example, a perspective may be applied to each image due to a phenomenon in which one side of the inclined first mirror 110 approaches the third position c and the other side of the first mirror 110 moves away from the third position c.

If the display means 150 projects the first image t1 of the normal rectangular screen as shown in FIG. 3A, the display means 150 distorts to the parallelogram screen due to the first distortion f (t) of the first mirror 110. First image f (t) i1 may be provided at a third position c.

When looking at the first mirror 110 at the third position c, the display means 150 displays the first image i1 as shown in FIG. 3B so that the first image i1 of the normal rectangular screen can be viewed. Can be output by inverse distortion f ^-1 (t).

The first reversely distorted first image f ⁻¹ (t) i1 may be the first image i1 of the normal rectangular screen before the first reverse distortion by the first distortion f (t) reflected while passing through the first mirror 110. Can be.

The second image i2 may also be processed in the same way.

In detail, the second image i2 may be projected onto the second mirror 120 along the third optical axis ③ inclined to the first optical axis ①.

The second mirror 120 may be formed to be inclined at the first optical axis ① so that the second image i2 projected along the third optical axis ③ is reflected toward the third position c.

Distortion may occur in the second image i2 based on the third position c due to the inclination of the second mirror 120 with respect to the first optical axis ①.

The display means 150 may output the normal second image i2 by performing second reverse distortion.

The second reversely distorted second image may be the second normal image i2 before the second reverse distortion by the second distortion.

1 again, when the image projected from the projector is reflected directly to each mirror, the light projecting the image is directly input to the eye, so the eyes are swelling and each image cannot be recognized.

In order to shape the light projected from the projector into the first image i1 or the second image i2 visible to the human, a rear screen may be provided at a position facing each mirror. The rear screen may be stored in the case 190.

The first rear screen 130 may be disposed between the first mirror 110 and the projector.

The second rear screen 140 may be disposed between the second mirror 120 and the projector.

The projector may project the first image i1 on the first rear screen 130. If necessary, the adjusting means 170 may be disposed between the projector and the first rear screen 130.

The projector may project the second image i2 on the second rear screen 140. If necessary, the adjusting means 170 may be disposed between the projector and the second rear screen 140.

The first mirror 110 may reflect the first image i1 displayed on the first rear screen 130 to the third position c. The user may view the first image i1 displayed on the first rear screen 130 through the first mirror 110 at the third position c.

The second mirror 120 may reflect the second image i2 displayed on the second rear screen 140 to the third position c. The user may view the second image i2 displayed on the second rear screen 140 through the first mirror 110 and the second mirror 120 at the third position c.

4 is a block diagram showing the display means 150.

In order to provide a meaningful composite image i _t , the physically separate first image i1 and the second image i2 preferably include objects associated with each other.

In order to increase the correlation between the first image i1 and the second image i2, the display means 150 for providing the first image and the second image may include an extractor 151 and a generator 153.

Extraction unit 151 may receives the one of the original image i _o, i _o analyzing the original image. The extraction unit 151 may classify and extract the first object o1 included in one original image i _o and the second object o2 disposed behind the first object o1.

The generation unit 153 may generate a first image i1 including the first object o1 and generate a second image i2 including the second object o2.

The generation unit 153 may provide a first image i1 including the first object o1 to the first light processing unit and provide a second image i2 including the second object o2 to the second light processing unit.

The time point at which the first image i1 is displayed in the first light processing unit may coincide with the time point at which the second image i2 is displayed in the second light processing unit.

According to the present embodiment, a plurality of objects included in one original image may be divided into a first image and a second image. Thus, a meaningful composite image i _t can be provided in which the association of the first image with the second image is greatly improved.

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

110 ... first mirror 120 ... second mirror
130 ... first rear screen 140 ... second rear screen
150 Display means 151 Extraction unit
153.Generation unit 160 ... Means of movement
170 ... adjustment means 180 ... separator
190 ... Case 191 ... Adjustment button
199 ... opening

Claims (8)

A first light processing unit for displaying a first image at a first position on the first optical axis;
A second light processing unit displaying a second image at a second position on the first optical axis;
The first light processing unit passes the light input from the second position,
The first light processing unit and the second light processing unit provide a composite image of the first image and the second image,
The composite image is given a depth according to a physical distance difference between a first position and the second position,
The first image output from the display means installed at the position escaped from the first optical axis travels along the second optical axis and is reflected by the first light processing unit toward the first optical axis,
The second image output from the display means travels along a third optical axis and is reflected by the second light processing unit toward the first optical axis,
A separation plate is provided between the second optical axis and the third optical axis to distinguish the light propagation path of the first image from the light propagation path of the second image.
A case is provided to surround the first light processing unit and the second light processing unit to block the inflow of external light, and an opening is formed on one side of the first light processing unit on the first optical axis.
The second light processing unit is disposed behind the first light processing unit based on the opening,
The first light processing unit comprises a translucent first mirror disposed at the first position,
The second light processing unit includes a second mirror disposed at the second position,
When a third position on the first optical axis where the eye looking at the composite image is located is defined,
The second mirror reflects the second image projected by the display means toward the third position,
The semi-transparent first mirror reflects the first image projected by the display means toward the third position, passes the second image reflected from the second mirror towards the third position,
One display means is provided,
One display means has one projection area,
The display means divides one projection area into a first area and a second area,
The display means projecting the first image onto the first area, projecting the second image onto the second area,
The display means comprises a projector,
A first rear screen disposed between the first mirror and the projector, and a second rear screen disposed between the second mirror and the projector,
The projector to project the first image to the first rear screen, to project the second image to the second rear screen,
The first mirror reflects the first image displayed on the first rear screen,
The second mirror reflects the second image displayed on the second rear screen,
Adjusting means for adjusting the light path of the first image projected on the first area toward the first mirror and adjusting the light path of the second image projected on the second area toward the second mirror; Prepared,
The adjusting means comprises a reflecting mirror,
A holographic device provided with moving means for moving said reflection mirror to align said each image separately to said first mirror or said second mirror.
delete delete delete The method of claim 1,
The first image is projected onto the first mirror along the second optical axis inclined to the first optical axis,
The second image is projected onto the second mirror along the third optical axis inclined to the first optical axis,
The first mirror and the second mirror are formed to be inclined to the first optical axis,
A tilt of the first mirror causes a first distortion in the first image,
The display means outputs the first reverse distortion by the first image,
The first reversely distorted first image becomes the first image before the first reverse distortion by the first distortion,
A second distortion occurs in the second image due to the tilt of the second mirror,
The display means outputs the second reverse distortion by the second image,
And the second inversely distorted second image is the second image before the second inverse distortion by the second distortion.
delete delete The method of claim 1,
The display means provides the first image and the second image,
The display means includes an extracting unit and a generating unit,
The extractor classifies and extracts a first object included in one original image and a second object disposed behind the first object,
The generation unit generates the first image including the first object, generates the second image including the second object,
The generation unit provides the first image to the first light processing unit and simultaneously provides the second image to the second light processing unit,
And a time point at which the first image is displayed in the first light processing unit is coincident with a time point at which the second image is displayed in the second light processing unit.

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