KR101027065B1 - 3d viewer - Google Patents

Abstract

PURPOSE: A 3D viewer is provided to eliminate the distance limit between a viewer and a 3D image, thereby providing a viewer used in both a parallel equation and a cross equation. CONSTITUTION: The reflective surface(101') of a first reflector(101) faces the reflective surface of a second reflector(102). The reflective surface of a third reflector(103) faces the reflective surface of a fourth reflector(104). The first reflector and the fourth reflector are arranged in a V shape. A right eye image is successively incident on the first reflector. The right eye image is incident on the reflective surface of the second reflector through the reflective surface of the first reflector. And the right eye image is reflected through the reflective surface of the second reflector. A left eye image is successively incident on the reflective surface of the fourth reflector. The left eye image is incident of the reflective surface of the third reflector. And the left eye image is reflected by the reflective surface of the third reflector.

Description

3D viewer {3D VIEWER}

The present invention relates to a device for converting a 2D image into a 3D image, and in particular, consists of four reflectors, without intersecting and parallel methods, the distance between the images and the image according to the rotation and specific arrangement of the reflector It relates to a device that can arbitrarily adjust the distance between the devices.

In general, three-dimensional images representing three-dimensional images depend on the principle of stereo vision through two eyes, the parallax of two eyes, that is, binocular disparity due to the distance between two eyes that are about 65mm apart, is the most important factor of stereoscopic feeling. can do. In other words, when the left and right eyes of the human body each see a 2D image associated with each other, when these two images are delivered to the brain through the retina, the brain fuses them together to reproduce the depth and reality of the original 3D image. It is called grasterography.

The stereoscopic images use binocular disparity. The important point here is that the visible stereoscopic object must contain two images with binocular disparity or the same picture with different focus.

This method is divided into two types: parallel and crossover.

The parallel method is to focus on the back of the image so that two images are superimposed and look three-dimensional, and the crossover method is to focus on the front of the image and make two images superimposed.

Thus, a source that provides a stereoscopic image is divided into two images, a view from the right eye and a view from the left eye. By overlapping these two images, the brain recognizes them as a single image.

As such, 3D image providers produce a right eye image and a left eye image. And it is essential to check whether the images form a complete 3D, and therefore, the production of the 3D image is generally confirmed using a stereoscopic viewer (converter).

The crossover method and the parallel method have different operating principles. The producers as well as the users of the stereoscopic image had to use the crossover viewer and the parallel viewer separately. In addition, the conventional viewer has a disadvantage that the distance between the stereoscopic image and the viewer and the distance between the left eye image and the right eye image are preset. Even in the case of an adjustable viewer, there was a limitation in that adjustment.

In Figure 1 one aspect of the prior art can be seen. In the conventional viewer for the crossing method, the left and right eye images are incident through two reflectors positioned in the middle of four reflectors, reflected by the reflectors, incident and reflected on the two outermost reflectors, and sent to the eye. Devices with fixed rotations of reflectors were common, and even though the rotation was possible, the incidence method of the image was incident through the two reflectors, so the distance between the images and the available distance between the viewer and the viewer were very small. Moreover, this method is not suitable for the parallel method, so a separate parallel viewer is required for the parallel method, which will be further described below.

Figure 1b is a side of the prior art, illustrating the prior art for the parallel method. In order to transmit the left eye image and the right eye image only to the left eye and the right eye, respectively, as shown, only a limited image through the aperture is incident to the left and right eyes.

Meanwhile, conventional viewers or converters used mirrors as reflectors. The mirror is covered by a thick protective layer such as glass that covers the reflective coating. Such a thick protective layer causes distortion of the visible image due to refraction or reflection of light, thereby providing inconvenience.

As suggested above, the prior art had a lot of inconvenience. There is no restriction of the distance between the viewer and the stereoscopic image, and there is a need for a viewer that can be used in both a parallel method and a crossover method. In addition, there is a need for a viewer without light distortion.

The present invention as claimed in the following claims overcomes the above problem and provides a viewer without distance constraints and without regard to manner.

In the present invention, the four plate-shaped reflectors (101, 102, 103, 104) composed of the first reflector (101), the second reflector (102), the third reflector (103), and the fourth reflector (104), Spaced apart from the frame 110 so that the vertical axis 120 of the upper surface 111 of the frame and the rotation axis of the reflectors may be coaxially, vertically and in a row. 3D viewer 100, coupled to 110, wherein the respective reflecting surfaces 101 ′, 102 ′ of the first reflector 101 and the second reflector 102 face and the third reflector 103. ) And the respective reflecting surfaces 103 'and 104' of the fourth reflector 104 face each other, and when the viewer is viewed perpendicularly to the upper surface 111, the second reflector 102 and the third reflector 103 is arranged to form a V shape, the first reflector 101 and the fourth reflector 104 are also arranged to form a V shape, the right eye image is sequentially Incident on the reflecting surface 101 'of the dead body 101, incident on the reflecting surface 102' of the second reflector 102 through the reflecting surface 101 ', and through the reflecting surface 102'. And the left eye image is sequentially incident on the reflection surface 104 'of the fourth reflector 104, and is incident on the reflection surface 103' of the third reflector 103 through the reflection surface 104 '. And a 3D viewer 100, which is reflected through the reflective surface 103 '.

The 3D viewer of the present invention may be configured such that the exposed surface of the reflective surface of the reflector directly reflects light. The direct reflecting surface is subjected to a metal coating, preferably silver coating, for example by vacuum deposition, called magnetron sputtering, onto a metal, plastic or glass substrate, and deposits a carbon-based protective overcoat in the same manner. Can be prepared. In this way, direct reflection can be achieved and the distortion of light (refraction, interference, etc.) can be blocked.

Meanwhile, in the 3D viewer of the present invention, the second reflector 102 and the third reflector 103 may be fixed, and the first and fourth reflectors 101 and 104 may be rotated. It may include a rotation control unit to facilitate the rotation.

On the other hand, the size of the reflector and the distance between the reflectors of the 3D viewer of the present invention can be arbitrarily selected. Preferably, a person skilled in the art can arbitrarily select a size such that the size of the image can be fully projected.

The length of the frame of the present invention can be selected arbitrarily. Preferably it may be a horizontal face size of the human face.

Meanwhile, in the 3D viewer of the present invention, preferably, the second and third reflectors may be oriented at a 45 degree angle with the alignment axis of the reflectors. It will be readily appreciated by those skilled in the art that this angle may vary depending on the environment of use.

1A is a simplified plan view of the prior art associated with the present invention, for a crossing scheme.
1b is a simplified plan view of the prior art associated with the present invention, for a balanced manner.
Fig. 2A is a perspective view of the viewer of the present invention as seen from the side on which the video is placed.
2B is a perspective view of the viewer of the present invention as seen from the side where the eyeball is located.
3 is a schematic diagram utilizing the viewer of the present invention in a crossover manner.
4 is a schematic diagram of utilizing the viewer of the present invention in a parallel manner.

As shown in FIG. 2A, the 3D viewer of the present invention has a plate-shaped first reflector 101, a second reflector 102, a third reflector 103, and a fourth reflector 104, which reflectors. They each have reflective surfaces 101 ', 102', 103 ', 104' on one surface. These reflectors are spaced apart and are vertically coupled to the top surface 111 of the frame 110 in a row, and the coupling is rotated such that the vertical axis 120 of the frame surface 111 and the rotation axis of the reflectors are coaxial. If possible, it is coupled to the frame 110. Each of the reflecting surfaces 101 'and 102' of the first reflector 101 and the second reflector 102 faces each other, and each reflecting surface 103 of the third reflector 103 and the fourth reflector 104 is disposed. ', 104' are opposed to each other, and when the viewer is viewed vertically with respect to the upper surface 111, the second reflector 102 and the third reflector 103 are arranged to form a V shape. The first reflector 101 and the fourth reflector 104 are also arranged to form a V shape, and the right eye image is sequentially incident on the reflecting surface 101 'of the first reflector 101, and the reflecting surface 101' Is incident on the reflecting surface 102 'of the second reflector 102, and is reflected through the reflecting surface 102', and the left eye image is sequentially reflected on the reflecting surface 104 'of the fourth reflector 104. Is incident on the reflective surface 103 'of the third reflector 103 and reflected through the reflective surface 103'.

For example, in the present invention, as shown in FIG. 2A, the reflector and the frame are rotatably coupled vertically using the crank 120 and the screw 121. The scope of the present invention is not limited to this coupling manner, and any coupling method in which the parallel surface and the plate-like member can be rotatably coupled vertically can be utilized in the present invention.

One surface of the reflector may have a reflective surface, or both surfaces may have a reflective surface. The reflective surface is directly coated with a reflective material on the surface of the reflector for direct reflection of light. The present invention preferably uses a reflector from a platter of a hard disk.

2B is a perspective view of the 3D viewer of the present invention as viewed from the eyeball side. As illustrated, each reflector may have a rotation controller 130 at the lower side of the frame connected to the frame. The rotation control unit may be used to rotate the reflector. The rotation control unit 130 may be installed at each reflector so that each reflector may be rotated.

3 illustrates the conversion to 3D images in a crossover manner utilizing the 3D viewer of the present invention. The right eye image is incident on the reflecting surface 101 'of the first reflector and reflected by the second reflector, and the reflecting surface 102' of the second reflector sends the image to the right eye so that the right eye sees the right eye image. . Similarly, the left eye image is incident on the reflecting surface 104 'of the fourth reflector and reflected by the third reflector, and the reflecting surface 103' of the third reflector sends the image to the left eye, so that the left eye receives the left eye image. You see. The crossover method illustrated in FIG. 3 overlaps two pre-produced images (left eye image, right eye image) by focusing on two images in front of the two images so that a person looks three-dimensionally when viewing an image using the 3D viewer of the present invention. will be.

4 illustrates the conversion to 3D images in a parallel manner utilizing the 3D viewer of the present invention. The right eye image is incident on the reflecting surface 101 'of the first reflector and reflected by the second reflector, and the reflecting surface 102' of the second reflector sends the image to the right eye so that the right eye sees the right eye image. . Similarly, the left eye image is incident on the reflecting surface 104 'of the fourth reflector and reflected by the third reflector, and the reflecting surface 103' of the third reflector sends the image to the left eye, so that the left eye receives the left eye image. You see. In the parallel method illustrated in FIG. 4, the focus is confined to the rear side of the image, thereby making the image into two images of the image seen from the right eye and the image seen from the left eye, and the two images overlap each other so that the brain recognizes one stereoscopic image. Will be.

As shown in Fig. 3, the first reflector and the fourth reflector can be rotated, for example, freely adjusted according to the distance between the 3D viewer and the image, and according to the distance between the left and right eye images. It is possible. As illustrated, if the first reflector and the fourth reflector are rotated outwardly, the shorter distance between the 3D viewer and the image may be adjusted, or the distance between the left eye image and the right eye image may be adjusted. Similarly, if the first reflector and the fourth reflector are narrowed, the reverse will be true. Although not illustrated, the second reflector and the third reflector are also rotatable and can be adjusted for various situations.

Although described above by way of example only, it will be understood by those skilled in the art that the present invention may be variously modified and changed without departing from the spirit and spirit of the present invention as set forth in the claims below. will be.

Claims (6)

Four plate-shaped reflectors 101, 102, 103, 104 made up of the first reflector 101, the second reflector 102, the third reflector 103, and the fourth reflector 104 are spaced apart, Vertically coupled to the upper surface 111 of the frame 110, in a row, the vertical axis 120 of the upper surface 111 of the frame and the rotation axis of the reflector is rotatably coupled to the frame 110, As the 3D viewer 100,
Each of the reflecting surfaces 101 'and 102' of the first reflector 101 and the second reflector 102 faces each other, and each reflecting surface 103 of the third reflector 103 and the fourth reflector 104 is disposed. ', 104') are facing each other,
When the viewer is viewed perpendicularly to the upper surface 111, the second reflector 102 and the third reflector 103 are arranged to form a V shape, and the first reflector 101 and the fourth reflector are arranged. 104 is also arranged to form a V shape,
The right eye image is sequentially incident on the reflecting surface 101 'of the first reflector 101, and is incident on the reflecting surface 102' of the second reflector 102 through the reflecting surface 101 '. Reflected through slope 102 ',
The left eye image is sequentially incident on the reflecting surface 104 'of the fourth reflector 104, and is incident on the reflecting surface 103' of the third reflector 103 through the reflecting surface 104 '. Reflected through slope 103 ',
3D viewer (100).
The method of claim 1,
The exposed face of the reflecting face of the reflector is configured to reflect light directly,
3D viewer (100).
The method according to claim 1 or 2,
The second reflector 102 and the third reflector 103 is fixed,
3D viewer (100).
The method according to claim 1 or 2,
Wherein the second and third reflectors are oriented at a 45 degree angle with the alignment axis of the reflectors,
3D viewer (100).
The method according to claim 1 or 2,
Through the angle adjustment of the first and fourth reflector made to see both the crossing method and the parallel method,
3D viewer (100).
The method according to claim 1 or 2,
Through the angle adjustment of the second and the third reflector made to see both the crossing method and the parallel method,
3D viewer (100).

Images