KR101414094B1 - Apparatus for testing align in three-dimensional device without glasses - Google Patents

Abstract

The present invention relates to an alignment test device of a glasses-free three-dimensional display device. Especially, the display device includes: a surface plate mounting a glasses-free display device of a parallax barrier method; a support standing up at one side of the top surface of the surface plate; a cradle installed at the support; an image capturing unit including a center camera installed at the center of the cradle to capture a middle portion between a left image and a right image generated from the glasses-free three-dimensional display device, a left camera installed at the left of the center camera to capture a left image generated from the glasses-free three-dimensional display device, and a right camera installed at the right of the center camera to capture a right image generated from the glasses-free three-dimensional display device; an image display unit including a center monitor electrically connected to the image capturing unit to display an image captured by the center camera, a left monitor displaying an image captured by the left camera, and an image captured by the right camera; a control unit electrically connected to the image display device to determine whether the alignment of a parallax barrier is normal on the basis of an image displayed on the image display unit. Since there is not need to determine whether each alignment is normal by a user, work processes may be automated and also the accurate determination on whether each alignment is normal may be obtained.

Description

TECHNICAL FIELD [0001] The present invention relates to an alignment inspection apparatus for a three-

The present invention relates to an alignment inspection apparatus for a three-dimensional non-eyeglass display apparatus, and more particularly, to an alignment inspection apparatus for a three-dimensional non-eyeglass display apparatus capable of determining whether alignment of a parallax barrier included in a three- .

Generally, stereoscopic images representing three-dimensional images are made by the principle of stereoscopic vision through two eyes. The parallax parallax which appears because the parallax of the two eyes, that is, the two eyes are about 60 to 70 mm away, This is an important factor. In other words, the left and right eyes see different two-dimensional images, and when these two images are transmitted to the brain through the retina, the brain fuses them exactly to reproduce the depth and real feeling of the original three-dimensional image.

Currently presented techniques for displaying a three-dimensional stereoscopic image include a stereoscopic image display using special glasses, a non-stereoscopic stereoscopic image display, and a holographic display method.

The stereoscopic image display system using the double special glasses includes a polarizing glasses system using a vibration direction or a rotation direction of polarized light, a time division spectacle system in which left and right images are alternately presented while being switched to each other, and a system of transmitting light of different brightness in the right and left Can be divided into the concentration difference method.

In the non-eye-hardened stereoscopic image display system, a parallax barrier system in which an image can be separated and viewed through a vertical grid-like aperture in front of each image in the right and left eyes, A lenticular method using an aligned lenticular plate, and an integral method using a fly-eye lens plate.

In the holographic display method, a three-dimensional stereoscopic image having all factors such as focus adjustment, convergence angle, binocular parallax, and motion parallax which are three-dimensional images can be obtained. The laser light reproduction hologram and the white light reproduction hologram .

Although the stereoscopic image display system using the special glasses can enjoy the stereoscopic image by a large number of people, it is disadvantageous to wear separate polarizing glasses or liquid crystal shutter glasses. That is, the observer must wear special glasses to cause inconvenience and unnaturalness.

The non-eye-hardened stereoscopic image display system tends to be preferred because it has a fixed range of observation and is limited to a small number of people but does not wear glasses. That is, since the observer directly observes the screen, the above-mentioned disadvantages disappear and many studies are proceeding.

A holographic display method can be exemplified as displaying a perfect three-dimensional image, which mainly displays images of three-dimensional coordinates directly in space through a laser, a lens, and a mirror, , But there is a disadvantage that the technical difficulties and the space occupied by the equipment become large.

Therefore, there is an increasing tendency to adopt the Parallax Barrier method, which is a method of realizing a virtual three-dimensional image through a spoof using a stereo image.

The Parallax Barrier has a vertical or horizontal shape (slit) in front of the image corresponding to the left and right eyes, thereby separating the stereoscopic images synthesized through the slit, thereby realizing a stereoscopic effect.

Hereinafter, a three-dimensional image display apparatus using the parallax barrier system will be briefly described.

FIG. 1 is a diagram showing a three-dimensional image implemented by a 3D display device of a Parallax Barrier type.

1, in the conventional parallax barrier system, a barrier panel 2, in which a slit through which light emitted from a video panel is transmitted and a barrier for blocking the light are repeatedly arranged, As shown in Fig.

Thus, the observer 1 sees the displayed or printed image on the image panel 3 through the slit of the barrier panel 2. Even if the left and right eyes of the observer 1 pass through the same slit, You will see another area.

The parallax barriers are based on this principle, so that images corresponding to pixels in different regions of the left eye and the right eye are seen through the slit, thereby realizing a stereoscopic effect.

1, the left eye L sees the left eye corresponding pixel LP in the image panel 3 and the right eye R sees the right eye corresponding pixel RP in the image panel 3. [

Accordingly, in the parallax barrier method of implementing a three-dimensional image in the above-described manner, the alignment state of the parallax barrier, that is, the barrier panel 2, is very important. That is, if the alignment of the barrier panel is not normal, the images entering the left eye and the right eye are mixed with each other and an accurate image can not be realized. Therefore, a device capable of checking the energetic state of the barrier panel is needed.

However, there has been a problem that not only an alignment state of a barrier panel, that is, a parallax barrier can be accurately determined, but an apparatus capable of automating a work process related to the determination has not been developed yet.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the conventional art, and it is an object of the present invention to provide a display device capable of not only determining whether the parallax barrier included in the three- An object of the present invention is to provide an alignment inspection apparatus for a three-dimensional non-eyeglass display device.

According to another aspect of the present invention, there is provided an apparatus for inspecting alignment of a three-dimensional non-eyeglass display device, including: a platen for placing a three-dimensional non-eyeglass display device of a parallax barrier type; A support table installed upright on one side of the upper surface of the table; A cradle mounted on the support; A center camera installed at the center of the cradle for capturing an intermediate portion between a left image and a right image generated in the 3D glassesless glasses display device and a center camera installed at the left side of the center camera, An image photographing unit including a left camera for photographing a left image and a right camera for photographing a right image generated in the 3D non-eyeglass display device installed on the right side of the center camera; A center monitor electrically connected to the image capturing unit and displaying an image photographed by the center camera, a left monitor displaying an image photographed by the left camera, and a right monitor displaying an image photographed by the right camera, A video display unit; And a control unit electrically connected to the image display unit to determine whether the parallax barrier is aligned or misaligned from the image displayed on the image display unit.

Here, the cradle is mounted on the support frame so that the cradle can be elevated, and the left camera and the right camera are installed on the cradle so as to be adjustable in angle.

If the colors of the left image and the right image appear mixed in the left image and the right image respectively displayed on the left monitor and the right monitor of the image display unit, the control unit determines that the alignment error is a parallax barrier.

The apparatus for inspecting alignment of a three-dimensional non-eyeglass display apparatus according to the present invention configured as described above is characterized in that a screen of a three-dimensional non-eyeglass display apparatus photographed by an image photographing unit is displayed on an image display unit, It is not necessary for the person to determine whether or not the alignment is normal by judging the alignment error of the parallax barrier and the alignment error so that it is possible to automate the work process and increase the accuracy of the alignment normal determination.

1 is a view showing a three-dimensional image implemented by a 3D display device of a Parallax Barrier type.
2 is a perspective view of an alignment inspection apparatus of a three-dimensional non-eyeglass display apparatus according to the present invention.
3 is a block diagram briefly showing a relation of an alignment inspection apparatus of a three-dimensional non-eyeglass display apparatus according to the present invention.
FIG. 4 is a view showing a state in which alignment is observed when the alignment inspection apparatus of the three-dimensional non-eyeglass display apparatus according to the present invention is inspected.
FIG. 5 is a view showing a case where an alignment error occurs when the alignment inspection apparatus of the three-dimensional non-eyeglass display apparatus according to the present invention is inspected.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of an alignment inspection apparatus for a three-dimensional non-eyeglass display apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view of an alignment inspection apparatus of a three-dimensional non-eyeglass display apparatus according to the present invention, and FIG. 3 is a block diagram briefly showing a relation of an alignment inspection apparatus of a three-dimensional non-eyeglass display apparatus according to the present invention.

FIG. 4 is a view showing a state in which alignment is performed when the alignment inspection apparatus of the three-dimensional non-eyeglass display apparatus according to the present invention is inspected. FIG. It is a diagram showing a case where an alignment error occurs when the apparatus is inspected.

The alignment inspection apparatus of the three-dimensional non-eyeglass display apparatus according to the present invention comprises a base 10, a support 20 mounted on the top of the base 10, a holder 30 mounted on the support 20, An image capturing unit 40 installed in the cradle 30, an image display unit 50 electrically connected to the image capturing unit 40 and a control unit 60 electrically connected to the image display unit 50 .

The surface plate 10 has a flat upper surface, and a three-dimensional non-eyeglass display device D of a parallax barrier type is mounted on the flat upper surface.

The support base 20 is installed upright on one side of the upper surface of the base 10. A rail hole 21 is formed at the center of the support base 20 in a vertical direction, 30 are moved up and down.

The cradle 30 is installed on the support 20, and the overall shape of the cradle 30 is a panel shape having a certain radius of curvature. As described above, the cradle 30 can be elevated and lowered along the rail hole 21 of the support 20 by being installed on the support 20.

The image capturing unit 40 includes a central camera 41, a left camera 42, and a right camera 43.

The center camera 41 is installed at the center of the cradle 30 to photograph an intermediate portion between the left and right images generated in the 3D glassesless display device D.

The left camera 42 is installed on the cradle 30 and is installed on the left side of the center camera 41 to photograph a left image generated by the 3D glassesless display device D. [

The right camera 43 is installed on the cradle 30 and is located on the right side of the center camera 41 to photograph the right meditation generated in the 3D glassesless display device D. [

Meanwhile, the left camera 42, the right camera 43, and the center camera 41 are installed on the cradle 30 so as to be adjustable in angle.

The image display unit 50 includes a central monitor 51, a left monitor 52, and a right monitor 53.

The central monitor 51 is electrically connected to the central camera 41 of the image capturing unit 40 to display an image captured by the central camera 41. If the alignment state of the parallax barrier is normal, the central camera 41 captures an intermediate portion between the left image and the right image as described above. Therefore, the image displayed on the central monitor 51, as shown in FIG. 4, A line is formed and the color of the left image and the color of the right image are displayed separately on both sides of the line. As shown in the figure, if the color of the left image is blue and the color of the right image is red, a blue image is displayed on the left side and a red image is displayed on the right side based on the center line.

The left monitor 52 is installed on the left side of the central monitor 51 and is electrically connected to the left camera 42 of the image capturing unit 40. Therefore, the left monitor 52 displays the image captured by the left camera 42. [ If the color of the left image is blue as in the previous example, a blue image is displayed on the left monitor 52.

The right monitor 53 is installed on the right side of the central monitor 51 and is electrically connected to the right camera 43 of the image capturing unit 40. Therefore, the image photographed by the right camera 43 is displayed on the right monitor 53. If the color of the right image is red as in the previous example, a red image is displayed on the right monitor 53.

The control unit 60 is electrically connected to the image display unit 50 to determine whether the parallax barrier is aligned or misaligned from the image displayed on the image display unit 50. [ The control unit 50 stores a reference data range for determining the alignment error and the alignment error in advance. If the screen displayed on the image display unit 50 is out of the reference data range based on the reference data, the control unit 50 determines that the alignment error If it is within the reference data range, it is determined that the alignment is normal.

The control unit 60 mixes the color of the left image and the color of the right image in the left image displayed on the left monitor 52 of the image display unit 50 and displays the right image on the right monitor 53, when the color of the left image and the color of the right image are mixed, it is determined that the parallax barrier is an alignment error.

That is, as shown in FIG. 5, the colors of the left image and the right image are not clearly displayed on the left monitor 52 and the right monitor 53, Is displayed on the left monitor 52 and the right monitor 53 to grasp that the parallax barriers are not aligned normally and are misaligned. The control unit 60 determines the alignment error state or the alignment steady state through the image displayed on the image display unit 50.

10: Plate 20: Support
21: Rail hole 30: Cradle
40: image capturing section 41: central camera
42: left camera 43: right camera
50: video display section 51: central monitor
52: Left monitor 53: Right monitor
60:

Claims (3)

A base 10 on which a 3D non-eyeglass display device D of a parallax barrier type is placed; A support table 20 installed upright on one side of the upper surface of the base 10; A cradle (30) installed on the support (20); A center camera 41 installed at the center of the cradle 30 for capturing an intermediate portion between a left image and a right image generated by the 3D non-eyeglass display device D, A left camera 42 installed on the right side of the center camera 41 for photographing a left side image generated in the 3D glassesless display device D, And a right camera (43) for photographing a right side image; A central monitor 51 electrically connected to the image capturing unit 40 to display an image captured by the central camera 41 and a left monitor 52 displaying an image captured by the left camera 42, And a right monitor (53) for displaying an image photographed by the right camera (43); And a controller 60 electrically connected to the image display unit 50 to determine whether the parallax barrier is aligned or misaligned from the image displayed on the image display unit 50,
A rail hole 21 is vertically formed at the center of the support base 20 so that the base 30 is moved up and down on the rail hole 21,
When the colors of the left image and the right image appear mixed in the left image and the right image respectively displayed on the left monitor 52 and the right monitor 53 of the image display unit 50, Of the three-dimensional non-eyeglass display device.
The method according to claim 1,
Wherein the left camera (42) and the right camera (43) are installed on the cradle (30) so as to be adjustable in angle. delete

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