KR102008323B1 - Three Dimensional Image Display Device - Google Patents

Abstract

The present invention provides a left eye image, and includes a first group subpixel for a left eye and a second group subpixel for a left eye of a second red, green and blue subpixel for a left eye. , The left eye pixel consisting of the left eye third group subpixel for the left eye, and the left eye third pixel for the left eye, and the right eye image for displaying the right eye image. A right eye pixel comprising a pixel, a second group subpixel for the right eye of the right, a green and a blue subpixel for the right eye, and a third group subpixel for the right eye of a third, green and a blue subpixel for the right eye A display panel; And a barrier panel that separates the left eye image and the right eye image and delivers the left eye image and the right eye image to the left eye and the right eye, respectively, wherein the first to third subpixels for the left eye have a left portion within the first to third group subpixels for the left eye. Are alternately arranged at the central portion and the right portion, and the first to third green subpixels for the left eye are alternately arranged at the left portion, the center portion, and the right portion within the first to third group subpixels for the left eye, The first to third blue subpixels for the left eye may alternately arrange the left, the center, and the right portions within the first to third group subpixels for the left eye.

Description

3D image display device and driving method thereof {Three Dimensional Image Display Device}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional image display device, and more particularly, to a switchable three-dimensional image display device including first to third red, green, and blue pixels arranged to prevent color separation, and a driving method thereof.

The technology of realizing 3D image that allows you to feel 3D depth and 3D feeling from 2D image is widely used in direct related fields such as display, home appliances, communication industry, aerospace, art industry and automobile business field. The technical ripple effect is expected to be higher than the current high definition television (HDTV).

The most important factor for the human sense of depth and three-dimensionality is binocular disparity due to the distance between the two eyes, but there is also a strong relationship between psychological and memory factors. Based on whether a 3D image can be provided to a user, it is generally classified into a volumetric type (volumetric type), a three-dimensional type (holographic type), and a stereoscopic type (stereoscopic type).

The volume expression method is a way to feel the perspective of the depth direction due to psychological factors and inhalation effects. The viewing angle is calculated by a 3D computer graphic or an observer who displays perspective, superposition, shadow, contrast, and movement by calculation. It is applied to so-called IMAX movies, which provide a large large screen and cause optical illusions to be sucked into the space.

In addition, the 3D representation method known as the most complete stereoscopic image realization technology may be represented by laser light reproduction holography or white light reproduction holography.

In addition, the stereoscopic expression method is a way to feel the three-dimensional feeling by using the physiological factors of both eyes, specifically, when the associated image of the plane containing the parallax information in the left and right of human beings that are about 65 mm apart, the brain fused them In the process of creating spatial information before and after the display surface, the ability to feel a three-dimensional effect, that is, using stereography (stereography).

This stereoscopic expression method is called a multi-eye display method, and the spectacle method using the special glasses on the observer's side or the parallax barrier, lenticular or integral on the display side depending on the actual stereoscopic generation position. It can be divided into an autostereoscopic method using a lens array of the back.

Among these, in brief, the principle of realizing a 3D image of an autostereoscopic 3D image display apparatus using a parallax barrier or a lens array, a stripe is displayed between a user and a display panel that simultaneously displays left and right stereo images. A slit and barrier of a shape or a plurality of semi-cylindrical lenticular lenses are arranged to make a viewer feel three-dimensional.

A three-dimensional image display device using a barrier among such auto glasses-less systems will be described with reference to the drawings.

1 is a plan view illustrating the operation of a parallax barrier type 3D image display device.

As shown in FIG. 1, the parallax barrier type 3D image display device 10 includes a display panel 20 and a parallax barrier 30 that simultaneously display left and right images.

The display panel 20 includes a left eye pixel L for displaying a left eye image IL and a right eye pixel R for displaying a right eye image IR, which includes a left eye pixel L and a right eye pixel R. Are alternately arranged.

The parallax barrier 30 includes a slit 32 and a barrier 34 for selectively passing the light emitted from the display panel 20, and the slit 32 and the barrier 34 include the viewer 40. Are alternately arranged in a stripe shape in the longitudinal direction.

In the 3D image display apparatus 10, the left eye image IL displayed by the left eye pixel L of the display panel 20 passes through the slit 32 of the parallax barrier 30 of the viewer 40. The right eye image IR reached by the left eye and displayed by the right eye pixel R of the display panel 20 reaches the right eye of the viewer 40 via the slit 32 of the parallax barrier 30. The left eye image IL and the right eye image IR each contain separate images in consideration of parallax that can be detected by a human, and the viewer 40 recognizes a three-dimensional image by combining the two images.

At this time, the width P of the left eye pixel L and the right eye R formed on the display panel 20, the width M of the barrier 34 of the parallax barrier 30, and the width of the parallax barrier 30 The width Q of the slit 32, the width E between the left and right eyes, the distance S from the display panel 20 to the parallax barrier 30, and the viewer 40 from the parallax barrier 30. The distance D to has the following relationship.

M + Q = 2 / (1 / E + 1 / P)

D = SE / P

Since the width E between the left eye and the right eye of a human is about 65 mm, the width E of the left eye L and the right eye R using the above relationship with the value of the width E between the left eye and the right eye By designing P), the width M of the barrier 34, and the width Q of the slit 32, the three-dimensional image can be displayed by the parallax barrier type three-dimensional image display device 10.

On the other hand, barrier panels are formed by forming two electrodes facing the parallax barrier and a liquid crystal layer interposed therebetween, so that the position and size of the slit and barrier can be modified by voltages applied to the two electrodes. A switchable display device capable of selectively displaying two-dimensional images and three-dimensional images by driving the entire area of the barrier panel to transmit light or selectively driving a portion of the barrier panel to transmit light selectively. display device) has been proposed.

In addition, with the development of smart phones, the method of using the display device also appears in a variety of aspects, as an example of the product is introduced to rotate one screen vertically or horizontally to suit each purpose have.

That is, in general, a display device is typically fixed to display only one of a landscape image having a width in a horizontal direction greater than a height in a vertical direction or a portrait image on the contrary, but recently, the display device is rotated. And a display device having a pivot function for displaying a horizontal image or a vertical image as needed, such a display device operates in a landscape display mode in the case of movie watching, In the case of displaying a large amount of information, for example, when working with a large number of text files open, it is utilized to operate in a portrait display mode.

2A and 2B illustrate an operation in a portrait display mode and a landscape display mode of a conventional switchable 3D image display device having a pivot function, respectively.

As shown in FIG. 2A, when the conventional switchable 3D image display device 110 operates in the vertical display mode, the red, green, and blue pixels r, g, and b of the display panel 120 The slits 132 and the barriers 134 of the barrier panel 130 have a vertical stripe shape which is repeatedly arranged alternately left and right.

As shown in FIG. 2B, when the conventional switchable 3D image display device 110 operates in the horizontal display mode, the red, green, and blue pixels (r, g, b) of the display panel 120 are operated. ) Has a vertical stripe shape that is arranged alternately left and right, and the slit 132 and the barrier 134 of the barrier panel 130 has a vertical stripe shape that is repeatedly arranged alternately left and right.

In the switchable three-dimensional image display apparatus 110, the display panel 120 displays the left eye image and the right eye image, and the barrier panel 130 separately supplies the left eye image and the right eye image to the viewer's left and right eyes, thereby three-dimensionally Display the video.

However, in the switchable 3D image display device 110 operating in the horizontal display mode, since the amount of light for each color in the front viewing angle and the inclined viewing angle is different, a defect such as color break-up occurs. It demonstrates with reference to drawings.

FIG. 3 is a view for explaining color separation of a conventional switchable 3D image display device, and FIG. 4 is a view showing a light amount distribution for each color of an image displayed by a conventional switchable 3D image display device. .

As shown in FIG. 3, in the conventional switchable three-dimensional image display device 110 operating in the horizontal display mode, the left eye red, green, and blue pixels 121r, 121g, 121b of the display panel 120 are formed. The left eye image IL to be displayed is transmitted to the left eye of the viewer 140 through the slit 132 of the barrier panel 130, and the right, green, and blue sub-pixels 125r, 125g, and 125b of the display panel 120 are provided. The right eye image IR displayed by) is transmitted to the right eye of the viewer 140 through the slit 132 of the barrier panel 130.

However, the left, green, and blue subpixels 121r, 121g, and 121b and the right, red, green, and blue subpixels 125r, 125g, and 125b of the display panel 120 are arranged in the horizontal direction to the left and right, and the barrier panel Since the slit 132 and the barrier 134 of 130 are also arranged in the horizontal direction to the left and right, the left eye red, green and blue subpixels 121r, 121g and 121b and the right eye red, green and blue subpixels 125r and 125g. , The distance from 125b to the slit 132 of the barrier panel 130 is different from each other.

Accordingly, the central portions of the red, green, and blue light passing through the slit 132 of the barrier panel 130 reach different positions in the horizontal direction at the left and right at the point of the viewer 140, and as a result, the viewer 140 The red, green, and blue light amount distributions are different, and color separation occurs.

For example, the red, green, and blue light (Lr, Lg, Lb) for displaying the right-eye image (IR) emitted from the right-eye red, green, and blue sub-pixels (125r, 125g, 125b) is the right eye of the viewer 140. The peaks in the center are transmitted at positions a, b, and c different from each other. As a result, the amount of red, green, and blue light received by the viewer 140 is different from each other, so that the viewer 140 separates colors. Will feel.

That is, as shown in Figure 4, the position of the peak (peak) of the red, green, blue light displayed by the switchable three-dimensional image display device 110 at the viewer point is different from each other, the viewer 140 accordingly There is a problem in that the display quality is deteriorated because the user feels a different color from the color of the actual 3D image by color separation.

The present invention has been proposed to solve this problem, by arranging the first to third, green, and blue pixels so that the average distance from the display panel to the barrier panel is the same, color separation is prevented, An object of the present invention is to provide a 3D image display device and a driving method thereof having improved display quality.

In order to solve the above problems, the present invention, the left eye first group sub-pixel consisting of the first eye, green, blue sub-pixel for the left eye and the left eye image, and the second, green, blue sub-pixel for the left eye A left eye pixel composed of a second group subpixel for the left eye, a third group green pixel for the left eye, and a pixel for the left eye composed of a third group subpixel for the left eye, and a right eye image for displaying a right eye image And the first group subpixel for the right eye consisting of blue subpixels, the second group subpixel for the right eye consisting of second, green and blue subpixels for the right eye, and the third, green, blue subpixel for the right eye A display panel including a right eye pixel comprising a right eye third group of subpixels; A barrier panel disposed in front of the display panel to separate the left eye image and the right eye image and to transfer the left eye image and the right eye image to the left eye and the right eye, respectively, wherein the first to third subpixels for the left eye include the first to third eyes for the left eye. The left, first, and third green subpixels of the left eye are alternately arranged in the left, middle, and right portions of the three group subpixels. The left eye first to third blue subpixels are alternately arranged on the right side, and the left eye first to third group subpixels are alternately arranged on the left side, the center portion, and the right side within the first to third group subpixels for the left eye. Provide the device.

The first to third subpixels for the right eye are alternately arranged in the left, center, and right portions of the first to third group subpixels for the right eye, and the first to third green subpixels for the right eye. Are alternately arranged in the left part, the center part, and the right part in the first to third group subpixels for the right eye, and the first to third blue subpixels for the right eye are first to third for the right eye. In the group subpixel, the left part, the center part, and the right part may be alternately arranged.

In addition, the same left eye red data signal is applied to the first to third subpixels for the left eye, and the same left eye green data signal is applied to the first to third green subpixels for the left eye. The same left eye blue data signal is applied to the first to third subpixels, and the same right eye red data signal is applied to the first to third subpixels for the right eye, and the first to third greens for the right eye are applied. The same right eye green data signal may be applied to the subpixel, and the same right eye blue data signal may be applied to the first to third blue subpixels for the right eye.

The left eye first to third group subpixels are sequentially arranged, the right eye first to third group subpixels are sequentially arranged, and the left eye pixel and the right eye pixel are alternately repeatedly arranged. Can be.

Further, the first red, green, blue sub-pixel for the left eye, the second blue for the left eye, red, green sub-pixel, the third green for the left eye, the blue, red sub-pixel, the first red, green, The blue sub-pixel, the right eye second blue, red, green sub-pixel, the right eye third green, blue, red sub-pixel may be arranged sequentially.

And the first group subpixel for the left eye, the first group subpixel for the right eye, the second group subpixel for the left eye, the second group subpixel for the right eye, the third group subpixel for the left eye, and the right eye The third group subpixels may be sequentially and repeatedly arranged.

In addition, the left eye first red, green, blue sub-pixel, the right eye first red, green, blue sub-pixel, the left eye second blue, red, green sub-pixel, the right eye second blue, red, The green subpixel, the left eye third green, blue, red subpixel, and the right eye third green, blue, red subpixel may be sequentially arranged.

The barrier panel includes a slit through which light passes and a barrier through which light is blocked, and the position and size of the slit and the barrier are in a vertical display mode, a horizontal display mode, a two-dimensional image display mode, and a three-dimensional image. It can be changed according to the display mode.

Meanwhile, the present invention applies the same left eye red data signal to the left eye first to third sub-pixels of the left eye first to third group sub-pixels that constitute the left eye pixel of the display panel. The same left eye green data signal is applied to the left eye first to third green subpixels of the first to third group subpixels, and the first to third blue parts for the left eye of the first to third group subpixels for the left eye are applied. Displaying a left eye image by applying the same left eye blue data signal to a pixel; The same right eye red data signal is applied to the right eye first to third subpixels of the right eye first to third group subpixels constituting the right eye pixel of the display panel, and the first to third group for the right eye The same right eye green data signal is applied to the first to third green subpixels for the right eye of the subpixel, and the same right eye to the first to third blue subpixels for the right eye of the first to third group subpixels for the right eye. Displaying a right eye image by applying a blue data signal; And separating the left eye image and the right eye image by a barrier panel and delivering the left eye image and the right eye image, respectively.

The first to third subpixels for the left eye are alternately arranged in the left part, the center part, and the right part in the first to third group subpixels for the left eye, and the first to third green subpixels for the left eye. Are alternately arranged in the left part, the center part, and the right part in the first to third group subpixels for the left eye, and the first to third blue subpixels for the left eye are the first to third eyepieces for the left eye. The left part, the center part, and the right part are alternately arranged in the group subpixel, and the first to third subpixels for the right eye are left, center, and right in the first to third group subpixels for the right eye. The right eye first to third green subpixels are alternately arranged in the left part, and are arranged alternately in the left part, the center part, and the right part in the first to third group subpixels for the right eye. The first to third blue sub-pixels are the first to the right eye. In the third group the sub-pixels may be alternately arranged in the left portion, the central portion, the right side portion.

The present invention has the effect of preventing color separation and improving display quality of a 3D image by arranging the first to third green, blue, and blue pixels so that the average distance from the display panel to the barrier panel is the same.

1 is a plan view for explaining the operation of the parallax barrier type three-dimensional image display device.
2A and 2B show an operation in a portrait display mode and a landscape display mode of a conventional switchable three-dimensional image display device having a pivoting function, respectively.
3 is a view for explaining the color separation of the conventional switchable three-dimensional image display device.
FIG. 4 is a view illustrating a light amount distribution for each color of an image displayed by a conventional switching type 3D image display device. FIG.
5A and 5B are diagrams illustrating operations in a portrait display mode and a landscape display mode, respectively, of the switchable three-dimensional image display device according to the first embodiment of the present invention.
6 is a view for explaining color separation prevention in the switchable three-dimensional image display device according to a first embodiment of the present invention.
FIG. 7 is a view illustrating a light amount distribution for each color of an image displayed by a switchable 3D image display device according to a first embodiment of the present invention. FIG.
8A and 8B are diagrams illustrating operations in a portrait display mode and a landscape display mode, respectively, of a switchable three-dimensional image display device according to a second embodiment of the present invention.
9 is a view for explaining color separation prevention in the switchable three-dimensional image display device according to a second embodiment of the present invention.

Hereinafter, a 3D image display device and a driving method thereof according to the present invention will be described with reference to the accompanying drawings.

5A and 5B are diagrams illustrating operations in a portrait display mode and a landscape display mode of the switchable 3D image display device according to the first embodiment of the present invention, respectively.

5A and 5B, the switchable 3D image display device 210 according to the first embodiment of the present invention includes a display panel 220 for displaying a left eye image and a right eye image, and a display panel ( 220) a barrier panel 230 disposed in front to separate and transmit the left eye image and the right eye image.

Although not shown, the barrier panel 230 includes a first and a second substrate on which two corresponding electrodes are formed, and a liquid crystal layer formed between the first and second substrates, respectively.

The barrier panel 230 includes a slit 232 through which light is transmitted and a barrier 234 through which light is blocked, in a vertical display mode, a horizontal display mode, a 2D image display mode, and a 3D image display mode. The position and size of the slit 232 and the barrier 234 may be changed by voltages applied to the two electrodes.

As shown in FIG. 5A, when the switchable 3D image display device 210 according to the first exemplary embodiment of the present invention operates in the vertical display mode, the first red, green, Blue subpixels (221r, 221g, 221b), left eye 2nd blue, red, green subpixels (221b, 221r, 221g), left eye 3rd green, blue, red subpixels (223g, 223b, 223r), right eye 1st red, green, blue subpixel (225r, 225g, 225b), right 2nd blue, red, green subpixel (226b, 226r, 226g), 3rd green, blue, red subpixel for right eye , 227b and 227r have a horizontal stripe shape that is repeatedly arranged up and down alternately, and the slit 232 and barrier 234 of the barrier panel 230 have a vertical stripe shape that is repeatedly arranged left and right alternately.

As shown in FIG. 5B, when the switchable 3D image display device 210 according to the first embodiment of the present invention operates in the horizontal display mode, the first eye for the left eye of the display panel 220 may be formed as shown in FIG. Green, blue sub-pixels (221r, 221g, 221b), left eye 2 blue, red, green sub-pixels (221b, 221r, 221g), left eye 3 green, blue, red sub-pixels (223g, 223b, 223r) First red, green, blue sub-pixel for eye and right eye (225r, 225g, 225b), second blue, red, green sub-pixel for right eye (226b, 226r, 226g), third green, blue, red sub pixel for right eye The 227g, 227b, and 227r have a vertical stripe shape that is alternately arranged left and right, and the slits 232 and the barrier 234 of the barrier panel 230 have a vertical stripe shape that is alternately arranged left and right. Have

That is, in the switchable three-dimensional image display device 210 according to the first embodiment of the present invention, the left eye first group subpixel comprising the first red, green, and blue subpixels 221r, 221g, and 221b for the left eye. And the second group sub-pixel for the left eye, which is composed of the second eye blue, red, and green sub-pixels (221b, 221r, 221g) for the left eye, and the third green, blue, red sub-pixel (223g, 223b, 223r) for the left eye. The left eye third group of subpixels constitutes one left eye pixel, which is a minimum unit for displaying a left eye two-dimensional color image, and the right eye of the first eye, green, and blue subpixels 225r, 225g, and 225b for the right eye. Second group sub-pixel for right eye, consisting of first group sub-pixel for eye, second blue, red, green sub-pixel for right eye, and third green, blue, red sub-pixel for right eye (227g) And the right eye third group subpixel consisting of 227b and 227r forms one right eye pixel which is a minimum unit for displaying a right eye two-dimensional color image.

The left eye first to third group subpixels are sequentially arranged, the right eye first to third group subpixels are sequentially arranged, and the left eye pixel and the right eye pixel are alternately repeatedly arranged.

The switchable 3D image display device 210 displays the left and right eye images of the display panel 220, and the barrier panel 230 separately supplies the left and right eyes images to the left and right eyes of the viewer, thereby displaying vertically. 3D image is displayed in mode and horizontal display mode.

Here, the first to third subpixels 221r, 222r, and 223r for the left eye emit red light having the same amount of light by the same data signal, and the first to third green subpixels 221g, 222g, and 223g for the left eye. ) Emits green light having the same amount of light by the same data signal, and the first to third blue subpixels 221b, 222b, and 223b for the left eye emit blue light of the same amount by the same data signal.

Similarly, the first to third subpixels 225r, 226r, and 227r for the right eye emit the same amount of red light by the same data signal, and the first to third green subpixels for the right eye (225g, 226g, 227g). ) Emits green light having the same amount of light by the same data signal, and the first to third blue subpixels 225b, 226b, and 227b for the right eye emit blue light of the same amount by the same data signal.

In particular, the first to third red, green, and blue pixels 221r, 221g, 221b, 222r, 222g, 222b, 223r, 223g for the left eye of the display panel 220 of the switchable three-dimensional image display device 210, 223b) and the first to third red, green and blue subpixels for the right eye (225r, 225g, 225b, 226r, 226g, 226b, 227r, 227g, 227b) by adjusting the order of the barrier panel from the display panel 220. By allowing the average distance to 230 to be the same, the light amount distribution for each color felt by the viewer 240 becomes the same and color separation is prevented, which will be described with reference to the drawings.

FIG. 6 is a view for explaining color separation prevention in the switchable 3D image display device according to the first embodiment of the present invention, and FIG. 7 is a switchable 3D image display device according to the first embodiment of the present invention. Is a diagram illustrating a light amount distribution for each color of a video to be displayed.

As shown in FIG. 6, in the switchable three-dimensional image display device 210 according to the first embodiment of the present invention operating in a horizontal display mode, the first to third eyes for the left eye of the display panel 220, The left eye image IL displayed by the green and blue subpixels 221r, 221g, 221b, 222r, 222g, 222b, 223r, 223g, and 223b is displayed by the viewer 240 through the slit 232 of the barrier panel 230. The right eye image transmitted to the left eye and displayed by the first to third, green, and blue pixels 225r, 225g, 225b, 226r, 226g, 226b, 227r, 227g, and 227b for the right eye of the display panel 220. IR) is transmitted to the right eye of the viewer 240 through the slit 232 of the barrier panel 230.

Here, the first to third subpixels 221r, 222r, and 223r for the left eye are respectively the left portion of the first red, green, and blue subpixels 221r, 221g, and 221b for the left eye, second red, green, and It is arranged at the center of the blue subpixels 222r, 222g and 222b, and on the right side of the third red, green and blue subpixels 223r, 223g and 223b for the left eye.

The first to third green subpixels 221g, 222g, and 223g for the left eye are respectively the central portion of the first red, green, and blue subpixels 221r, 221g, and 221b for the left eye, and the second red, green, The right side of the blue subpixels 222r, 222g and 222b, and the left side of the third red, green and blue subpixels 223r, 223g and 223b for the left eye.

The first to third blue subpixels 221b, 222b, and 223b for the left eye are respectively the right side of the first red, green, and blue subpixels 221r, 221g, and 221b for the left eye, and the second red and green for the left eye, respectively. And the left portion of the blue subpixels 222r, 222g, and 222b, and the central portion of the third red, green, and blue subpixels 223r, 223g, and 223b for the left eye.

Accordingly, the average of the distances from the corresponding points (eg, the center) of the first to third subpixels 221r, 222r, and 223r for the left eye to the corresponding points (eg, the center) of the slit 232. (Or sum of distances) and corresponding points (eg, centers) of the slit 232 from corresponding points (eg, centers) of the first to third green subpixels 221g, 222g, and 223g for the left eye. The corresponding point of the slit 232 (eg, the center) from the average (or sum of the distances) to and the corresponding point (eg, center) of the first to third blue subpixels 221b, 222b, and 223b for the left eye. For example, the average (or sum of the distances) of the distances to the centers becomes substantially equal to each other, and as a result, the red light emitted from the first to third subpixels 221r, 222r, and 223r for the left eye, The highest value of green light emitted from the first to third green subpixels 221g, 222g and 223g for the left eye, and blue light emitted from the first to third blue subpixels 221b, 222b and 223b for the left eye. The position and amount of light distribution is the same is prevented from the color separation.

Similarly, the first to third subpixels 225r, 226r, and 227r for the right eye are respectively the left side of the first red, green, and blue subpixels 225r, 225g, and 225b for the right eye, the second red, green, Central part of blue subpixels 226r, 226g, 226b, right eye third red, green, blue subpixels 227r, 227g, 227b arranged on the right side of the first to third green subpixels 225g , 226g, 227g) are the central portion of the right eye, green, and blue subpixels 225r, 225g, and 225b for the right eye, the right side of the second red, green, blue and blue subpixels, 226r, 226g, and 226b, respectively, Right eye third red, green, and blue subpixels 227r, 227g, and 227b are arranged on the left side, and right eye first to third blue subpixels 225b, 226b, and 227b are respectively red eye first red, green , Right side of blue subpixel (225r, 225g, 225b), right eye second, green, left side of blue subpixel (226r, 226g, 226b), right side third red, green, blue subpixel (227r, 227g, 227b).

For example, the first to third red lights Lr1, Lr2, and Lr3 emitted from the first to third subpixels 225r, 226r, and 227r for the right eye may be centered based on the right eye of the viewer 240. Peaks of the first to the third green light (Lg1, Lg2, Lg3) is transmitted to be located at points c, b, a, respectively, and emitted from the first to third green sub-pixels (225g, 226g, 227g) for the right eye The first peak emitted from the first to third blue sub-pixels 225b, 226b, and 227b for the right eye is transmitted so that the peaks in the center of the viewer 240 are located at points b, a, and c, respectively. The third to third blue lights Lb1, Lb2, and Lb3 are transmitted such that peaks at the center thereof are located at points a, c, and b, respectively, based on the right eye of the viewer 240.

Accordingly, the light for each color felt by the right eye of the viewer 240 has the same position and light intensity distribution of the highest value (Lb1 + Lb2 + Lb3 = Lg1 + Lg2 + Lg3 = Lr1 + Lr2 + Lr3), and as a result, color separation. Is avoided and the display quality is improved.

That is, as shown in FIG. 7, the peak, red, green, and blue light peaks displayed by the switchable three-dimensional image display device 210 at the viewer 240 are identical to each other, and the amount of light is distributed. They are identical to each other, thereby preventing color separation and improving display quality.

In the first embodiment, the left eye sub-pixel and the right eye sub-pixel are repeatedly arranged in the color order of red, green, blue, blue, red, green, green, blue, and red (rgbbrggbr). In the example, red, green, blue, green, blue, red, blue, red, green (rgbgbrbrg) is arranged repeatedly, red, blue, green, green, red, blue, blue, green, red (rbggrbbgr) The arrangement order may be repeated. In this arrangement order, the average (or sum of the distances) of the distances from the first to third group subpixels of the left eye pixel and the right eye pixel to the barrier panel 230 is small and green. However, various changes may be made to the extent that they are substantially the same for each blue color.

The first to third red, green and blue sub-pixels 221r, 221g, 221b, 222r, 222g, 222b, 223r, 223g, and 223b for the left eye formed on the display panel 220 and the first to third eyes for the right eye Red, green, blue and blue pixels (225r, 225g, 225b, 226r, 226g, 226b, 227r, 227g, 227b) width (P), barrier panel (234) width (M) of barrier panel 230, barrier panel The width Q of the slit 232 of 230, the width E between the left and right eyes, the distance S from the display panel 220 to the barrier panel 230, and the viewer (from the barrier panel 230). The distance D to 240 may be set to satisfy the following equation.

M + Q = 2 / (1 / E + 1 / P)

D = SE / P

Meanwhile, in another embodiment, the left eye subpixel and the right eye subpixel may be alternately arranged, which will be described with reference to the drawings.

8A and 8B are diagrams illustrating operations in a portrait display mode and a landscape display mode of the switchable 3D image display device according to a second embodiment of the present invention, respectively.

As shown in FIG. 8A, when the switchable 3D image display device 310 according to the second exemplary embodiment of the present invention operates in the vertical display mode, the first red, green, Blue subpixels (321r, 321g, 321b), right eye first, green, blue subpixels (325r, 325g, 325b), second blue eye for left eye, red, green subpixels (321b, 321r, 321g), right eye Second Blue, Red, Green Sub-pixel (326b, 326r, 326g), Third Green, Blue, Red Sub-pixel (323g, 323b, 323r) for Left Eye, Third Green, Blue, Red Sub-pixel for Right Eye (327g) , 327b and 327r have a horizontal stripe shape that is repeatedly arranged up and down alternately, and the slit 332 and barrier 234 of the barrier panel 330 have a vertical stripe shape that is repeatedly arranged left and right alternately.

As shown in FIG. 8B, when the switchable 3D image display device 310 according to the second embodiment of the present invention operates in the horizontal display mode, the first eye for the left eye of the display panel 320, Green, blue subpixels (321r, 321g, 321b), right eye first, green, blue subpixels (325r, 325g, 325b), second blue for left eye, red, green subpixels (321b, 321r, 321g) , Right eye 2 blue, red, green sub-pixel (326b, 326r, 326g), left eye 3 green, blue, red sub-pixel (323g, 323b, 323r), right eye 3 green, blue, red sub-pixel The 327g, 327b, and 327r have vertical stripe shapes that are alternately arranged left and right, and the slit 332 and barrier 334 of the barrier panel 330 have vertical stripe shapes that are alternately arranged left and right. Have

That is, in the switchable three-dimensional image display apparatus 310 according to the second embodiment of the present invention, the left eye first group subpixel comprising the first red, green, and blue subpixels 321r, 321g, and 321b for the left eye. And a second group subpixel for the left eye consisting of the second blue, red, and green subpixels 321b, 321r, and 321g for the left eye, and the third green, blue, and red subpixels for the left eye (323g, 323b, and 323r). The left eye third group of subpixels constitutes one left eye pixel, which is a minimum unit for displaying a left eye two-dimensional color image, and the right eye of the first eye, green, and blue subpixels 325r, 325g, and 325b for the right eye. The first group sub-pixel for right eye, the second group sub-pixel for right eye consisting of second blue, red and green sub-pixel for right eye, and the third green, blue and red sub-pixel for right eye (327 g) And the right eye third group of subpixels 327b and 327r form one right eye pixel, which is a minimum unit for displaying a right eye two-dimensional color image.

The first group subpixel for the left eye, the first group subpixel for the right eye, the second group subpixel for the left eye, the second group subpixel for the right eye, the third group subpixel for the left eye, and the third group subpixel for the right eye It is arranged repeatedly sequentially.

The switchable three-dimensional image display device 310 displays the left and right eye images of the display panel 320, and the barrier panel 330 separately supplies the left and right eye images to the left and right eyes of the viewer, thereby displaying vertically. 3D image is displayed in mode and horizontal display mode.

Here, the first to third subpixels 321r, 322r, and 323r for the left eye emit red light having the same amount of light by the same data signal, and the first to third green subpixels 321g, 322g, and 323g for the left eye. ) Emits green light having the same amount of light by the same data signal, and the first to third blue subpixels 321b, 322b, and 323b for the left eye emit blue light of the same amount by the same data signal.

Similarly, the first to third subpixels 325r, 326r and 327r for the right eye emit red light having the same amount of light by the same data signal, and the first to third green subpixels 325g, 326g and 327g for the right eye. ) Emits green light having the same amount of light by the same data signal, and the first to third blue subpixels 325b, 326b and 327b for the right eye emit blue light of the same amount by the same data signal.

In particular, the first to third red, green, and blue pixels 321r, 321g, 321b, 322r, 322g, 322b, 323r, 323g for the left eye of the display panel 320 of the switchable three-dimensional image display device 310, 323b) and barrier panels from the display panel 320 by adjusting the arrangement order of the first to third red, green and blue subpixels 325r, 325g, 325b, 326r, 326g, 326b, 327r, 327g, and 327b for the right eye. By making the average distance to 330 the same, the light amount distribution for each color felt by the viewer 340 becomes the same and color separation is prevented, which will be described with reference to the drawings.

9 is a view for explaining color separation prevention in the switchable three-dimensional image display device according to a second embodiment of the present invention.

As shown in FIG. 9, in the switchable three-dimensional image display device 310 according to the second embodiment of the present invention operating in a horizontal display mode, the first to third eyes of the display panel 320 are provided. The left eye image IL displayed by the green and blue subpixels 321r, 321g, 321b, 322r, 322g, 322b, 323r, 323g, and 323b is displayed by the viewer 340 through the slit 332 of the barrier panel 330. The right eye image transmitted to the left eye and displayed by the first to third, green, and blue pixels 325r, 325g, 325b, 326r, 326g, 326b, 327r, 327g, and 327b for the right eye of the display panel 320. IR is transmitted to the right eye of the viewer 340 through the slit 332 of the barrier panel 330.

Here, the first to third subpixels 321r, 322r, and 323r for the left eye are respectively the left portion of the first red, green, and blue subpixels 321r, 321g, and 321b for the left eye, and the second red, green, and It is arranged in the center of the blue subpixels 322r, 322g, 322b, and on the right side of the third red, green, blue subpixels 323r, 323g, 323b for the left eye.

The first to third green subpixels 321g, 322g, and 323g for the left eye are respectively the central portion of the first red, green, and blue subpixels 321r, 321g, and 321b for the left eye, and the second red, green, The right side of the blue subpixels 322r, 322g, 322b, and the left side of the third red, green, blue subpixels 323r, 323g, 323b for the left eye.

The first to third blue subpixels 321b, 322b, and 323b for the left eye are respectively the right side of the first red, green, and blue subpixels 321r, 321g, and 321b for the left eye, and the second red, green for the left eye, respectively. And the left portion of the blue subpixels 322r, 322g, and 322b, and the central portion of the third red, green, and blue subpixels 323r, 323g, and 323b for the left eye.

Accordingly, the average (or sum of the distances) of the distances from the first to third subpixels 321r, 322r, and 323r for the left eye to the slit 332, and the first to third green subpixels for the left eye 321g. , 322g, 323g, the average (or sum of the distances) of the distance from the slit 332, and the average of the distances from the first to third blue subpixels 321b, 322b, 323b for the left eye to the slit 332. (Or sum of distances) become equal to each other, and as a result, red light emitted from the first to third subpixels 321r, 322r, and 323r for the left eye, and the first to third green subpixels for the left eye 321g. , 322g, 323g) of green light emitted from the left eye and blue light emitted from the first to third blue subpixels 321b, 322b, and 323b for the left eye have the same position and light quantity distribution, thereby preventing color separation. .

Similarly, the first to third subpixels 325r, 326r, and 327r for the right eye are respectively the left side of the first red, green, and blue subpixels 325r, 325g, and 325b for the right eye, the second red, green, Central part of blue subpixels 326r, 326g and 326b, right eye third, green and blue subpixels 327r, 327g and 327b are arranged on the right side, and right to third green subpixels 325g for right eye , 326g, 327g) are the central portion of the right eye, green, and blue subpixels 325r, 325g, and 325b for the right eye, and the right side of the second red, green, blue and blue subpixels, 326r, 326g, and 326b for the right eye, The right eye third red, green and blue subpixels 327r, 327g, and 327b are arranged on the left side, and the right eye first to third blue subpixels 325b, 326b, and 327b, respectively, for the right eye first red, green , Right side of blue subpixel 325r, 325g, 325b, right eye second, green, left side of blue subpixel 326r, 326g, 326b, third red, green, blue subpixel 327r, 327g, 327b).

For example, the first to third red lights Lr1, Lr2, and Lr3 emitted from the first to third subpixels 325r, 326r, and 327r for the right eye are centered on the right eye of the viewer 340. Peaks of the first to third green light (Lg1, Lg2, Lg3) is transmitted to be located at points c, b, a, respectively, and emitted from the first to third green sub-pixels (325g, 326g, 327g) for the right eye The first peak emitted from the first to third blue sub-pixels 325b, 326b, and 327b for the right eye is transmitted so that the peaks in the center thereof are located at points b, a, and c, respectively, based on the right eye of the viewer 340. The third to third blue lights Lb1, Lb2, and Lb3 are transmitted such that peaks at the center thereof are located at points a, c, and b, respectively, based on the right eye of the viewer 340.

Accordingly, the light for each color felt by the right eye of the viewer 340 has the same position and light intensity distribution of the highest value (Lb1 + Lb2 + Lb3 = Lg1 + Lg2 + Lg3 = Lr1 + Lr2 + Lr3), and as a result, color separation. Is avoided and the display quality is improved.

In the second embodiment, the left eye subpixel and the right eye subpixel are exemplarily arranged in the order of red, green, blue, blue, red, green, green, blue, and red (rgbbrggbr), respectively. In FIG. 5, the arrangement order may be variously changed within a limit in which the average (or sum of distances) of the distances from the subpixels to the barrier panel 330 is the same for each color.

The first to third red, green, and blue pixels 321r, 321g, 321b, 322r, 322g, 322b, 323r, 323g, and 323b for the left eye formed on the display panel 320 and the first to third eyes for the right eye Red, green, blue and blue pixels (325r, 325g, 325b, 326r, 326g, 326b, 327r, 327g, 327b) width (P) of each barrier (330) of barrier panel (330) (M), barrier The width Q of the slit 332 of the panel 330, the width E between the left and right eyes, the distance S from the display panel 320 to the barrier panel 330, and the viewer from the barrier panel 330. The distance D to 340 may be set to satisfy the following equation.

M + Q = 2 / (1 / E + 1 / P)

D = SE / P

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

210: 3D image display device 220: display panel
230: barrier panel
221r, 221g, 221b: first red, green, blue subpixel for left eye
222r, 222g, 222b: secondary red, green, blue subpixel for left eye
223r, 223g, 223b: third eye, green, blue subpixel for left eye
225r, 225g, 225b: first red, green, blue
226r, 226g, 226b: second eye, green, blue
227r, 227g, 227b: Third eye for right eye, green, blue subpixel

Claims (10)

The left eye first group sub-pixel consisting of the first, green, and blue sub-pixels for the left eye, and the second group sub-pixel for the left eye, consisting of the second, green, and blue sub-pixels for the left eye. The left eye pixel consists of a third group subpixel for the left eye consisting of a third, green, and blue subpixel, and the first group part for the right eye, consisting of a first red, green, and blue subpixel for displaying a right eye image. Right eye pixel consisting of pixels, right eye second group subpixel consisting of second, green, and blue subpixels for right eye, and right eye third group subpixel consisting of third, green, and blue subpixels for right eye A display panel comprising a;
The barrier panel is disposed in front of the display panel and separates the left eye image and the right eye image and transfers them to the left eye and the right eye, respectively.
Including,
The first to third subpixels for the left eye are alternately arranged in the left part, the center part, and the right part in the first to third group subpixels for the left eye, respectively, and for the first to third subpixels for the left eye. The same left eye red data signal is applied,
The first to third green sub-pixels for the left eye are alternately arranged in the center part, the right part, and the left part in the first to third group sub-pixels for the left eye, respectively. The same left eye green data signal is applied to the subpixel,
The first to third blue subpixels for the left eye are alternately arranged in the right, left, and center portions of the first to third group subpixels for the left eye, respectively. The same left eye blue data signal is applied to the subpixel,
The red light of the first to third subpixels for the left eye, the green light of the first to third green subpixels for the left eye, and the first to the third blue subpixels for the left eye, which the viewer's left eye feels. 3D image display device wherein the position of the highest value of blue light and the amount of light distribution are the same.
The method of claim 1,
The first to third sub-pixels for the right eye are alternately arranged in the left, middle, and right portions in the first to third group subpixels for the right eye, respectively.
The first to third green sub-pixels for the right eye are alternately arranged in the center part, the right part, and the left part in the first to third group subpixels for the right eye, respectively.
The first to third blue subpixels for the right eye are alternately arranged in the right, left, and center portions of the first to third group subpixels for the right eye, respectively.
The method of claim 2,
The same right eye red data signal is applied to the first to third subpixels for the right eye, and the same right green data signal is applied to the first to third green subpixels for the right eye, and the first to third subpixels for the right eye are applied. The same right eye blue data signal is applied to the third sub-pixel.
The red light of the first to third subpixels for the right eye, the green light of the first to third green subpixels for the right eye, and the first to the third blue subpixels for the right eye, felt by the viewer's right eye. 3D image display device wherein the position and light quantity distribution of the highest value of blue light are the same.
The method of claim 1,
The first group subpixel for the left eye, the second group subpixel for the left eye, the third group subpixel for the left eye, the first group subpixel for the right eye, the second group subpixel for the right eye, and the third for the right eye The group subpixels are sequentially arranged repeatedly.
The method of claim 4, wherein
The first red, green, blue sub-pixel for the left eye, the second blue, red, green sub-pixel for the left eye, the third green, blue, red sub-pixel for the left eye, the first red, green, blue for the right eye And a pixel, the right eye second blue, red and green sub-pixels, and the right eye third green, blue and red sub-pixels are sequentially arranged.
The method of claim 1,
The first group subpixel for the left eye, the first group subpixel for the right eye, the second group subpixel for the left eye, the second group subpixel for the right eye, the third group subpixel for the left eye, the third for the right eye The group subpixels are sequentially arranged repeatedly.
The method of claim 6,
The first red, green, blue sub-pixel for the left eye, the first red, green, blue sub-pixel for the right eye, the second blue for the left eye, red, the green sub-pixel, the second blue for the right eye, red, green And a pixel, the left eye third green, blue, and red subpixels, and the right eye third green, blue, and red subpixels are sequentially arranged.
The method of claim 1,
The barrier panel includes a slit through which light is transmitted and a barrier through which light is blocked, and the position and size of the slit and the barrier are in a vertical display mode, a horizontal display mode, a 2D image display mode, and a 3D image display mode. 3D image display device changed according to.
The same left eye red data signal is applied to the left-eye first to third sub-pixels arranged alternately in the left, middle, and right portions of the left-eye first to third group subpixels that constitute the left-eye pixel of the display panel. The same left eye green data signal is applied to the left eye first to third green subpixels alternately arranged in the center portion, the right side portion, and the left side portion in the left eye first to third group subpixels, respectively. The same left eye blue data signal is applied to the left eye first to third blue subpixels alternately arranged in the right, left, and center portions of the first to third group subpixels for the left eye. Displaying;
The same right eye red data signal is applied to the right eye first to third subpixels of the right eye first to third group subpixels constituting the right eye pixel of the display panel, and the first to third group for the right eye The same right eye green data signal is applied to the first to third green subpixels for the right eye of the subpixel, and the same right eye to the first to third blue subpixels for the right eye of the first to third group subpixels for the right eye. Displaying a right eye image by applying a blue data signal;
Separating the left eye image and the right eye image by a barrier panel and transferring the left eye image and the right eye image to the left eye and the right eye, respectively
Including,
The red light of the first to third subpixels for the left eye, the green light of the first to third green subpixels for the left eye, and the first to the third blue subpixels for the left eye, which the viewer's left eye feels. A method of driving a 3D image display device, wherein positions of the highest value of blue light and distribution of light amount are the same.
The method of claim 9,
The first to third subpixels for the right eye are alternately arranged in the left, center, and right portions in the first to third group subpixels for the right eye, respectively.
The first to third green sub-pixels for the right eye are alternately arranged in the center part, the right part, and the left part in the first to third group subpixels for the right eye, respectively.
The first to third blue subpixels for the right eye are alternately arranged in the right, left and center portions in the first to third group subpixels for the right eye,
The red light of the first to third subpixels for the right eye, the green light of the first to third green subpixels for the right eye, and the first to the third blue subpixels for the right eye, felt by the viewer's right eye. A method of driving a three-dimensional image display device wherein the position and light quantity distribution of the highest value of blue light are the same.

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