KR101904472B1 - Stereoscopic image display - Google Patents

Abstract

The present invention relates to a stereoscopic image display device, and includes a 3D filter bonded on a display panel. Pixels of the display panel are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written. The left eye subpixels include two subpixels, one of which includes green subpixels in the first subframe period and the white subpixels in the second subframe period. The right subpixels include two subpixels, one of which includes the white subpixel in the first subframe period and the green subpixel in the second subframe period.

Description

[0001] STEREOSCOPIC IMAGE DISPLAY [0002]

The present invention relates to a stereoscopic image display device.

The stereoscopic image display device can be divided into a spectacle method and a non-spectacle method. The spectacle method realizes a stereoscopic image by using polarizing glasses or liquid crystal shutter glasses by changing the polarization direction of the right and left parallax images to a direct view type display device or projector and displaying them in a time division manner. Such as a parallax barrier or a lenticular lens, for separating the stereoscopic image, is installed in front of or behind the display screen to realize a stereoscopic image.

In such a stereoscopic image display apparatus, there may be luminance differences between pixels viewed through the left eye and pixels viewed through the right eye according to the colors of the pixels when the pixels viewed by the left eye and the right eye are different. If the luminance of the pixels viewed through the left eye and the luminance difference of the pixels viewed through the right eye are large, the viewer feels flicker and crosstalk, and feel fatigue even if the viewing time is short.

For example, a pixel of the display panel can be divided into a red subpixel R, a green subpixel G, a blue subpixel B and a white subpixel W. [ The non-eyeglass stereoscopic image display device can connect a 3D filter such as a parallax barrier or a lenticular lens on a display panel to separate pixels viewed as a left eye and pixels seen as a right eye through the 3D filter. Pixels seen in a monocular (left eye or right eye) include green subpixels and white subpixels having relatively high luminance ratios, and pixels showing another monocular (right eye or left eye) include red subpixels having a relatively low luminance ratio and blue And may include subpixels. In this case, the luminance of the pixels viewed through the left eye may be higher than the luminance of the pixels seen through the right eye.

The present invention provides a stereoscopic image display device capable of reducing a luminance difference between left eye subpixels and right eye subpixels.

A stereoscopic image display device according to an exemplary embodiment of the present invention includes: a display panel having pixels intersecting with data lines and scan lines; And a 3D filter bonded on the display panel. The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written. The left eye subpixels include two subpixels, one of which includes green subpixels in the first subframe period and the white subpixels in the second subframe period. The right subpixels include two subpixels, one of which includes the white subpixel in the first subframe period and the green subpixel in the second subframe period.

According to another aspect of the present invention, there is provided a stereoscopic image display device including: a display panel including pixels intersecting data lines and scan lines; And a 3D filter bonded on the display panel. The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written. The left eye subpixels include two subpixels, one of which includes a first green subpixel in a first subframe period and a second green subpixel in a second subframe period. The right subpixels include two subpixels, one of which includes the second green subpixel in the first subframe period and the first green subpixel in the second subframe period.

According to another aspect of the present invention, there is provided a stereoscopic image display device including: a display panel including pixels intersecting data lines and scan lines; And a 3D filter bonded on the display panel. The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written. The left eye subpixels include two subpixels, one of which includes green subpixels in the first subframe period and the yellow subpixels in the second subframe period. The right subpixels include two subpixels, one of which includes the yellow subpixel in the first subframe period and the green subpixel in the second subframe period.

According to another aspect of the present invention, there is provided a stereoscopic image display device including: a display panel including pixels intersecting data lines and scan lines; And a 3D filter bonded on the display panel. The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written. The left eye subpixels are arranged in the first line of the display panel and include white subpixels. The right subpixels are arranged in a second line below the first line in the display panel and include green subpixels.

The present invention distributes subpixels having a relatively high luminance ratio and subpixels having a relatively low luminance ratio relative to left eye subpixels and right eye subpixels. As a result, the present invention can reduce the luminance difference between the left sub-pixels and the right sub-pixels in the stereoscopic image display device, thereby improving flicker and crosstalk felt by the viewer.

1 is a diagram showing an example of a large luminance ratio of subpixels viewed through the left eye and subpixels viewed through the right eye.
2 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a first embodiment of the present invention.
3 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a second embodiment of the present invention.
4 is a diagram showing an example of a shift of a switchable barrier and pixel data.
5 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a third embodiment of the present invention.
6 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a fourth embodiment of the present invention.
7 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a fifth embodiment of the present invention.
8 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a sixth embodiment of the present invention.
9 is a diagram illustrating an example of driving a liquid crystal display element in a 2D mode and a 3D mode using a one-dot inversion method.
10 is a diagram illustrating an example of a dot inversion method applied to a 2D mode and a dot inversion method applied to a 3D mode in a stereoscopic image display apparatus according to an embodiment of the present invention.
FIG. 11 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 10 is applied to the stereoscopic image display apparatus as shown in FIG.
12 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 10 is applied to the stereoscopic image display apparatus as shown in FIG.
13 is a diagram illustrating another example of a dot inversion method applied to a 2D mode and a dot inversion method applied to a 3D mode in a stereoscopic image display device according to an embodiment of the present invention.
FIG. 14 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 13 is applied to the stereoscopic image display apparatus as shown in FIG.
15 is a block diagram illustrating a display panel driver and a 3D filter driver in a stereoscopic image display apparatus according to an exemplary embodiment of the present invention.
16 is a cross-sectional view showing a lenticular lens film or a switchable lens.
17 is a sectional view showing a parallax barrier or a switchable barrier.
18 is a view showing a pattern retarder and polarizing glasses.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Like reference numerals throughout the specification denote substantially identical components. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The display device of the present invention can be applied to a liquid crystal display (LCD), a field emission display (FED), a plasma display panel (PDP), an organic light emitting display , OLEDs, and electrophoresis (EPD) devices. In the following embodiments, a display device is described as a liquid crystal display device as an example of a flat panel display device, but it should be noted that the display device of the present invention is not limited to a liquid crystal display device.

In the display device of the present invention, the pixels include a plurality of sub-pixels. The subpixels are separated into subpixels visible through the viewer's left eye by the 3D filter and subpixels visible through the viewer's right eye.

Pixels are displayed with 2D image data in 2D mode. The polarity of the data voltage supplied to the pixels through the data lines in the 2D mode can be reversed by the version method with a one dot. The left eye image data and the right eye image data are spatially divided and displayed in the 3D mode in the pixels. The polarity of the data voltage supplied to the pixels through the data lines in the 3D mode can be reversed by the version method with 2 dots.

The 3D filter of the present invention is bonded to a display panel of a flat panel display device. A 3D filter is an optical component that separates subpixels viewed through the viewer's left eye and subpixels viewed through the right eye. The 3D filter may be a 3D filter used in a stereoscopic image display apparatus such as a parallax barrier or a lenticular lens, or a 3D filter used in a stereoscopic image display apparatus such as a pattern retarder. The parallax barrier and the lenticular lens can be realized by a switchable barrier or a switchable lens that is electrically controlled using a liquid crystal panel. The applicant of the present application has proposed a switchable barrier and a switchable lens through US Application No. 13/077565, US Application No. 13/325272, Application No. 10-2010-0030531, and Application No. 10-2010-0130547, etc. The switchable barrier or the switchable lens may be electronically controlled and shifted by a predetermined time unit, and the shift interval may be a sub-pixel pitch of n (n is a positive integer of 1 or more) .

The subpixels have different luminance ratios in the pixels depending on their colors. The present invention places subpixels such that the difference in luminance between the subpixels viewed through the viewer's left eye and the subpixels viewed through the viewer's right eye is small.

1 is a diagram showing an example of a large luminance ratio of subpixels viewed through the left eye and subpixels viewed through the right eye.

Referring to FIG. 1, the stereoscopic image display apparatus includes a display panel PNL and a 3D filter (BAR, LENTI) bonded on the display panel PNL.

The display panel (PNL) includes a pixel array for displaying 2D image data in 2D mode and displaying 3D image data in 3D mode. The pixel array includes data lines to which a data voltage (or current) is supplied, scan lines that are sequentially crossed with the data lines and scan pulses (or gate pulses), and data lines and gate lines And pixels formed per pixel region. Each of the pixels may comprise a red subpixel R, a green subpixel G, a blue subpixel B and a white subpixel W. The 3D filter can be selected from any one of a switchable barrier (BAR) and a switchable lens (LENTI). One frame period of such a stereoscopic image display apparatus may be time-divided into first and second sub frame periods F (n) and F (n + 1).

1, the viewer sees the green subpixel G and the white subpixel W through the left eye during the first sub frame period F (n), and the red subpixel G (R) and a blue sub-pixel (B). The luminance ratio of the subpixels may be approximately R: G: B: W = 0.1495: 0.2935: 0.057: 0.5. The viewer feels the luminance of the pixels viewed through the left eye to be higher than the luminance of the pixels viewed through the right eye during the first sub frame period F (n).

Data written to the 3D filter and / or pixels is shifted by one sub-pixel in the second sub frame period F (n + 1). The viewer sees the red subpixel R and the blue subpixel B through the left eye during the second sub frame period F (n + 1), and the green subpixel G and the white subpixel G W). The viewer feels the luminance of the pixels viewed through the right eye to be higher than the luminance of the pixels viewed through the left eye during the second sub frame period F (n + 1). When the frame rate of the stereoscopic image display device is 120 Hz and the subpixels are arranged as shown in FIG. 1, the viewer feels 60 Hz flicker whose luminance varies at a frequency of 60 Hz in each of the left eye and right eye, You can feel 3D crosstalk overlapping images.

In order to reduce the luminance of the subpixels viewed through the left eye and the luminance difference of the subpixels seen through the right eye when the 3D image is displayed on the stereoscopic image display device, the subpixels are arranged in the manner as shown in FIGS.

2 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a first embodiment of the present invention.

Referring to FIG. 2, each of the pixels includes subpixels (hereinafter referred to as " left subpixels ") to which left eye image data is written, and subpixels ). Each of the pixels may comprise four sub-pixels.

Left eye subpixels and right eye subpixels are segmented by a 3D filter (BAR, LENTI). In Fig. 2, the "left eye recognition image" is the left eye subpixels viewed through the viewer's left eye, and the "right eye recognition image" is the right eye subpixels visible through the viewer's right eye. The 3D filters BAR and LENTI match the path of light emitted from the left eye subpixels with the left eye of the viewer and match the path of the light emitted from the right eye subpixels with the viewer's right eye.

Each of the left eye subpixels and the right eye subpixels may be divided into two row lines in a pixel array of the display panel PNL as shown in FIG. The viewer sees only the left subpixels through the left eye, and only the right subpixels are viewed through the right eye, so that a stereoscopic image can be viewed with a binocular disparity.

Left eye subpixels and right eye subpixels are separated according to the slit or lens direction of the 3D filter (BAR, LENTI). An example is assumed in which a slit or lens direction of the 3D filters BAR and LENTI is formed along a column line of the display panel PNL. In this case, the left subpixels are divided into a green subpixel G and a blue subpixel B (n) arranged along the odd column line of the display panel PNL during the first sub frame period F (n) ). The right subpixels include a red subpixel R and a white subpixel W arranged along the odd column line of the display panel PNL for the first sub frame period F (n). The subpixels G and W with relatively high luminance ratios and the subpixels R and B with relatively low luminance ratios during the first sub frame period F (n) Are evenly distributed over the pixels.

Data written to the 3D filter and / or pixels is shifted by one sub-pixel in the second sub frame period F (n + 1). 2, the red subpixel R and the white subpixel W (n + 1) arranged along the odd-numbered column line of the display panel PNL during the second subframe period F (n + ). Right subpixels include a green subpixel G and a blue subpixel B arranged along the even column line of the display panel PNL during the second sub frame period F (n + 1). The subpixels G and W with relatively high luminance ratios and the subpixels R and B with relatively low luminance ratios during the second sub frame period F (n + 1) And is evenly distributed to the right subpixels. Therefore, the viewer hardly senses the difference in luminance between the left-eye subpixels viewed through the left eye and the right-eye subpixels viewed through the right eye during the first and second subframe periods F (n) and F (n + 1) 3D images can be viewed without flicker and 3D crosstalk.

The left eye subpixels and the right eye subpixels are separated according to the slit or lens direction of the 3D filter (BAR, LENTI) as described above. For example, when the slit or lens direction of the 3D filter (BAR, LENTI) is formed along the diagonal direction of the display panel (PNL), the left eye subpixels and right eye subpixels are separated along the oblique direction.

3 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a second embodiment of the present invention.

Referring to FIG. 3, each of the pixels includes left eye subpixels and right eye subpixels. Left eye subpixels and right eye subpixels are segmented by a 3D filter (BAR, LENTI). Left eye subpixels and right eye subpixels may be arranged along one row line in the pixel array of the display panel PNL as shown in FIG. The viewer sees only the left subpixels through the left eye, and only the right subpixels are viewed through the right eye, so that a stereoscopic image can be viewed with a binocular disparity.

Left eye subpixels and right eye subpixels can be separated according to the slit or lens direction of the 3D filter (BAR, LENTI). The left eye subpixels include left and right blue subpixels B and white subpixels W for the first subframe period F (n) as shown in FIG. And the white subpixel W may be disposed on the right side of the blue subpixel B. [ The right subpixels include a red subpixel R and a green subpixel G neighboring left and right for the first sub frame period F (n). The green subpixel G may be disposed between the blue subpixel B and the red subpixel R and the red subpixel R may be disposed on the left side of the green subpixel G. [ The subpixels G and W with relatively high luminance ratios and the subpixels R and B with relatively low luminance ratios during the first sub frame period F (n) Are evenly distributed over the pixels.

The data (pixel data) written to the 3D filter and / or pixels is shifted by two sub-pixels in the second sub frame period F (n + 1). Then, the left subpixels include red subpixels R and green subpixels G during the second subframe period F (n + 1) as shown in FIG. The right subpixels include the blue subpixel B and the white subpixel W during the second subframe period F (n + 1). The subpixels G and W with relatively high luminance ratios and the subpixels R and B with relatively low luminance ratios during the second sub frame period F (n + 1) And is evenly distributed to the right subpixels. Therefore, the viewer hardly senses the difference in luminance between the left-eye subpixels viewed through the left eye and the right-eye subpixels viewed through the right eye during the first and second subframe periods F (n) and F (n + 1) 3D images can be viewed without flicker and 3D crosstalk.

In FIG. 3, the subframe periods may be interchanged. For example, the left-eye subpixels include the red subpixel R and the green subpixel G for the first subframe period F (n) and the blue subpixel R (n) for the second subframe period F (B) and a white sub-pixel (W). And the right subpixels include the blue subpixel B and the white subpixel W during the first subframe period F (n) and the red subpixel B during the second subframe period F (n + 1) And may include a pixel R and a green subpixel G. [

FIG. 4 is a diagram illustrating an example of a shift of a switchable barrier (BAR) and pixel data in a stereoscopic image display apparatus of a non-eyeglass system having pixels as shown in FIG.

Referring to FIG. 4, the pixel data written in the pixel array of the display panel PNL and the switchable barrier (BAR) may be shifted in opposite directions every frame period. In Fig. 4, "F (n) and F (n + 1)" are first and second subframe periods time-divided in the first frame period, and "F And a first sub frame period among the first and second sub frame periods. "OR1, OR2, OR3" are the left eye subpixels in which the left eye image data is written in the first sub frame periods F (n) and F (n + 2) Right subpixels in which right eye image data is written in the first sub frame periods F (n) and F (n + 2) every frame period. Quot; EL1, EL2, and EL3 "are left-eye subpixels in which the left eye image data is written in the second sub frame period F (n + 1) Right subpixels in which right eye image data is written in two sub frame periods F (n + 1).

In the case of FIG. 4, the left-eye subpixels include a red subpixel R and a green subpixel G neighboring to the left and right for the first sub-frame period F (n) of the first frame period. The right subpixels include a blue subpixel B and a white subpixel W that are adjacent to the right and left sides during the first sub frame period F (n) of the first frame period.

In the second sub frame period F (n + 1), the switchable barrier (BAR) and the pixel data are shifted in opposite directions. As a result, the left-eye subpixels include the blue subpixel B and the white subpixel W, which are adjacent to the right and left in the second sub-frame period F (n + 1) of the first frame period. Right subpixels include a red subpixel R and a green subpixel G neighboring to the right and left sides during the second sub frame period F (n + 1) of the first frame period.

The switchable barrier BAR and the pixel data are shifted in the opposite directions in the first sub frame period F (n + 2) of the second frame period. As a result, the left-eye subpixels include the red subpixel R and the green subpixel G, which are adjacent to each other for the first sub-frame period F (n + 2) of the second frame period. Right subpixels include blue subpixels B and white subpixels W that are adjacent to the right and left sides during the second sub frame period F (n + 2) of the second frame period.

The 3D filter can be implemented as a pattern retader in a stereoscopic image display device of a glasses system. The pattern retarder makes the polarization of the left eye image written in the left eye subpixels displayed on the display panel different from that of the right eye image written in the right eye subpixels. For example, the light of the left eye image displayed on the left eye subpixels passes through the first retarder of the pattern retarder, its phase is delayed and its polarization characteristic becomes the first polarized light. On the other hand, the light of the right eye image displayed on the right subpixels passes through the second retarder of the pattern retarder, and its phase is delayed, and its polarization characteristic becomes the second polarized light. The optical axes of the first and second retarders of the pattern retarder can be orthogonal to each other. The left eye polarizing filter of the polarizing glasses transmits only the first polarized light and the right eye polarizing filter of the polarizing glasses transmits only the second polarized light. When viewing a stereoscopic image in a stereoscopic image display apparatus using a polarizing glasses system, the viewer wears polarizing glasses to see the left eye sub-pixels through the left eye polarizing filter of the polarizing glasses, and the right eye polarizing filter of the polarizing glasses So that a three-dimensional feeling can be felt.

The pattern retarder (PR) consists of a glass patterned retarder (GPR) on which a pattern retarder is formed on a glass substrate and a film patterned retarder (FPR) on which a pattern retarder is formed on the film substrate Is divided. In recent years, a film pattern retarder (FPR) that can reduce the thickness, weight, and price of a display panel compared to a glass pattern retarder is preferred.

5 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a third embodiment of the present invention.

Referring to Fig. 5, the pattern retarder PR is bonded onto the display panel PNL. The pattern retarder PR includes a first retarder PR1 facing the odd-numbered lines in the pixel array of the display panel PNL and a second retarder PR1 opposed to odd-numbered lines in the pixel array of the display panel PNL. And a retarder PR2. Left-eye subpixels are arranged in the odd-numbered lines of the pixel array, and right-eye subpixels are arranged in the even-th lines.

The left eye polarizing filter of the polarizing glasses not shown passes only the first polarized light of the left eye image displayed on the left eye subpixels disposed on the odd-numbered lines of the pixel array. The right eye polarizing filter of the polarizing glasses passes only the second polarized light of the right eye image displayed on right eye subpixels disposed on the even lines of the pixel array. In order to reduce the luminance of the left eye subpixels and the luminance difference of right eye subpixels, the left eye subpixels are composed of red subpixels R and white subpixels W as shown in FIG. 5, ) And a blue sub-pixel (B). Alternatively, the left eye subpixels may be composed of a red subpixel R and the green subpixel G, and the right eye subpixels may be composed of a blue subpixel B and a white subpixel W. [

5, the subpixels G and W having relatively high luminance ratios and the subpixels R and B having relatively low luminance ratios are used for the left eye subpixels and the right eye subpixels R, . Accordingly, the viewer can hardly sense the difference in luminance between the left eye subpixels viewed through the left eye polarizing filter and the right eye subpixels viewed through the right eye polarizing filter, so that a stereoscopic image can be appreciated without flicker and 3D crosstalk.

The colors of the sub-pixels constituting the pixel are not limited to red, green and blue. For example, the pixel may be composed of cyan, magenta and yellow sub-pixels as shown in FIGS. 6 to 8, or may be composed of one or more sub-pixels of the sub- , Green (Green), and blue (Blue).

6 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a fourth embodiment of the present invention.

Referring to FIG. 6, each of the pixels may include one cyan sub-filter C, one magenta sub-filter M, and two yellow sub-pixels Y. In this case, when the luminance within one pixel is 1, the luminance ratio of the sub-pixels may be approximately C: M: Y: Y = 0.243: 0.146: 0.305: 0.305.

In each of the pixels, the left-eye subpixels and the right-eye subpixels are divided by a 3D filter (BAR, LENTI). Each of the left eye subpixels and the right eye subpixels may be divided into two row lines in a pixel array of the display panel PNL as shown in FIG. The viewer sees only the left subpixels through the left eye, and only the right subpixels are viewed through the right eye, so that a stereoscopic image can be viewed with a binocular disparity.

An example is assumed in which a slit or lens direction of the 3D filter (BAR, LENTI) is formed along the column line of the display panel (PNL). In this case, the left subpixels are divided into the magenta sub-filter M arranged along the odd-numbered column line of the display panel PNL for the first sub-frame period F (n) and the first yellow sub- (Y). Right subpixels include a cyan sub-filter C and a second yellow subpixel Y arranged along the odd-numbered column line of the display panel PNL during the first sub-frame period F (n). The subpixels Y having relatively high luminance ratios and the subpixels C and M having relatively low luminance ratios during the first sub frame period F (n) .

Data written to the 3D filter and / or pixels is shifted by one sub-pixel in the second sub frame period F (n + 1). 6, the left subpixels are divided into a cyan sub-filter C arranged along the odd-numbered column line of the display panel PNL for the second sub-frame period F (n + 1) (Y). Right subpixels include a magenta sub-filter M and a first yellow subpixel Y arranged along the odd column line of the display panel PNL for the second sub frame period F (n + 1) . The subpixels Y having relatively high luminance ratios and the subpixels C and M having relatively low luminance ratios during the second sub frame period F (n + 1) Are evenly distributed over the pixels. Therefore, the viewer can adjust the luminance of the left eye subpixels viewed through the left eye polarization filter and the right eye subpixels viewed through the right eye polarization filter during the first and second subframe periods F (n) and F (n + 1) I can hardly notice the difference, so I can enjoy stereoscopic video without flicker and 3D crosstalk.

The left eye subpixels and the right eye subpixels are separated according to the slit or lens direction of the 3D filter (BAR, LENTI) as described above. For example, when the slit or lens direction of the 3D filter (BAR, LENTI) is formed along the diagonal direction of the display panel (PNL), the left eye subpixels and right eye subpixels are separated along the oblique direction.

7 is a view illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a fifth embodiment of the present invention.

7, each of the pixels may include one cyan sub-filter C, one magenta sub-filter M, one yellow sub-pixel Y, and one green sub-pixel G have. In this case, when the luminance within one pixel is 1, the luminance ratio of the sub-pixels may be approximately C: M: Y: G = 0.220: 0.132: 0.277: 0.370.

In each of the pixels, the left-eye subpixels and the right-eye subpixels are divided by a 3D filter (BAR, LENTI). Each of the left eye subpixels and the right eye subpixels may be divided into two row lines in a pixel array of the display panel PNL as shown in FIG. The viewer sees only the left subpixels through the left eye, and only the right subpixels are viewed through the right eye, so that a stereoscopic image can be viewed with a binocular disparity.

An example is assumed in which a slit or lens direction of the 3D filter (BAR, LENTI) is formed along the column line of the display panel (PNL). In this case, the left subpixels are divided into a green sub filter G and a magenta sub filter M (N) arranged along the odd column line of the display panel PNL for the first sub frame period F (n) ). Right subpixels include a cyan sub-filter C and a yellow subpixel Y arranged along the odd-numbered column line of the display panel PNL for the first sub-frame period F (n). The subpixels Y and G having relatively high luminance ratios and the subpixels C and M having relatively low luminance ratios during the first sub frame period F (n) Are evenly distributed over the pixels.

Data written to the 3D filter and / or pixels is shifted by one sub-pixel in the second sub frame period F (n + 1). 7, the left subpixels are divided into the cyan sub-filter C and the yellow subpixel Y (n) arranged along the odd-numbered column line of the display panel PNL during the second sub frame period F (n + ). The right subpixels include a green subfilter G and a magenta subfilter M arranged along the even column line of the display panel PNL for the second sub frame period F (n + 1). The subpixels Y and G having a relatively high luminance ratio during the second sub frame period F (n + 1) and the subpixels C and M having relatively low luminance ratios are connected to the left subpixels And is evenly distributed to the right subpixels. Therefore, the viewer can adjust the luminance of the left eye subpixels viewed through the left eye polarization filter and the right eye subpixels viewed through the right eye polarization filter during the first and second subframe periods F (n) and F (n + 1) I can hardly notice the difference, so I can enjoy stereoscopic video without flicker and 3D crosstalk.

8 is a diagram illustrating a stereoscopic image display apparatus and a method of arranging pixels according to a sixth embodiment of the present invention.

Referring to Fig. 8, the pattern retarder PR is bonded onto the display panel PNL. The pattern retarder PR includes a first retarder PR1 facing the odd-numbered lines in the pixel array of the display panel PNL and a second retarder PR1 opposed to odd-numbered lines in the pixel array of the display panel PNL. And a retarder PR2. Left-eye subpixels are arranged in the odd-numbered lines of the pixel array, and right-eye subpixels are arranged in the even-th lines.

In order to reduce the luminance of the left eye subpixels and the luminance difference of right eye subpixels, the left eye subpixels are composed of a cyan subfilter C and a first yellow subpixel Y as shown in the upper diagram of FIG. 8, A second yellow sub-pixel Y and a magenta sub-filter M. 8, the left subpixels are composed of a cyan subpixel C and a yellow subpixel Y and the right subpixels are composed of a green subpixel G and a magenta subfilter M Lt; / RTI >

In the stereoscopic image display apparatus shown in FIG. 8, the subpixels (Y, G) having a relatively high luminance ratio and the subpixels (C, M) having a relatively low luminance ratio are displayed on the left and right subpixels . Accordingly, the viewer can hardly sense the difference in luminance between the left eye subpixels viewed through the left eye polarizing filter and the right eye subpixels viewed through the right eye polarizing filter, so that a stereoscopic image can be appreciated without flicker and 3D crosstalk.

In a liquid crystal display (LCD), pixels display an image by changing the transmittance of light passing through the display panel by turning the liquid crystal molecules according to the data voltage supplied to the pixel electrode and the potential difference of the common voltage (Vcom) supplied to the common electrode . Such a liquid crystal display device is driven by an inversion method that periodically reverses the polarity of a data voltage applied to the liquid crystal in order to reduce a direct current (DC) afterimage and prevent deterioration of the liquid crystal. However, when the polarity of the data voltage charged in the subpixels arranged on the same line in the pixel array is shifted to a certain polarity, the common voltage Vcom applied to the common electrode in the dominant polarity direction can be shifted. In this case, the viewer can feel the flicker between neighboring lines and feel the crosstalk due to the common voltage (Vcom) shift. In addition, if the polarity of the data voltage applied to the subpixels of the same color is shifted to any one of the polarities, the color may appear prominently or may not be well visible. For example, when the liquid crystal display element is driven by the one-dot version method in the 2D mode and the 3D mode as shown in FIG. 9, there is no problem in the 2D mode, but a polarity deviation occurs in the 3D mode. In detail, when divided into left-eye subpixels and right-eye subpixels by the 3D filter in the 3D mode, the green subpixels G arranged in the upper line among the left-eye subpixels shown as the left eye of the viewer are filled The polarities of the data voltages are all positive (+) while the polarity of the data voltages charged in the blue sub-pixels B arranged in the lower line is negative (-). The polarity of the data voltage charged in the red subpixels R disposed on the upper line among the right subpixels viewed from the right side of the viewer is all negative while the polarity of the white subpixels W ) Are positive polarity (+). This polarity bias can cause crosstalk and color distortion. In order to solve this problem, the present invention controls the polarity inversion interval to be longer in the dot inversion method applied to the 3D mode, compared to the dot inversion method applied in the 2D mode. This will be described with reference to FIGS. 10 to 14. FIG.

Referring to FIG. 10, the stereoscopic image display apparatus of the present invention controls a polarity of a data voltage in a 2D mode by a 1-dot version method. The one-dot inversion method inverts the polarity of the data voltage charged in the sub-pixels (or liquid crystal cells) neighboring in the horizontal and vertical directions by one dot. Here, one dot means the same as one sub-pixel or one liquid crystal cell. 10, "L1 to L6" means the number of the row lines of the pixel array, and "C1 to C6" means the column number of the pixel array. The one-dot inversion method reverses the polarity of the data voltage charged in the subpixels neighboring in the vertical and horizontal directions within one frame period in units of one dot, and the polarity of the data voltage charged in the subpixels To a polarity opposite to that of the previous frame.

The stereoscopic image display device of the present invention controls the polarity of the data voltage in the 3D mode by a version method with two dots. The two-dot inversion method illustrated in FIG. 10 shows an example in which the data voltage is inverted in the two-dot unit along the row line direction (or the horizontal direction). The two dot inversion method can be reversed in a version method in which the data voltage is one dot in the column direction (or vertical direction) or reversed in two dot units as in the example of Fig.

In the two-dot inversion method illustrated in FIG. 10, the polarity of the data voltage charged in the sub-pixels neighboring in the horizontal direction within one frame period is inverted in units of two dots, and data The polarity of the voltage is inverted to the polarity opposite to the previous frame.

FIG. 11 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 10 is applied to the stereoscopic image display apparatus as shown in FIG. 12 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 10 is applied to the stereoscopic image display apparatus as shown in FIG.

Referring to FIGS. 11 and 12, the stereoscopic image display apparatus of the present invention inverts polarities of data voltages to be charged in subpixels by applying different dot-inversion methods in the 2D mode and the 3D mode. The dot inversion method applied in the 2D mode is the one dot inversion method shown in Fig. 10, and the dot inversion method applied in the 3D mode is the two dot inversion method shown in Fig.

As a result of applying the dot inversion switching method as shown in FIG. 10 to the stereoscopic image display apparatus as shown in FIG. 2 or FIG. 3, the polarities of left subpixels neighboring in the vertical and horizontal directions in the 3D mode are opposite to each other, The polarities of neighboring right-eye subpixels in the vertical and horizontal directions are opposite to each other. In the 3D mode, no polarity deviation occurs in any color subpixel. Therefore, the stereoscopic image display apparatus of the present invention can minimize flicker, crosstalk, and color distortion. Although not shown, the dot inversion method of the stereoscopic image display apparatus as shown in Figs. 6 and 7 can also be switched in the same manner as in Fig.

13 is a diagram illustrating another example of a dot inversion method applied to a 2D mode and a dot inversion method applied to a 3D mode in a stereoscopic image display device according to an embodiment of the present invention. The dot inversion method can minimize flicker, crosstalk, and color distortion when applied to a stereoscopic image display device of the polarizing glasses type as shown in Figs. 5 and 8. Fig.

Referring to FIG. 13, the stereoscopic image display apparatus of the present invention controls a polarity of a data voltage in a 2D mode by a 1-dot version method. In this one-dot-inversion method, the polarity of the data voltage charged in the subpixels neighboring in the vertical and horizontal directions in one frame period is inverted in the unit of one dot, and the polarity of the data voltage charged in the subpixels The polarity is inverted to the polarity opposite to the previous frame.

The stereoscopic image display device of the present invention controls the polarity of the data voltage in the 3D mode by a version method with two dots. The two-dot inversion method illustrated in FIG. 13 shows an example in which the data voltage is inverted in a two-dot unit along the column direction (or vertical direction). The two dot inversion method can be reversed in a version method in which the data voltage is one dot in the row line direction (or in the horizontal direction) or reversed in two dot units as in the example of Fig.

In the two-dot inversion method illustrated in FIG. 13, the polarity of the data voltage charged in the vertically neighboring subpixels is inverted in units of two dots in one frame period, and the data charged in the subpixels The polarity of the voltage is inverted to the polarity opposite to the previous frame.

FIG. 14 is a diagram illustrating an example in which the dot inversion method as shown in FIG. 13 is applied to the stereoscopic image display apparatus as shown in FIG.

Referring to FIG. 14, the stereoscopic image display device of the present invention inverts the polarity of a data voltage to be charged in subpixels by applying a different dot inversion method in a 2D mode and a 3D mode. The dot inversion method applied in the 2D mode is the 1-dot inversion method shown in Fig. 13, and the dot inversion method applied in the 3D mode is the 2-dot inversion method shown in Fig.

As a result of applying the dot inversion switching method as shown in FIG. 13 to the stereoscopic image display device as shown in FIG. 2 or FIG. 3, the polarities of the left subpixels neighboring in the vertical and horizontal directions in the 3D mode are opposite to each other, The polarities of neighboring right-eye subpixels in the vertical and horizontal directions are opposite to each other. In the 3D mode, no polarity deviation occurs in any color subpixel. Therefore, the stereoscopic image display apparatus of the present invention can minimize flicker, crosstalk, and color distortion. Although not shown, the dot inversion method of the stereoscopic image display apparatus as shown in FIG. 8 can also be switched in the same manner as in FIG.

15 is a block diagram illustrating a display panel driver and a 3D filter driver in a stereoscopic image display apparatus according to an exemplary embodiment of the present invention. 16 is a cross-sectional view showing a lenticular lens film or a switchable lens. 17 is a sectional view showing a parallax barrier or a switchable barrier. 18 is a cross-sectional view showing a pattern retarder and polarizing glasses.

15 to 18, the stereoscopic image display apparatus of the present invention includes a display panel (PNL) 100, a 3D filter 200 bonded on a display panel (PNL) 100, a display panel driver, a 3D filter driver 210, a timing controller 101, and the like.

The display panel PNL includes a pixel array in which the data lines 105 and the scan lines (or gate lines) 106 are orthogonalized and the pixels are arranged in a matrix form. The pixel array displays the 2D image in the 2D mode, and displays the left eye image and the right eye image in the 3D mode in the same manner as in FIGS. 1 to 8 and 10 to 14.

The 3D filter 200 may be any of a lenticular lens film or a switchable lens LENTI as shown in Fig. 16, a parallax barrier or switchable barrier (BAR) as shown in Fig. 17, or a pattern retarder PR as shown in Fig. . When the 3D filter 200 is implemented as a pattern retarder (PR), the viewer must watch the 3D image by wearing polarized glasses (PG). The switchable lens LENTI or switchable barrier (BAR) includes a birefringent medium such as liquid crystal and is electrically driven by the 3D filter driver 210 to emit light from the left eye subpixels and from the right eye subpixels Separate the path of light. If the 3D filter 200 is implemented as an optical component such as a parallax barrier, a lenticular lens film, and a pattern retarder (PR), which is not electrically controlled, the 3D driver 210 is not required.

The display panel driving unit includes a data driving circuit 102 for supplying data voltages of the 2D / 3D image to the data lines 105 of the display panel PNL 100, And a scan driving circuit 103 for sequentially supplying scan pulses (or gate pulses)

The data driving circuit 102 converts the digital video data input from the timing controller 101 into an analog gamma voltage to generate data voltages and supplies the data voltages to the data lines 105 of the display panel PNL 100 do. The data driving circuit 102 inverts the polarity of the data voltage supplied to the data lines 105 under the control of the timing controller 101 in the same manner as in FIGS. The scan driver circuit 103 supplies a scan pulse synchronized with the data voltage supplied to the data lines 105 to the scan lines 106 under the control of the timing controller 101 and sequentially shifts the scan pulses .

The 3D filter driver 210 is driven in the 3D mode under the control of the timing controller 101. The 3D filter driving unit 210 synchronizes the 3D image data written in the pixel array of the display panel PNL 100 with the switchable lens LENTI or the switchable barrier BAR, 7, 11 to 12, 14, and so on.

The timing controller 101 supplies digital video data (RGB) of a 2D / 3D input image input from the host system 120 to the data driving circuit 102. The timing controller 101 synchronizes with the digital video data RGB of the 2D / 3D input video and outputs a timing signal such as a vertical synchronizing signal, a horizontal synchronizing signal, a data enable signal, and a main clock input from the host system 120 GDC, and GDC for controlling the operation timings of the display panel driving units 102 and 103 and the 3D filter driving unit 210 using the timing signals and for synchronizing the operation timings of the driving units, SBC).

The timing controller 101 may generate a polarity control signal for inverting the polarity of the data voltage in the same manner as in FIGS. 10 to 14. FIG. The polarity control signal and the method of controlling the polarity of the data voltage using the polarity control signal can be implemented by a method proposed in U.S. Patent No. 8,111,229 (2012.02.07), US Application No. 12 / 844,252 (Mar.

The timing controller 101 raises the frame frequency of the input image to the frame frequency x N (where N is a positive integer equal to or greater than 2) Hz and multiplies the operation frequency of the display panel driving units 102 and 103 and the 3D filter driving unit 210 by N times The frame rate can be controlled. The frame frequency of the input image is 60 Hz in the National Television Standards Committee (NTSC) system and 50 Hz in the PAL (Phase-Alternating Line) system. Accordingly, the timing controller 101 time-divides one frame period into first and second sub frame periods as shown in Figs. 1 to 4, 6, 7, 11 to 12, and 14, And 103 and the 3D filter driving unit 210, the frame rate can be increased to a frequency that is N times the frame frequency of the input image.

A 3D data arrangement unit 110 is provided between the host system 120 and the timing controller 101. The 3D data sorting unit 110 separates the left eye image data and the right eye image data of the 3D image input from the host system 120 in the 3D mode into shapes such as FIGS. 1 to 8, 11 to 12, and 14 To the timing controller 101. When the 2D image data is input in the 3D mode, the 3D data sorting unit 110 executes a predetermined 2D-3D image transformation algorithm to generate left eye image data and right eye image data from 2D image data, , 11 to 12, 14, and so on, and transmits them to the timing controller 101.

 The host system 120 may be implemented as any one of a navigation system, a set top box, a DVD player, a Blu-ray player, a personal computer (PC), a home theater system, a broadcast receiver, and a phone system. The host system 120 converts the digital video data of the 2D / 3D input image into a format suitable for the resolution of the display panel (PNL) 100 using a scaler, and transmits a timing signal to the timing controller 101 together with the data. Lt; / RTI >

The host system 120 supplies the 2D image to the timing controller 101 in the 2D mode while supplying the 3D image or 2D image data to the 3D data arrangement unit 110 in the 3D mode. The host system 120 may switch a 2D mode operation and a 3D mode operation by transmitting a mode signal to the timing controller in response to user data input through a user interface (not shown). The user interface includes a keypad, a keyboard, a mouse, an on screen display (OSD), a remote controller, a graphical user interface (GUI), a touch UI (user interface) UI, or the like. The user can select the 2D mode and the 3D mode through the user interface, and select the 2D-3D image conversion in the 3D mode.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the present invention should not be limited to the details described in the detailed description, but should be defined by the claims.

PNL, 100: Display panel LENTI: Lenticular lens, Switchable lens
BAR: Parallax Barrier, Switcher Barrier

Claims (14)

A display panel in which data lines and scan lines are crossed and includes pixels; And
And a 3D filter bonded on the display panel,
The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written,
The left eye subpixels include two subpixels, one of which includes green subpixels in the first subframe period and the white subpixels in the second subframe period,
Wherein the right subpixels include two subpixels, one of which includes the white subpixel in the first subframe period and the green subpixel in the second subframe period. Display device. The method according to claim 1,
Wherein the 3D filter includes any one of a switchable barrier and a switchable lens which are electrically controlled. 3. The method of claim 2,
2D image data is displayed in the 2D mode on the pixels,
The polarity of the data voltage supplied to the pixels through the data lines in the 2D mode is inverted by a version method with one dot,
The left eye image data and the right eye image data are divided into the left eye subpixels and the right eye subpixels in the 3D mode,
Wherein the polarity of the data voltage supplied to the pixels through the data lines in the 3D mode is inverted by a version method with two dots. 4. The method according to any one of claims 1 to 3,
Wherein the left subpixels include the green subpixel and the blue subpixel in the first subframe period and include the white subpixel and the red subpixel in the second subframe period,
Wherein the right subpixels include the white subpixel and the red subpixel in the first subframe period and include the green subpixel and the blue subpixel in the second subframe period. Device. 5. The method of claim 4,
Wherein the left subpixels and the right subpixels are arranged in two rows of the display panel. 4. The method according to any one of claims 1 to 3,
The left subpixels include the green subpixel and the red subpixel in the first subframe period and include the white subpixel and the blue subpixel in the second subframe period,
Wherein the right subpixels include the white subpixel and the blue subpixel in the first subframe period and include the green subpixel and the red subpixel in the second subframe period. Device. The method according to claim 6,
Wherein the left subpixels and the right subpixels are arranged along one row line in the display panel. A display panel in which data lines and scan lines are crossed and includes pixels; And
And a 3D filter bonded on the display panel,
The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written,
The left sub-pixels include two sub-pixels, one of which includes a first green sub-pixel in a first sub-frame period and a second green sub-pixel in a second sub-frame period,
The right subpixels include two subpixels, one of which includes the second green subpixel in the first subframe period and the first green subpixel in the second subframe period Dimensional image display device. A display panel in which data lines and scan lines are crossed and includes pixels; And
And a 3D filter bonded on the display panel,
The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written,
The left eye subpixels include two subpixels, one of which includes green subpixels in the first subframe period and the yellow subpixels in the second subframe period,
Wherein the right subpixels include two subpixels, one of which includes the yellow subpixel in the first subframe period and the green subpixel in the second subframe period. Display device. A display panel in which data lines and scan lines are crossed and includes pixels; And
And a 3D filter bonded on the display panel,
The pixels are divided into left eye subpixels into which left eye image data is written and right eye subpixels into which right eye image data is written,
Wherein the left subpixels are arranged in a first line of the display panel and include white subpixels,
Wherein the right subpixels are arranged in a second line below the first line in the display panel and include green subpixels. 10. The method according to claim 8 or 9,
Wherein the 3D filter includes any one of a switchable barrier and a switchable lens which are electrically controlled. 12. The method of claim 11,
2D image data is displayed in the 2D mode on the pixels,
The polarity of the data voltage supplied to the pixels through the data lines in the 2D mode is inverted by a version method with one dot,
The left eye image data and the right eye image data are divided into the left eye subpixels and the right eye subpixels in the 3D mode,
Wherein the polarity of the data voltage supplied to the pixels through the data lines in the 3D mode is inverted by a version method with two dots. 11. The method of claim 10,
Wherein the 3D filter includes a pattern retarder. 14. The method of claim 13,
2D image data is displayed in the 2D mode on the pixels,
The polarity of the data voltage supplied to the pixels through the data lines in the 2D mode is inverted by a version method with one dot,
The left eye image data and the right eye image data are divided into the left eye subpixels and the right eye subpixels in the 3D mode,
Wherein the polarity of the data voltage supplied to the pixels through the data lines in the 3D mode is inverted by a version method with two dots.

Images