KR101318761B1 - Image display device - Google Patents

Abstract

The image display device includes a display device for selectively implementing 2D and 3D images, including a pixel array having subpixels formed at intersections of column lines and row lines; And a patterned retarder in which a first retarder through which light from the display element passes through the first polarization component and a second retarder through the second polarization component are alternately formed; 2D image data is displayed on all subpixels in the 2D image implementation; When the 3D image is implemented, black data is displayed on the subpixels of the fourth i lowline, and 3D image data of one of the left eye and the right eye is displayed on the subpixels of the upper three lowlines adjacent to the fourth i lowline. The 3D image data of the other of the left eye and the right eye is displayed on the subpixels of the lower three rowlines adjacent to the fourth i rowline.

Description

IMAGE DISPLAY DEVICE [0002]

The present invention relates to an image display device capable of realizing a two-dimensional plane image (hereinafter referred to as '2D image') and a three-dimensional stereoscopic image (hereinafter referred to as '3D image').

With the development of various contents and the development of circuit technology, image display apparatuses can selectively implement 3D images as well as 2D images. The image display device implements a 3D image using a binocular stereoscopic technique or an autostereoscopic technique.

The binocular parallax method uses parallax images of right and left eyes with large stereoscopic effect, and both glasses and non-glasses are used, and both methods are practically used. In the non-eyeglass system, an optical plate such as a parallax barrier for separating the optical axis of left and right parallax images is installed in front of or behind the display screen. In the spectacle method, left and right parallax images having different polarization directions are displayed on a display panel, and stereoscopic images are implemented using polarized glasses or liquid crystal shutter glasses.

In the liquid crystal shutter glasses system, a left-eye image and a right-eye image are alternately displayed on a display unit in frame units, and a left-eye and right-eye shutter of the liquid crystal shutter glasses is opened and closed in synchronization with the display timing. The liquid crystal shutter glasses open the left eye shutter only during the odd frame period in which the left eye image is displayed and only the right eye shutter is opened during the excellent frame period in which the right eye image is displayed to produce binocular parallax in a time division manner. The liquid crystal shutter glasses have a short data on time, and thus have low luminance of 3D images, and 3D crosstalk is severely generated depending on the synchronization between the display element and the liquid crystal shutter glasses and on / off switching response characteristics.

The polarizing glasses system includes a patterned retarder 2 attached on the display panel 1 as shown in Fig. The polarizing glasses system alternately displays the left eye image data L and the right eye image data R on a horizontal line basis in the display panel 1 and displays the polarized glasses 3 incident on the polarizing glasses 3 through the patterned retarder 2 Switch the characteristics. Through this, the polarized glasses method can realize a 3D image by spatially dividing the left eye image and the right eye image.

In the polarizing glasses method, since the left eye image and the right eye image are displayed adjacent to each other in a line unit, the vertical viewing angle at which crosstalk is not generated is narrow. Crosstalk occurs when the left and right eye images are superimposed on the monocular (either left or right eye) at the vertical viewing angle position. Thus, as shown in FIG. 2, a method of widening the vertical viewing angle of the 3D image by forming a black stripe BS on the patterned retarder 2 has been proposed through Japanese Laid-Open Patent Publication No. 2002-185983. However, the black stripe BS used to improve the viewing angle causes side effects that greatly reduce the luminance of the 2D image.

Accordingly, it is an object of the present invention to provide an image display apparatus which can widen the vertical viewing angle of a 3D image without lowering the luminance of the 2D image.

In order to achieve the above object, the image display device of the present invention includes a display element for selectively implementing a 2D image and a 3D image, including a pixel array having subpixels formed at intersections of column lines and row lines; And a patterned retarder in which a first retarder through which light from the display element passes through the first polarization component and a second retarder through the second polarization component are alternately formed; 2D image data is displayed on all subpixels in the 2D image implementation; When the 3D image is implemented, black data is displayed on the subpixels of the fourth i lowline, and 3D image data of one of the left eye and the right eye is displayed on the subpixels of the upper three lowlines adjacent to the fourth i lowline. The 3D image data of the other of the left eye and the right eye is displayed on the subpixels of the lower three rowlines adjacent to the fourth i rowline.

According to an aspect of the present invention, there is provided an image display device including: a display device configured to selectively implement 2D and 3D images, including a pixel array having subpixels formed at intersections of column lines and row lines; And a patterned retarder in which a first retarder through which light from the display element passes through the first polarization component and a second retarder through the second polarization component are alternately formed; 2D image data is individually displayed on all subpixels when the 2D image is implemented; When the 3D image is implemented, black data is displayed on subpixels of at least one or more low lines among the low lines included in the first retarder and the second retarder, and the remaining low lines except for the low line on which the black data is displayed. 3D image data of any one of the left eye and the right eye is displayed on the subpixels of.

According to an aspect of the present invention, there is provided an image display device including: a display device configured to selectively implement 2D and 3D images, including a pixel array having subpixels formed at intersections of column lines and row lines; And a patterned retarder in which a first retarder through which light from the display element passes through the first polarization component and a second retarder through the second polarization component are alternately formed; 2D image data is displayed on all subpixels in the 2D image implementation; When the 3D image is implemented, black data is displayed on the subpixels of the fourth i column line, and 3D image data of one of the left eye and the right eye is displayed on the subpixels of the left three column lines adjacent to the fourth i column line. The 3D image data of the other of the left eye and the right eye is displayed on the subpixels of the right three rowlines adjacent to the fourth column.

According to an aspect of the present invention, there is provided an image display device including: a display device configured to selectively implement 2D and 3D images, including a pixel array having subpixels formed at intersections of column lines and row lines; And a patterned retarder in which a first retarder through which light from the display element passes through the first polarization component and a second retarder through the second polarization component are alternately formed; The first and second retarders are arranged to include at least two row lines or at least two column lines; 2D image data is displayed on subpixels of the at least two row lines or at least two column lines when the 2D image is implemented; When the 3D image is implemented, 3D image data of any one of the left eye and the right eye is displayed on some lines of the subpixels of the at least two or more row lines or at least two column lines, and black data is displayed on the remaining lines except the some lines. Become; The remaining lines may individually display the 2D image data when the 2D image is implemented.

The video display device according to the present invention determines the alignment of the patterned retarder and adjusts the data applied to the subpixels according to the arrangement of the RGB subpixels, thereby reducing the brightness of the 2D image. The vertical viewing angle of the image can be widened.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
2 is a view for explaining a decrease in brightness of a 2D image due to a black stripe used for improving the viewing angle in the polarizing glasses system;
FIG. 3 and FIG. 4 are views showing a polarizing glasses type video display device according to an embodiment of the present invention. FIG.
5 to 7 are views showing the arrangement of the RGB sub-pixels according to an embodiment of the present invention and the alignment state of the patterned retarder corresponding thereto.
8A and 8B are diagrams of a first example showing a display state of image data targeting FIGS. 5 to 7;
9A and 9B are diagrams of a second example showing a display state of image data targeting FIGS. 5 to 7;
10A and 10B are diagrams of a third example showing a display state of image data targeting FIGS. 5 to 7;
11A and 11B are diagrams of a fourth example showing a display state of image data targeting FIGS. 5 to 7;
12 to 14 are views illustrating an arrangement of RGB subpixels and alignment states of a patterned retarder corresponding thereto according to another embodiment of the present invention.
15A and 15B are views illustrating a display state of image data for FIGS. 12 to 14.
16 to 18 are views illustrating an arrangement of RGB subpixels and an alignment state of a patterned retarder corresponding thereto according to another embodiment of the present invention.
19A and 19B are views illustrating a display state of image data for FIGS. 16 to 18.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 3 to 19B. In the following description, a 'low line' is defined as a horizontal display line formed by subpixels adjacent to each other along a row direction, and a 'column line' is formed by subpixels adjacent to each other along a column direction. It is defined as a vertical display line.

3 and 4 show an image display apparatus according to an embodiment of the present invention.

Referring to FIG. 3, the image display device includes a display element 10, a patterned retarder 20, a controller 30, a panel driver 40, and polarizing glasses 50.

The display device 10 includes a liquid crystal display (LCD), a field emission display (FED), a plasma display panel (PDP), an inorganic electroluminescent device and an organic light emitting diode device. The display device may be implemented as a flat panel display device such as an electroluminescence device (EL) including an organic light emitting diode (OLED) and an electrophoresis display device (EPD). Hereinafter, the display element 10 will be described mainly with respect to the liquid crystal display element.

The display element 10 includes a display panel 11, an upper polarizer 11a, and a lower polarizer 11b.

The display panel 11 includes two glass substrates and a liquid crystal layer formed therebetween. A plurality of data lines DL and a plurality of gate lines GL are disposed on the lower glass substrate of the display panel 11 so as to intersect with the data lines DL. Due to the intersecting structure of the signal lines DL and GL, a plurality of sub pixels are arranged in a matrix form on the display panel 11 to form a pixel array.

On the upper glass substrate of the display panel 11, a black matrix, a color filter, and a common electrode are formed. Upper and lower polarizing films 11a and 11b are attached to each of the upper and lower glass substrates of the display panel 11, and an alignment layer for setting the pre-tilt angle of the liquid crystal is formed. The common electrode to which the common voltage Vcom is supplied is formed on the upper glass substrate in a vertical electric field driving mode such as TN (Twisted Nematic) mode and VA (Vertical Alignment) Field switching mode) is formed on the lower glass substrate together with the pixel electrode. A column spacer for maintaining a cell gap of the liquid crystal cell may be formed between the glass substrates.

The display panel 11 may be implemented in any liquid crystal mode as well as the TN mode, VA mode, IPS mode, and FFS mode. The liquid crystal display element of the present invention can be implemented in any form of a transmissive display element, a transflective display element, a reflective display element, and the like. In the transmissive display device and the transflective display device, the backlight unit 12 is required. The backlight unit 12 may be implemented as a direct type backlight unit or an edge type backlight unit.

The patterned retarder 20 is attached to the upper polarizing film 11a of the display panel 11. In the patterned retarder 20, a first retarder through which light from the display element 10 passes through the first polarization component and a second retarder through the second polarization component are alternately formed. The light absorption axis of the first retarder and the light absorption axis of the second retarder are perpendicular to each other. The first retarder of the patterned retarder 20 may pass light incident from the pixel array through left circularly polarized light, and the second retarder may pass light incident from the pixel array through right circularly polarized light. The first retarder of the patterned retarder 20 may be implemented as a polarization filter that converts incident light to left circularly polarized light, and the second retarder of the patterned retarder 20 converts incident light to right circularly polarized light. It can be implemented as.

The controller 30 controls the operation of the panel driver 40 in the 2D mode or the 3D mode according to the mode selection signal.

The controller 30 renders the 3D image data input from the system board (not shown) in the 3D mode according to the display position on the display panel 11 and supplies the 3D image data to the panel driver 40. The controller 30 renders the RGB data of the 2D image input from the system board in the 2D mode according to the display position on the display panel 11 and supplies the RGB data to the panel driver 40.

The controller 30 receives timing signals such as a vertical sync signal Vsync, a horizontal sync signal Hsync, a data enable signal DE, and a dot clock DCLK from the system board. Generate control signals for controlling the operation timing of the signal.

A data control signal for controlling the operation timing of the data driver 40A includes a source start pulse (SSP), a rising start signal A source sampling clock (SSC) for controlling the latch operation of the data on the basis of the falling edge of the data, a source output enable signal SOE for controlling the output of the data driver 40A, And a polarity control signal POL for controlling the polarity of the data voltage to be supplied to the liquid crystal cells of the liquid crystal cells 11,

The gate control signal for controlling the operation timing of the gate driver 40B includes a gate start pulse (GSP) indicating a start horizontal line from which a scan starts in one vertical period in which one screen is displayed, a gate driver 40B A gate shift clock signal GSC for sequentially shifting the gate start pulse GSP and a gate output enable signal Gate OUT for controlling the output of the gate driver 40B, Enable: GOE).

The control unit 30 multiplies the timing signals (Vsync, Hsync, DE, DCLK) synchronized with the input frame frequency to generate a frame signal having a frame frequency of Nxf (where N is a positive integer of 2 or more and f is an input frame frequency) The operation of the driving unit 40 can be controlled. The input frame frequency is 60 Hz in the National Television Standards Committee (NTSC) scheme and 50 Hz in the phase-alternating line (PAL) scheme.

The panel driver 40 includes a data driver 40A for driving the data lines DL of the display panel 11, and a gate driver 40B for driving the gate lines GL of the display panel 11. It includes.

Each of the source driver ICs of the data driver 40A includes a shift register, a latch, a digital-to-analog converter (DAC), an output buffer, and the like. The data driver 40A latches the RGB data of the 2D or 3D image according to the data control signals SSP, SSC and SOE. The data driver 40A converts the RGB data of the 2D or 3D image into the analog positive gamma compensation voltage and the negative gamma compensation voltage in response to the polarity control signal POL to reverse the polarity of the data voltage. The data driver 40A outputs the data voltage to the data lines DL so as to be synchronized with the scan pulse (or gate pulse) output from the gate driver 40B. The source drive ICs of the data driver 40A can be bonded to the lower glass substrate of the display panel 11 by a TAB (Tape Automated Bonding) process.

The gate driver 40B generates a scan pulse that swings between the gate high voltage and the gate low voltage in accordance with the gate control signals GSP, GSC, and GOE. The scan pulse is supplied to the gate lines GL in a line sequential manner according to the gate control signals GSP, GSC, and GOE. The gate driver 40B includes a gate shift register array and the like. The gate shift register array of the gate driver 40B may be formed in a GIP (Gate In Panel) method in a non-display area outside the display area where the pixel array is formed in the display panel 11. [ With the GIP scheme, the gate shift registers can be formed with the pixel array in the TFT process of the pixel array.

The polarizing glasses 50 include a left eye 50L having a left eye polarization filter and a right eye 50R having a right eye polarization filter. The left eye polarization filter has the same light absorption axis as the first retarder of the pattern retarder 20, and the right eye polarization filter has the same light absorption axis as the second retarder of the pattern retarder 20. For example, the left eye polarization filter of the polarizing glasses 50 may be selected as a left circular polarization filter, and the right eye polarization filter of the polarizing glasses 50 may be selected as a right circular polarization filter. The user may view 3D image data displayed on the display device 10 in a spatial division manner through the polarizing glasses 50.

Such an image display apparatus has three embodiments according to an arrangement configuration of RGB subpixels and an alignment state of a patterned retarder corresponding thereto (first embodiment: FIGS. 5 to 11b and second embodiment: FIGS. 12 to 15b). , A third embodiment: FIGS. 16 to 19b).

5 to 7 illustrate an arrangement of RGB subpixels and an alignment state of a patterned retarder corresponding thereto according to an embodiment of the present invention.

The subpixels constituting the pixel array are divided into a red subpixel including a red (R) color filter, a green subpixel including a green (G) color filter, and a blue subpixel including a blue (B) color filter. . The red subpixel, the green subpixel, and the blue subpixel are sequentially disposed along the column direction as shown in FIGS. 5 to 7 to form the unit pixel PIX. One data line and three gate lines are allocated to the unit pixel PIX. For example, in the unit pixel PIX as shown in FIG. 6, the first subpixel SP1 is formed at an intersection area of the data line DL1 and the gate line GL1 to display red R and the second subpixel. SP2 is formed at the intersection of the data line DL1 and the gate line GL2 to display green G, and the third sub-pixel SP3 crosses the data line DL1 and the gate line GL3. It may be formed in the area to display blue (B).

The patterned retarder 20 is aligned with the display panel 10 to separate polarized light in units of four low lines. The first retarder RT1 and the second retarder RT2 are formed long in the row direction, respectively. The first retarder RT1 and the second retarder RT2 are alternately formed along the column direction. The first retarder RT1 and the second retarder RT2 are respectively opposed to four row lines. For example, when the first retarder RT1 faces four rowlines including the first to fourth sub-pixels SP1 to SP4, as shown in FIG. 7, the second retarder RT2 may correspond to the fifth to fifth rowlines. Four rowlines including the eighth subpixels SP5 to SP8 may be opposite to each other.

8A and 8B are first examples illustrating a display state of image data of FIGS. 5 to 7.

Referring to FIG. 8A, RGB data of a 2D image is displayed in subpixels of the display panel 11 in the 2D mode along the column direction, and the display order of the RGB data is all column lines (c # 1 to c # 4). Are identical to each other. As a result, 2D is applied to the subpixels of the third i-2 low lines r # 1, r # 4, r # 7 (i is a positive integer) that intersects the column lines c # 1 to c # 4. The R data of the image is displayed, and the subpixels of the 3i-1 low lines r # 2, r # 5, and r # 8 that intersect the column lines c # 1 to c # 4 are displayed in the 2D image. The G data is displayed, and the B data of the 2D image is displayed on the subpixels of the third i-line lines r # 3, r # 6, and r # 9 that intersect the column lines c # 1 to c # 4. do.

Referring to FIG. 8B, in the 3D mode, subpixels of the display panel 11 display RGB data and black data BD of a 3D image along a column direction, and the display order of the RGB data is all column lines c. # 1 to c # 4). The black data BD is displayed on the subpixels of the fourth i row lines r # 4 and r # 8 (i is a positive integer). The RGB data displayed along the column direction is divided into left eye and right eye image data with the fourth i row lines r # 4 and r # 8 interposed therebetween. Left and right eye image data is rendered in order of left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, left eye GBR data, and right eye BRG data along the column direction in all column lines (c # 1 to c # 4). do.

As can be seen from this, the present invention displays the 2D image data on all subpixels in the 2D mode to prevent deterioration of the brightness of the 2D image, and in the 3D mode, the subs of the fourth i line (r # 4, r # 8) The black data BD is displayed on the pixels to secure the display interval between the left eye image and the right eye image, thereby increasing the vertical viewing angle of the 3D image. The subpixels of the fourth i row lines r # 4 and r # 8 display the black data BD only in the 3D mode and serve as active black stripes.

In the first example, the first retarder RT1 and the second retarder RT2 respectively corresponding to four row lines are described, but the number of corresponding row lines is not limited thereto. The first and second retarders RT1 and RT2 may correspond to four or more row lines, respectively. In this case, the present invention displays 2D image data individually on all subpixels under 2D mode to prevent deterioration of luminance of 2D image, and displays data of left or right eye image on three or more low lines under 3D mode. The black data BD is displayed on the remaining one or more row lines.

There may be two or more row lines displaying the black data BD, thereby further reducing top and bottom crosstalk. The low line displaying the black data BD displays the 2D image under the 2D mode. Accordingly, the first retarder RT1 or the second retarder RT2 is arranged to correspond to the row lines displaying left or right eye image data, respectively, and displays 2D image data in 2D mode and black in 3D mode. The data BD is disposed to correspond to the row lines to display the data BD.

The left eye or right eye image data displayed to correspond to one first retarder RT1 or one second latitude RT2 in the 3D mode is not limited to only three row lines. That is, RGB data of two or more groups of left eye images and two or more groups of right eye images RGB data may be alternately displayed using three row lines as one group. In this case, the RGB data of the left eye image, the RGB data of the left eye image, the black data BD, or the RGB data of the right eye image, the RGB data of the right eye image BD, or the like may be one first retarder RT1 or the like. It may correspond to one second retarder RT2. Through this configuration, the present invention can further improve the luminance under the 3D mode.

That is, in this example, one first retarder RT1 and second retarder RT2 respectively correspond to at least four or more row lines, and each row line displays a separate 2D image under the 2D mode. In 3D mode, 3D image data is displayed by including at least one group of three row lines displaying RGB data, and at least one row line displays black data BD. In addition, since the row lines displaying black data under the 3D mode display individual data under the 2D mode, the row lines may be formed to have the same upper and lower widths as compared to other row lines.

9A and 9B are second examples illustrating a display state of image data of FIGS. 5 to 7.

Referring to FIG. 9A, RGB data of a 2D image is displayed in subpixels of the display panel 11 in the 2D mode along a column direction, and the display order of the RGB data is the 3i-2 column line (c # 1, c). # 4), in the 3i-1th column line c # 2 and in the 3ith column line c # 3. As a result, the R data of the 2D image is included in the subpixels of the 3i-2 low lines r # 1, r # 4 and r # 7 that intersect the 3i-2 column lines c # 1 and c # 4. Is displayed on the subpixels of the 3i-1 low lines r # 2, r # 5, r # 8 that intersect the 3i-2 column lines c # 1 and c # 4. The data is displayed, and the B data of the 2D image is included in the subpixels of the third i low lines r # 3, r # 6 and r # 9 that intersect the third i-2 column lines c # 1 and c # 4. Is displayed. The B data of the 2D image is displayed on the subpixels of the 3i-2 low lines r # 1, r # 4, and r # 7 that cross the 3i-1 column line c # 2. The R data of the 2D image is displayed on the subpixels of the 3i-1 lowlines r # 2, r # 5, and r # 8 that intersect the 3i-1 column line c # 2, and the 3i-1 The G data of the 2D image is displayed on the subpixels of the third i row lines r # 3, r # 6, and r # 9 that cross the column line c # 2. In addition, G data of a 2D image is displayed on the subpixels of the 3i-2 low lines r # 1, r # 4, r # 7 that intersect the 3i column line c # 3, and the 3i column. The B data of the 2D image is displayed on the subpixels of the 3i-1 low lines r # 2, r # 5, and r # 8 that intersect the line c # 3, and the 3i column line c # 3. R data of the 2D image is displayed on the subpixels of the third i low lines r # 3, r # 6, and r # 9 that intersect with each other.

Referring to FIG. 9B, RGB data and black data BD of a 3D image are displayed in the subpixels of the display panel 11 in the 3D mode along the column direction, and the display order of the RGB data is 3i-2 column line. (c # 1, c # 4), the 3i-1th column line c # 2 and the 3ith column line c # 3 are different from each other. The black data BD is displayed on the subpixels of the fourth i row lines r # 4 and r # 8. The RGB data displayed along the column direction is divided into left eye and right eye image data with the fourth i row lines r # 4 and r # 8 interposed therebetween. Left eye and right eye image data are in the order of the left eye RGB data, the right eye GBR data, the left eye BRG data, the right eye RGB data, the right eye GRG data, and the right eye BRG data along the column direction in the 3i-2 column lines c # 1 and c # 4. Is rendered as: The left eye and right eye image data are rendered in the order of the left eye BRG data, the right eye RGB data, the left eye GBR data, the right eye BRG data, the left eye RGB data, and the right eye GBR data along the column direction in the 3i-1 column line c # 2. do. The left eye and right eye image data are rendered in the order of the left eye GBR data, the right eye BRG data, the left eye RGB data, the right eye GBR data, the left eye BRG data, and the right eye RGB data along the column direction in the 3i column line c # 3.

As can be seen from this, the present invention displays the 2D image data on all subpixels in the 2D mode to prevent deterioration of the brightness of the 2D image, and in the 3D mode, the subs of the fourth i line (r # 4, r # 8) The black data BD is displayed on the pixels to secure the display interval between the left eye image and the right eye image, thereby increasing the vertical viewing angle of the 3D image. The subpixels of the fourth i row lines r # 4 and r # 8 display the black data BD only in the 3D mode and serve as active black stripes. Furthermore, in this example, the display order of the RGB data is different from that of the 3i-2 column line (c # 1, c # 4), the 3i-1 column line (c # 2), and the 3i column line (c # 3). Prevent color distortion of 3D images.

In the second example, as in the first example, the row lines corresponding to the first retarder RT1 and the second retarder RT2 display the respective 2D images in the 2D mode under the 2D mode, and the left eye in the 3D mode. Alternatively, the RGB data and the black data BD of the right eye image may be displayed. To this end, the present invention includes at least one group of three row lines displaying RGB data to display image data, and display black data BD on at least one row line. In addition, since the row lines displaying black data under the 3D mode display individual data under the 2D mode, the row lines may be formed with the same upper and lower widths as compared with other row lines.

10A and 10B illustrate a third example of a display state of image data of FIGS. 5 to 7.

Referring to FIG. 10A, RGB data of a 2D image is displayed in subpixels of a display panel in a 2D mode along a column direction, and the display order of the RGB data is the 2i-1th column line (c # 1, c # 3). And second column lines c # 2 and c # 4. As a result, the R data of the 2D image is included in the subpixels of the 3i-2 low lines r # 1, r # 4, r # 7 that intersect the 2i-1 column lines c # 1 and c # 3. Is displayed on the subpixels of the 3i-1 lowlines r # 2, r # 5, and r # 8 that intersect the 2i-1th column lines c # 1 and c # 3. Data is displayed, and the B data of the 2D image is included in the subpixels of the third i low lines r # 3, r # 6 and r # 9 that intersect the second i-1 column lines c # 1 and c # 3. Is displayed. The B data of the 2D image is displayed on the subpixels of the 3i-2 low lines r # 1, r # 4, and r # 7 that intersect the second i column lines c # 2 and c # 4. R data of the 2D image is displayed on the subpixels of the 3i-1 low lines r # 2, r # 5, and r # 8 that intersect the second i column lines c # 2 and c # 4. The G data of the 2D image is displayed on the subpixels of the third i row lines r # 3, r # 6, and r # 9 that intersect the second i column lines c # 2 and c # 4.

Referring to FIG. 10B, RGB data and black data BD of a 3D image are displayed in subpixels of the display panel in the 3D mode along the column direction, and the display order of the RGB data is the 2i-1 column line (c #). 1, c # 3 and 2i column lines c # 2 and c # 4. The black data BD is displayed on the subpixels of the fourth i row lines r # 4 and r # 8. The RGB data displayed along the column direction is divided into left eye and right eye image data with the fourth i row lines r # 4 and r # 8 interposed therebetween. Left eye and right eye image data are left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, right eye GRG data, and right eye BRG data along the column direction in the 2i-1 column line (c # 1, c # 3). Is rendered as: The left eye and right eye image data are left eye BRG data, right eye RGB data, left eye GBR data, right eye BRG data, left eye RGB data, and right eye GBR data in the column direction in the 2i column lines c # 2 and c # 4. Is rendered.

As can be seen from this, the present invention displays the 2D image data on all subpixels in the 2D mode to prevent deterioration of the brightness of the 2D image, and in the 3D mode, the subs of the fourth i line (r # 4, r # 8) The black data BD is displayed on the pixels to secure the display interval between the left eye image and the right eye image, thereby increasing the vertical viewing angle of the 3D image. The subpixels of the fourth i row lines r # 4 and r # 8 display the black data BD only in the 3D mode and serve as active black stripes. Furthermore, in this example, the display order of the RGB data is different in the 2i-1th column lines c # 1 and c # 3 and the 2ith column lines c # 2 and c # 4 to prevent color distortion of the 3D image. .

In the third example, as in the first example, the row lines corresponding to the first retarder RT1 and the second retarder RT2 display each row line as a separate 2D image in the 2D mode, and the left eye in the 3D mode. Alternatively, the RGB data and the black data BD of the right eye image may be displayed. To this end, the present invention includes at least one group of three row lines displaying RGB data to display image data, and display black data BD on at least one row line. In addition, since the row lines outputting the black data in the 3D mode display individual data in the 2D mode, the row lines may be formed with the same upper and lower widths as compared with other row lines.

11A and 11B illustrate a fourth example of a display state of image data of FIGS. 5 to 7.

Referring to FIG. 11A, RGB data of a 2D image is displayed in subpixels of a display panel in a 2D mode along a column direction, and the display order of the RGB data is the 2i-1 column lines c # 1 and c # 3. And second column lines c # 2 and c # 4. As a result, the R data of the 2D image is included in the subpixels of the 3i-2 low lines r # 1, r # 4, r # 7 that intersect the 2i-1 column lines c # 1 and c # 3. Is displayed on the subpixels of the 3i-1 lowlines r # 2, r # 5, and r # 8 that intersect the 2i-1th column lines c # 1 and c # 3. Data is displayed, and the B data of the 2D image is included in the subpixels of the third i low lines r # 3, r # 6 and r # 9 that intersect the second i-1 column lines c # 1 and c # 3. Is displayed. The G data of the 2D image is displayed on the subpixels of the 3i-2 low lines r # 1, r # 4, and r # 7 that cross the secondi column lines c # 2 and c # 4. The B data of the 2D image is displayed on the subpixels of the 3i-1 lowlines r # 2, r # 5, and r # 8 that intersect the secondi column lines c # 2 and c # 4. R data of the 2D image is displayed on the subpixels of the third i row lines r # 3, r # 6, and r # 9 that cross the secondi column lines c # 2 and c # 4.

Referring to FIG. 11B, in the 3D mode, subpixels of the display panel display RGB data and black data BD of a 3D image along a column direction, and the display order of the RGB data is the 2i-1 column line (c #). 1, c # 3 and 2i column lines c # 2 and c # 4. The black data BD is displayed on the subpixels of the fourth i row lines r # 4 and r # 8. The RGB data displayed along the column direction is divided into left eye and right eye image data with the fourth i row lines r # 4 and r # 8 interposed therebetween. Left eye and right eye image data are left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, right eye GRG data, and right eye BRG data along the column direction in the 2i-1 column line (c # 1, c # 3). Is rendered. The left eye and right eye image data are in the order of the left eye GBR data, the right eye BRG data, the left eye RGB data, the right eye GBR data, the left eye BRG data, and the right eye RGB data along the column direction in the 2i column lines c # 2 and c # 4. Is rendered as:

As can be seen from this, the present invention displays the 2D image data on all subpixels in the 2D mode to prevent deterioration of the brightness of the 2D image, and in the 3D mode, the subs of the fourth i line (r # 4, r # 8) The black data BD is displayed on the pixels to secure the display interval between the left eye image and the right eye image, thereby increasing the vertical viewing angle of the 3D image. The subpixels of the fourth i row lines r # 4 and r # 8 display the black data BD only in the 3D mode and serve as active black stripes. Furthermore, in this example, the display order of the RGB data is different in the 2i-1th column lines c # 1 and c # 3 and the 2ith column lines c # 2 and c # 4 to prevent color distortion of the 3D image. .

In this fourth example, as in the first example, the row lines corresponding to the first retarder RT1 and the second retarder RT2 display the respective 2D images in the 2D mode under the 2D mode, and the left eye in the 3D mode. Alternatively, the RGB data and the black data BD of the right eye image may be displayed. To this end, the present invention includes at least one group of three row lines displaying RGB data to display image data, and display black data BD on at least one row line. In addition, since the row lines displaying black data under the 3D mode display individual data under the 2D mode, the row lines may be formed with the same upper and lower widths as compared with other row lines.

12 to 14 illustrate an arrangement of RGB subpixels and alignment states of a patterned retarder corresponding thereto according to another embodiment of the present invention.

The subpixels constituting the pixel array are divided into a red subpixel including a red (R) color filter, a green subpixel including a green (G) color filter, and a blue subpixel including a blue (B) color filter. . The red subpixel, the green subpixel, and the blue subpixel are sequentially arranged along the row direction as shown in FIGS. 12 to 14 to form the unit pixel PIX. Three data lines and one gate line are allocated to the unit pixel PIX. For example, in the unit pixel PIX as shown in FIG. 13, the first subpixel SP1 is formed at an intersection area of the data line DL1 and the gate line GL1 to display red R, and the second subpixel. SP2 is formed at the intersection of the data line DL2 and the gate line GL1 to display green G. The third sub-pixel SP3 crosses the data line DL3 and the gate line GL1. It may be formed in the area to display blue (B).

In the pixel array according to this exemplary embodiment, the vertical resolution in the column direction (the same as the number of gate lines) is larger than the general vertical resolution. For example, when the horizontal resolution is selected as '1920' which is a full HD level, the vertical resolution may be determined as 2 times that of '1080' which is a full HD level, that is, '2160'.

The patterned retarder 20 is aligned with the display panel 10 to separate polarized light in units of two low lines. The first retarder RT1 and the second retarder RT2 are formed long in the row direction, respectively. In addition, the first retarder RT1 and the second retarder RT2 are alternately formed along the column direction. The boundary portion of the first retarder RT1 and the second retarder RT2 may overlap the second i row line (i is a positive integer). For example, as illustrated in FIG. 14, a boundary between the first retarder RT1 and the second retarder RT2 may overlap the second and fourth row lines r # 2 and r # 4. As a result, the first retarder RT1 is opposed to the first low line r # 1 and the second retarder RT2 is opposite to the third low line r # 3.

The first retarder RT1 and the second retarder RT2 are not limited thereto, and the first retarder RT1 overlaps the first and second row lines r # 1 and r # 2, and the second The retarder RT2 may be formed to overlap the third and fourth row lines r # 3 and r # 4. In this case, the boundary between the first retarder RT1 and the second retarder RT2 may overlap the boundary between the second i low line and the second i + 1 low line.

15A and 15B show display states of image data targeted to FIGS. 12 to 14.

Referring to FIG. 15A, subpixels of the remaining low lines r # 1 and r # 3 (odd lowline) except for the secondi low lines r # 2 and r # 4 (excellent lowline) in the 2D mode. RGB data of the 2D image is displayed along the row direction, and RGB interpolation data of the 2D image is displayed on the subpixels of the second i row lines r # 2 and r # 4.

In other words, the subpixels of the third i-2 column lines c # 1, c # 4, c # 7, and c # 10 that intersect the odd row lines r # 1 and r # 3 are included in the 2D image. R data is displayed, and the subpixels of the third i-1 low lines c # 2, c # 5, c # 8, and c # 11 intersected with the odd rowlines r # 1 and r # 3. G data of the 2D image is displayed, and the subpixels of the third i low lines c # 3, c # 6, c # 9, c # 12 that intersect the odd rowlines r # 1, r # 3. The B data of the 2D video is displayed.

The subpixels of the third i-2 column lines c # 1, c # 4, c # 7, and c # 10 that intersect the even row lines r # 2 and r # 4 are R in the 2D image. The interpolation data R 'is displayed and the third i-1 row lines c # 2, c # 5, c # 8, c # 11 that intersect the even rowlines r # 2, r # 4 are displayed. The G interpolation data G 'of the 2D image is displayed on the subpixels, and the third i low lines c # 3, c # 6, and c # 9 intersect the even low lines r # 2 and r # 4. The interpolation data B 'of the 2D image is displayed in the subpixels of the c # 12.

The interpolation data R ', G', and B 'may be the same data as the RGB data to be displayed on the odd row lines. In addition, the interpolation data R ', G', and B 'may be data generated by interpolating RGB data to be displayed on the upper and lower radix lines with an interpolation algorithm to improve image quality. Also, the interpolation data R ', G', and B 'may be RGB data different from the RGB data to be displayed on the odd row lines in order to display more information as the vertical resolution is doubled.

Referring to FIG. 15B, in the 3D mode, subpixels of the display panel 11 display RGB data and black data BD of a 3D image along a row direction. The black data BD is displayed on the subpixels of the second i row lines r # 2 and r # 4. The RGB data displayed along the row direction is divided into left eye image data and right eye image data with the second i row lines r # 2 and r # 4 interposed therebetween.

As can be seen from this, the present invention displays 2D image data on all subpixels individually in 2D mode to prevent deterioration of luminance of the 2D image, and black data (BD) on subpixels of the second i-line in 3D mode. ) To increase the vertical viewing angle of the 3D image by securing the display interval between the left and right eye images. The subpixels of the second i row line display the black data BD only in the 3D mode to function as an active black stripe.

In another exemplary embodiment, the odd and even low lines are divided into 3D modes, and RGB data and black data BD of the 3D image are alternately displayed in the unit of the low line, but the present invention is not limited thereto. The first retarder RT1 and the second retarder RT2 may correspond to at least two or more row lines, respectively, and may correspond to at least one or more row lines to display left eye or right eye image data in a 3D mode. It may correspond to at least one row line to display black data BD.

At least one rowline for displaying black data BD may display RGB image data in 2D mode, but may include a portion of rowlines for displaying black data BD in 3D mode. The present invention can improve brightness and improve crosstalk under the 3D mode by appropriately adjusting the number of row lines for displaying black data BD. In addition, since the row lines displaying black data in the 3D mode display the individual RGB image data in the 2D mode, the row lines may be formed with the same upper and lower widths as compared with other row lines.

16 to 18 illustrate an arrangement of RGB subpixels and alignment states of a patterned retarder corresponding thereto according to another embodiment of the present invention.

The subpixels constituting the pixel array are divided into a red subpixel including a red (R) color filter, a green subpixel including a green (G) color filter, and a blue subpixel including a blue (B) color filter. . The red subpixel, the green subpixel, and the blue subpixel are sequentially disposed along the row direction as shown in FIGS. 16 to 18 to form the unit pixel PIX. Three data lines and one gate line are allocated to the unit pixel PIX. For example, in the unit pixel PIX as shown in FIG. 13, the first subpixel SP1 is formed at an intersection area of the data line DL1 and the gate line GL1 to display red R, and the second subpixel. SP2 is formed at the intersection of the data line DL2 and the gate line GL1 to display green G. The third sub-pixel SP3 crosses the data line DL3 and the gate line GL1. It may be formed in the area to display blue (B).

The patterned retarder 20 is aligned with the display panel 10 to separate polarized light in units of four column lines. The first retarder RT1 and the second retarder RT2 are formed long in the column direction, respectively. In addition, the first retarder RT1 and the second retarder RT2 are alternately formed along the row direction. The first retarder RT1 and the second retarder RT2 are opposed to the four column lines, respectively. For example, when the first retarder RT1 is opposed to four column lines including the first to fourth subpixels SP1 to SP4, as shown in FIG. 18, the second retarder RT2 may be the fifth to fifth columns. Four column lines including the eighth sub-pixels SP5 to SP8 may be opposite to each other.

19A and 19B show display states of image data targeting FIGS. 16 to 18.

Referring to FIG. 19A, RGB data of a 2D image is displayed on subpixels of the display panel 11 in a 2D mode along a row direction. In other words, the R of the 2D image is included in the subpixels of the third i-2 column lines c # 1, c # 4, c # 7, and c # 10 that intersect the row lines r # 1 to r # 4. 2D image is displayed on the subpixels of the 3i-1th column line (c # 2, c # 5, c # 8, c # 11) where data is displayed and intersect the row lines r # 1 to r # 4. G data of the 2D image is displayed on the subpixels of the third column line (c # 3, c # 6, c # 9, c # 12) intersecting the row lines r # 1 to r # 4. B data is displayed.

Referring to FIG. 19B, RGB data and black data BD of a 3D image are displayed on the subpixels of the display panel 11 in the 3D mode along the row direction. The black data BD is displayed on the subpixels of the fourth i column lines c # 4, c # 8, and c # 12. RGB data displayed along the column direction is divided into left eye and right eye image data with the fourth i column lines c # 4, c # 8, and c # 12 interposed therebetween. Left and right eye image data is rendered in the order of the left eye RGB data, the right eye GBR data, the left eye BRG data, the right eye RGB data, the left eye GBR data, and the right eye BRG data along the row direction in all row lines (r # 1 to r # 4). do.

As can be seen from this, the present invention displays 2D image data on all subpixels in the 2D mode to prevent deterioration of luminance of the 2D image, and in the 3D mode, the 4i column line (c # 4, c # 8, c #). The black data BD is displayed on the subpixels 12 to secure the display interval between the left eye image and the right eye image, thereby widening the left and right viewing angles of the 3D image. The subpixels of the fourth i column lines c # 4, c # 8, and c # 12 display the black data BD only in the 3D mode and serve as active black stripes.

In yet another exemplary embodiment, the first retarder RT1 and the second retarder RT2 corresponding to four column lines have been described, but the number of corresponding column lines is not limited thereto. The first retarder RT1 and the second retarder RT2 may correspond to four or more column lines, respectively. In this case, the present invention displays 2D image data on all subpixels under 2D mode to prevent a decrease in luminance of the 2D image, and displays RGB data, which is left or right eye image, on three column lines under 3D mode. Black data (BD) can be displayed on more than one column line.

There may be two or more column lines displaying the black data BD. In this case, the present invention may further reduce left and right crosstalk. The column line displaying the black data BD displays a 2D image under a 2D mode. Accordingly, the first retarder RT1 or the second retarder RT2 corresponds to column lines displaying left or right eye image data RGB, respectively, and outputs 2D image data in 2D mode and black data under 3D mode. (BD) is disposed corresponding to the column lines to be displayed.

The left eye or right eye image data displayed to correspond to one first retarder RT1 and one second latitude RT2 in the 3D mode is not limited to only three column lines. That is, RGB data of two or more groups of left eye images and two or more groups of right eye images RGB data may be alternately displayed using three column lines as one group. In this case, the RGB data of the left eye image, the RGB data of the left eye image, the black data BD, or the RGB data of the right eye image, the RGB data of the right eye image BD, etc. It may correspond to one second retarder RT2. Through this configuration, the present invention can further improve luminance under the 3D mode.

That is, in the present embodiment, one first retarder RT1 and the second retarder RT2 respectively correspond to at least four column lines, and in the 2D mode, each column line is displayed as a separate 2D image. . In the 3D mode, the image data is displayed by including at least one group of three column lines representing the RGB data, and the at least one column line displays the black data BD. In addition, since the column lines displaying black data under the 3D mode display individual image data under the 2D mode, the column lines may have the same left and right widths as compared with other column lines.

As described above, the image display apparatus according to the present invention determines the alignment of the patterned retarder and adjusts the data applied to the subpixels according to the arrangement of the RGB subpixels, thereby improving the brightness of the 2D image. The vertical viewing angle of the 3D image can be widened without degrading.

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.

10 display element 20 patterned retarder
30 control unit 40 panel driver
50: polarized glasses

Claims (23)

A display device for selectively implementing 2D and 3D images, including a pixel array having subpixels formed at each intersection of the column line and the row line; And
A patterned retarder in which a first retarder for passing the light from the display element to the first polarization component and a second retarder for passing the second polarization component are alternately formed;
2D image data is displayed on all subpixels in the 2D image implementation;
When the 3D image is implemented, black data is displayed on subpixels of a 4i (i is a positive integer) rowline, and any one of a left eye and a right eye is displayed on the subpixels of the upper three rowlines adjacent to the 4i rowline. One 3D image data is displayed, and the other 3D image data of the left eye and the right eye is displayed on the subpixels of the lower three rowlines adjacent to the fourth i rowline;
The patterned retarder is aligned with the display device to separate polarized light in units of four low lines, and the first and second retarders are respectively opposed to four low lines. Device. The method of claim 1,
And a red subpixel, a green subpixel, and a blue subpixel of the pixel array are sequentially disposed along the column direction to form a unit pixel. delete The method of claim 1,
When the 2D image is implemented, RGB data of the 2D image is displayed in the subpixels of the pixel array along the column direction, and the display order of the RGB data of the 2D image is the same in all column lines;
When the 3D image is implemented, RGB data of the 3D image and the black data are displayed on the subpixels of the pixel array along the column direction, and the display order of the RGB data of the 3D image is the same in all column lines. A video display device. 5. The method of claim 4,
RGB data of the 3D image is divided into left and right eye image data with the fourth i line interposed therebetween;
The left and right eye image data are rendered in the order of left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, left eye GBR data, and right eye BRG data along the column direction in all column lines. . The method of claim 1,
When the 2D image is implemented, RGB data of the 2D image is displayed in the subpixels of the pixel array along the column direction, and the display order of the RGB data of the 2D image is a 3i-2 column line (i is a positive integer). Are different in the 3i-1 column line and the 3i column line;
When the 3D image is implemented, RGB data of the 3D image and the black data are displayed in the subpixels of the pixel array along the column direction, and the display order of the RGB data of the 3D image is in the 3i-2th column line. And 3i-1 column lines and 3i column lines. The method according to claim 6,
RGB data of the 3D image is divided into left and right eye image data with the fourth i line interposed therebetween;
The left eye and right eye image data are rendered in order of left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, left eye GBR data, and right eye BRG data along the column direction in the 3i-2 column line;
The left eye and right eye image data are rendered in order of left eye BRG data, right eye RGB data, left eye GBR data, right eye BRG data, left eye RGB data, and right eye GBR data along the column direction in the 3i-1 column line;
The left eye and right eye image data are rendered in order of left eye GBR data, right eye BRG data, left eye RGB data, right eye GBR data, left eye BRG data, and right eye RGB data along the column direction in the 3i column line. Device. The method of claim 1,
When the 2D image is implemented, RGB data of the 2D image is displayed in the subpixels of the pixel array along the column direction, and the display order of the RGB data of the 2D image is a 2i-1 column line (i is a positive integer). And different in the second i column line;
When the 3D image is implemented, RGB data of the 3D image and the black data are displayed in the subpixels of the pixel array along a column direction, and the display order of the RGB data of the 3D image is in the 2i-1th column line and the first. Image display device characterized in that different in the 2i column line. The method of claim 8,
RGB data of the 3D image is divided into left and right eye image data with the fourth i line interposed therebetween;
The left eye and right eye image data are rendered in order of left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, left eye GBR data, and right eye BRG data along the column direction in the 2i-1 column line;
The left eye and right eye image data are rendered in order of left eye BRG data, right eye RGB data, left eye GBR data, right eye BRG data, left eye RGB data, and right eye GBR data along the column direction in the second column. Device. The method of claim 8,
RGB data of the 3D image is divided into left and right eye image data with the fourth i line interposed therebetween;
The left eye and right eye image data are rendered in order of left eye RGB data, right eye GBR data, left eye BRG data, right eye RGB data, left eye GBR data, and right eye BRG data along the column direction in the 2i-1 column line;
The left eye and right eye image data are rendered in order of left eye GBR data, right eye BRG data, left eye RGB data, right eye GBR data, left eye BRG data, and right eye RGB data along the column direction in the second column. Device. A display device for selectively implementing 2D and 3D images, including a pixel array having subpixels formed at each intersection of the column line and the row line; And
A patterned retarder in which a first retarder for passing the light from the display element to the first polarization component and a second retarder for passing the second polarization component are alternately formed;
2D image data is individually displayed on all subpixels in the 2D image implementation;
When the 3D image is implemented, black data is displayed on subpixels of at least one row line among the row lines corresponding to the first retarder and the second retarder, except for the row line where the black data is displayed. 3D image data of one of the left eye and the right eye is displayed on the subpixels of the remaining rowlines;
The patterned retarder is aligned with the display device to separate polarization in units of at least two low lines, and a boundary portion between the first retarder and the second retarder is a second i low line (i is a positive integer). And an image display device overlapping with each other. The method of claim 11,
The upper and lower widths of the row lines displaying the black data when the 3D image is implemented are the same as the upper and lower widths of each of the remaining row lines. The method of claim 11,
And a red subpixel, a green subpixel, and a blue subpixel of the pixel array are sequentially arranged in a row direction to form a unit pixel. delete The method of claim 11,
When the 2D image is implemented,
RGB data of a 2D image is displayed in the subpixels of the remaining low line except the second i low line (i is a positive integer);
And interpolation data using RGB data of a 2D image displayed on the subpixels of the remaining lowline. The method of claim 11,
When realizing the 2D image,
RGB data of a 2D image is displayed in the subpixels of the remaining low lines except for the second i low line (i is a positive integer),
And sub-pixels different from RGB data displayed in the remaining sub-line subpixels. A display device for selectively implementing 2D and 3D images, including a pixel array having subpixels formed at each intersection of the column line and the row line; And
A patterned retarder in which a first retarder for passing the light from the display element to the first polarization component and a second retarder for passing the second polarization component are alternately formed;
2D image data is displayed on all subpixels in the 2D image implementation;
When the 3D image is implemented, black data is displayed on subpixels of a fourth i column line (i is a positive integer), and any one of the left eye and the right eye is displayed on the subpixels of the left three column lines adjacent to the fourth i column line. One 3D image data is displayed, and the other 3D image data of the left eye and the right eye is displayed in the subpixels of the right three column lines adjacent to the fourth i line;
The patterned retarder is aligned with the display device to separate polarized light in units of four column lines, and the first and second retarders are respectively opposed to four column lines. Device. The method of claim 17,
And a red subpixel, a green subpixel, and a blue subpixel of the pixel array are sequentially arranged in a row direction to form a unit pixel. delete The method of claim 17,
When the 2D image is implemented, RGB data of the 2D image is displayed on the subpixels of the pixel array along a row direction;
When the 3D image is implemented, RGB data of the 3D image and the black data are displayed on the subpixels of the pixel array along a row direction;
And the RGB data of the 3D image is divided into left eye RGB data and right eye RGB data with the fourth i column line therebetween. A display device for selectively implementing 2D and 3D images, including a pixel array having subpixels formed at each intersection of the column line and the row line; And
A patterned retarder in which a first retarder for passing the light from the display element to the first polarization component and a second retarder for passing the second polarization component are alternately formed;
The first and second retarders are arranged to correspond to at least two row lines or at least two column lines;
2D image data is displayed on subpixels of the at least two row lines or at least two column lines when the 2D image is implemented;
When the 3D image is implemented, 3D image data of any one of the left eye and the right eye is displayed on some lines of the subpixels of the at least two or more row lines or at least two column lines, and black data is displayed on the remaining lines except the some lines. Image display device characterized in that. 22. The method of claim 21,
The first and second retarders respectively correspond to at least one or more groups of lines displaying image data in the 2D mode for the 2D image and the 3D mode for the 3D image.
And the lines of one or more groups include lines displaying red data, green data, and blue data. 22. The method of claim 21,
And the remaining lines include at least one of red data, green data, and blue data.

Images