KR20080000803A - Dual view display device and method for driving the same - Google Patents

Abstract

A dual view display device and a method for driving the same are provided to minimize the reduction of image quality by converting display data based on adjacent pixel data using a rendering scheme. A dual view display device includes a data rendering unit(12), a timing controller(14), a display panel(16), and a mask filter. The data rendering unit converts first and second display data using adjacent non-display data, and outputs alternately the converted first and second display data. The timing controller arranges the first and second display data from the data rendering unit and outputs the arranged result. The display panel displays the first and second display data from the timing controller in first and second pixels, respectively. The mask filter displays the first and second images, which are displayed in the first and second pixels, in first and second view angle areas, respectively.

Description

DUAL VIEW DISPLAY DEVICE AND METHOD FOR DRIVING THE SAME}

1 is a cross-sectional view showing a dual view display device according to an embodiment of the present invention.

2 is a block diagram illustrating a dual view display device according to an exemplary embodiment of the present invention.

3 is a diagram illustrating source data input to a data rendering unit illustrated in FIG. 2;

4 is a detailed block diagram of the data rendering unit shown in FIG. 2;

<Description of the Simple Symbols in the Drawing>

10 computer system 12 data rendering unit

14 timing controller 20 first frame memory

22: second frame memory 24: first data rendering unit

26: second data rendering unit MUX: multiplexer

40: display panel 80: mask filter

The present invention relates to a display device of the present invention, and more particularly, to a dual view display device capable of displaying different images according to a viewing angle and a driving method thereof.

Popular flat panel display devices include liquid crystal display (LCD) using liquid crystal, plasma display panel (PDP) using discharge of inert gas, organic electroluminescent display (OLED) using organic light emitting diode, and the like. to be. Among them, the plasma display panel is applied only to a large TV, whereas the liquid crystal display and the organic electroluminescent display are applied to many fields in various sizes from small to large, such as mobile phones, portable computers, monitors, and TVs.

Herein, the liquid crystal display uses the electrical and optical characteristics of the liquid crystal. This is because liquid crystals have anisotropic properties that are different in physical property values such as refractive index and dielectric constant, and have an advantage of easily controlling molecular arrangement and optical properties. In other words, the liquid crystal display displays an image by adjusting the light transmittance by changing the arrangement direction of the liquid crystal molecules according to the electric field.

In more detail, the liquid crystal display displays an image through a liquid crystal panel in which a plurality of pixels are arranged in a matrix. Each pixel of the liquid crystal panel implements a desired color by using a combination of red, green, and blue sub-pixels that adjust light transmittance by varying a liquid crystal array according to a data signal. Each subpixel charges the data signal supplied to the pixel electrode through the thin film transistor and the difference voltage of the common voltage supplied to the common electrode to drive the liquid crystal. Since the liquid crystal panel is a non-light emitting device, the liquid crystal display includes a backlight unit for supplying light from the rear side of the liquid crystal panel.

Meanwhile, recently, in order to satisfy the needs of various users, development of a dual view liquid crystal display capable of displaying different images according to left and right viewing angles through one liquid crystal display is required.

The user's request may be similarly applied to not only a liquid crystal display but also other display devices such as an organic light emitting display (OLED), a field emission display (FED), and a plasma display device (PDP).

Accordingly, an aspect of the present invention is to provide a dual view display device and a driving method thereof capable of displaying different images without reducing the resolution according to the viewing angle through one screen.

To this end, the dual view display device according to an aspect of the present invention comprises the steps of: converting the first display data using non-display data adjacent to the first display data; Converting the second display data using non-display data adjacent to the second display data; Alternately outputting the converted first display data and the converted second display data; Supplying the converted first display data to a first pixel of a display panel and the converted second display data to a second pixel of the display panel; And dividing the first image displayed on the first pixels of the display panel and the second image displayed on the second pixels into first and second viewing angle regions.

The converting of the first display data may include sampling the first display data and first non-display data adjacent to the first display data from source data of a first image; And multiplying and adding the first display data and the first non-display data, respectively, to a predetermined filter coefficient value and outputting the converted first display data.

The converting the second display data may include sampling the second display data and second non-display data adjacent to the second display data from source data of a second image; And multiplying and adding the second display data and the second non-display data, respectively, to a predetermined filter coefficient value and outputting the converted second display data.

The converted first display data is supplied to a first pixel of a display panel having a structure in which first and second pixels are alternately arranged, and the converted second display data is supplied to a second pixel of the display panel. Each of the first and second display data and the first and second non-display data includes red, green, and blue data.

According to another aspect of the present invention, a dual view display device converts first display data using adjacent non-display data, converts second display data using adjacent non-display data, and converts the first display data into the converted first display data. A data rendering unit configured to alternately output the converted second display data; A timing controller for aligning and outputting first and second display data from the data rendering unit; A display panel which displays the first display data from the timing controller in a first pixel and the second display data in a first pixel; And a mask filter configured to separate the first image displayed on the first pixels of the display panel and the second image displayed on the second pixels into first and second viewing angle regions.

The data rendering unit converts the first display data using non-display data adjacent to the first display data; A second data rendering unit converting second display data using non-display data adjacent to the second display data; And a selection unit for alternately outputting the converted first display data and the converted second display data.

The first data rendering unit samples the first display data and the first non-display data adjacent to the first display data from the source data of the first image, and previews the sampled first display data and the first non-display data in advance. Each of the set filter coefficients is multiplied and added to output the converted first display data.

The second data rendering unit samples the second display data and the second non-display data adjacent to the second display data from the source data of the second image, and previews the sampled second display data and the second non-display data in advance. Each of the set filter coefficients is multiplied and added to output the converted second display data.

The mask filter has a structure in which a blocking region in which a blocking pattern is formed and a transmission region between the blocking patterns are fixed, and the blocking region and the transmission region are repeated.

In contrast, the mask filter includes first and second regions for switching the liquid crystal layer to a blocking mode and a transmission mode depending on whether a voltage is applied; The first and second regions have a structure in which they are alternately repeated.

Other features and advantages of the present invention in addition to these features of the present invention will become apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 1 to 4.

1 illustrates a cross-sectional structure of a dual view display device according to an exemplary embodiment of the present invention.

The dual view display device illustrated in FIG. 1 includes a display panel 40 displaying an image and a mask filter 80 separating the images displayed on the display panel 40 in different directions.

The display panel 40 displays an image through the pixel matrix. The pixel matrix has a structure in which the first and second pixels P1 and P2, that is, the odd pixels and the even pixels are alternately arranged in the horizontal direction. Here, each of the first and second pixels P1 and P2 includes R, G, and B sub pixels. In addition, the plurality of first pixels P1 constitute a first pixel line arranged in the vertical direction, and the second pixel line in which the plurality of second pixels P2 are arranged in the vertical direction. Accordingly, the pixel matrix of the display panel 40 has a structure in which the first and second pixel lines are alternately arranged in the horizontal direction. As the display panel 40, any one of a liquid crystal panel, a plasma display panel, an EL (Electro-Luminescence) display device, and a field emission display device may be used.

The mask filter 80 has a structure in which the first and second regions D1 and D2 are alternately arranged in the horizontal direction. Each of the first and second regions D1 and D2 is formed in a vertical line shape that is long in the vertical direction like the first and second pixel lines of the display panel 40. The first and second regions D1 and D2 are aligned such that their boundary portions overlap with portions of each of the first and second pixels P1 and P2, for example, the central portion. The horizontal pitch (line width) of each of the first and second regions D1 and D2 varies depending on the viewing angle, but is mainly set to be equal to the horizontal pitch (line width) of each of the first and second pixels P1 and P2. . The mask filter 80 may have a structure in which a blocking pattern is formed only in the first region D1 so that the first region D1 is fixed to the blocking region and the second region D2 is fixed to the transmission region. Of course, the mask filter 80 may have a structure in which the first and second regions D1 and D2 are opposite to each other. Alternatively, the mask filter 80 may have a switching panel structure using a liquid crystal capable of controlling the first and second regions D1 and D2 in a blocking mode and a transmission mode and switching modes according to whether a voltage is applied.

For dual view, the data signal of the first image A is supplied to the first pixels P1 of the display panel 40, and the data signal of the second image B is supplied to the second pixels P2. In the mask filter 80, it is assumed that the first region D1 is a blocking region and the second region D2 is a transmission region. The first image A displayed on the first pixels P1 of the display panel 40 passes through the second region D2 of the mask filter 80 in the right viewing angle direction and is displayed in the right viewing angle region. The second image B displayed on the second pixels P2 of the display panel 40 passes through the second area D2 of the mask filter 80 in the left viewing angle direction and is displayed in the left viewing angle area. In other words, the first image A of the first pixels P1 partially overlapped with the left side of the second area D2 of the mask filter 80 is right, and the right side and part of the second area D2 is right. By transmitting the second image B of the overlapping second pixels P1 to the left side, the first and second images A and B from the display panel 40 are separated into left and right viewing angle regions.

Accordingly, the user located in the right viewing angle area can view the first image A displayed by the combination of the first pixels P1 of the display panel 40 through the mask filter 80, and the user located in the left viewing angle area. The second image B displayed as a combination of the second pixels P2 of the display panel 40 may be viewed through the mask filter 80.

However, since each of the first and second images A and B is displayed by half of the pixels in the display panel 40, the resolution may be deteriorated and thus the image quality may be deteriorated. The data processor supplying data to the display panel 40 samples only the odd data to be supplied to the first pixels P1 of the display panel 40 from the source data of the first image A. Only even data to be supplied to the second pixels P2 of the display panel 40 is sampled from the source data of B), and then the odd data of the sampled first image A and the even data of the second image B are sampled. Are alternately arranged and supplied to the display panel 40. Here, the data processor ignores even data of the unsampled first image A and odd data of the second image B without consideration. Accordingly, the first and second images A and B displayed on the display panel 40 generate a sudden voltage difference between adjacent data of the same image due to the data ignored by the data processing unit, thereby resulting in image quality such as aliasing. There is a fear that a defect may occur.

In order to minimize such a poor image quality, the data processing apparatus according to the present invention will be supplied to the display panel 40 using a rendering method that converts the sampled data in consideration of data of adjacent pixels to be ignored.

2 is a block diagram illustrating a dual view display device according to an exemplary embodiment of the present invention.

The dual view display device shown in FIG. 2 includes a data rendering unit 12 and a timing controller 14 connected between the computer system 10 and the display panel 16.

The computer system 10 supplies source data R, G, and B of each of the first and second images A and B to be supplied to the display panel 16. In addition, the computer system 10 includes a dot clock DCLK, which is a transmission clock of a vertical sync signal Vsync, a horizontal sync signal Hsync, and source data R, G, B together with the source data R, G, and B. And a plurality of control signals CS including a data enable signal DE supporting a valid section of data.

The data rendering unit 12 is different from the display data to be displayed on the display panel 40 in the source data R, G and B of each of the first and second images A and B supplied from the computer system 10. Separate and display the non-display data to be displayed. The display data is converted in consideration of the non-display data adjacent to the display data. For example, as shown in FIG. 3, when the R, G, and B data of the even pixel EP are display data, the R, G, and B data of the even pixel EP are adjacent to the left and right sides of the odd pixel OP. The R, G, and B data are each considered and converted. Then, the conversion data R ', G', and B 'are supplied to the timing controller 14 so that the display data of the converted first image A and the display data of the converted second image B are alternated. The data rendering unit 12 also transmits a plurality of control signals CS from the computer system 10 to the timing controller 14.

The timing controller 14 properly aligns the converted data R ', G', and B 'of the first and second images A and B supplied from the data rendering unit 12 to the display panel 16. The data driver is supplied to the data driver of the display panel 16. In addition, the timing controller 14 uses a plurality of control signals CS supplied through the data rendering unit 12 to control the data driver of the display panel 16 and the display panel 16. Generates and supplies a plurality of gate control signals for controlling the gate driver of the &quot;

The display panel 16 displays the conversion data R ′, G ′, and B ′ of the first and second images A and B supplied from the timing controller 14 through the gate driver and the data driver. In other words, the display panel 16 displays the converted data of the first image A on the first pixels P1, that is, the odd (or even) pixels, and displays the second pixels P2, that is, the even (or Odd) The converted data of the second image B are displayed on the pixels.

Accordingly, the display panel 16 displays the display data of the first image A and the display data of the second image B in consideration of non-display data, thereby reducing the voltage difference between adjacent data in the same image, thereby improving image quality.

4 is a block diagram illustrating in detail the data rendering unit 12 shown in FIG. 2.

The data rendering unit 12 shown in FIG. 4 includes first and second frame memories 20 and 22 that store source data R, G, and B of the first and second images A and B, respectively. First and second data rendering units 24 and 26 connected to the first and second frame memories 20 and 22, and a multiplexer commonly connected to the first and second data rendering units 24 and 26. MUX).

The first frame memory 20 stores the source data R, G, and B of the first image A from the computer system 10. The second frame memory 20 stores the source data R, G, and B of the second image B from the computer system 10.

The first data rendering unit 24 converts the display data from the source data R, G, and B of the first image A from the first frame memory 20 to a rendering method considering the non-display data. For example, the first data rendering unit 24 displays odd data which is display data in source data R, G, and B of the first image A from the first frame memory 20, and the odd data and the left and right. The two even data, which are two adjacent non-display data, are sampled respectively. The first data rendering unit 24 converts and outputs the odd data by multiplying even data adjacent to the odd data to the left and right by a predetermined filter coefficient and adding the values multiplied by the filter coefficient. For example, filter coefficients defined in even data adjacent left and right adjacent to the odd data are shown in Tables 1 to 3 below.

Filter coefficients for left undisplayed data Filter coefficients for display data Filter coefficients for right non-display data 1/4 1/2 1/4

Referring to Table 1, the first data rendering unit 24 multiplies the odd data, which is the display data, by a coefficient value of 1/2, and the coefficient value of 1/4, for each even data, which is adjacent to the left and right sides. Multiply by Here, the coefficient values of the left and right data are generally set to be the same. The first data rendering unit 24 adds both the odd data value multiplied by the filter coefficient values and the left data value and outputs the converted odd data OR, OG, and OB.

Filter coefficients for left undisplayed data Filter coefficients for display data Filter coefficients for right non-display data 1/8 3/4 1/8

Referring to Table 1, the first data rendering unit 24 multiplies the odd data by 3/4, and multiplies the left and right adjacent data by 1/8. The first data rendering unit 24 adds the odd data values multiplied by the filter coefficient values and the left data values to output the converted odd data OR, OG, and OB.

Filter coefficients for left undisplayed data Filter coefficients for display data Filter coefficients for right non-display data 1/16 7/8 1/16

Referring to Table 1, the first data rendering unit 24 multiplies the odd data by 7/8, and multiplies the left and right adjacent even data by 1/16. The first data rendering unit 24 adds the odd data value multiplied by the filter coefficient values and the left data value and outputs the converted current odd data OR, OG, and OB.

The second data rendering unit 26 converts the display data from the source data R, G, and B of the second image B from the second frame memory 22 into a rendering method considering the non-display data. For example, the second data rendering unit 26 may include even data as display data, source data R, G, and B of the second image B from the second frame memory 22, and left and right data. The two odd data, which are two non-display data adjacent to each other, are sampled respectively. The second data rendering unit 26 converts the even data ER, EG, and EB by multiplying the odd data left and right adjacent to the even data by a predetermined filter coefficient and adding the values multiplied by the filter coefficient. The filter coefficients defined in the even data adjacent to the left and right data are as shown in Tables 1 to 3, for example.

The multiplexer MUX is configured to control the odd data data OR, OG, and OB of the first image A from the first data rendering unit 24 and the second image B from the second data rendering unit 26. Even data ER, EG, and EB are alternately selected and output to the timing controller 14.

As described above, the dual view display device and the driving method thereof display the first and second images on the display panel by converting the sampled display data into display data considering adjacent non-display data. Accordingly, the image quality of the first and second images separated into the left and right viewing angle regions through the mask filter is improved.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (11)

Converting the first display data using non-display data adjacent to the first display data; Converting the second display data using non-display data adjacent to the second display data; Alternately outputting the converted first display data and the converted second display data; Supplying the converted first display data to a first pixel of a display panel and the converted second display data to a second pixel of the display panel; And dividing the first image displayed on the first pixels of the display panel and the second image displayed on the second pixels into first and second viewing angle regions. Method of driving. The method of claim 1, Converting the first display data Sampling the first display data and first non-display data adjacent to the first display data from source data of a first image; And multiplying and adding the first display data and the first non-display data to a predetermined filter coefficient value and outputting the converted first display data as the converted first display data. The method of claim 2, Converting the second display data Sampling the second display data and second non-display data adjacent to the second display data from source data of a second image; And multiplying and adding the second display data and the second non-display data to a predetermined filter coefficient value and outputting the converted second display data as the converted second display data. The method of claim 3, wherein And the first and second display data and the first and second non-display data each include red, green, and blue data. Convert first display data using adjacent non-display data, convert second display data using adjacent non-display data, and alternately output the converted first display data and the converted second display data. A data rendering unit; A timing controller for aligning and outputting first and second display data from the data rendering unit; A display panel for displaying the first display data from the timing controller in a first pixel and the second display data in a first pixel; And a mask filter configured to separately display the first image displayed on the first pixels of the display panel and the second image displayed on the second pixels into first and second viewing angle regions. Device. The method of claim 5, The data rendering unit A first data rendering unit converting the first display data using non-display data adjacent to the first display data to the left and right; A second data rendering unit converting the second display data using non-display data adjacent to the second display data to the left and right; And a selector configured to alternately output the converted first display data and the converted second display data. The method of claim 6, The first data rendering unit The first display data and the first non-display data adjacent to the first display data are sampled from the source data of the first image. And multiplying and adding the multiplication and outputting the converted first display data. The method of claim 7, wherein The second data rendering unit The second display data and the second non-display data adjacent to the second display data are sampled from the source data of the second image, and the sampled second display data and the second non-display data are respectively set with predetermined filter coefficient values. And multiplying and adding the multiplication and outputting the converted second display data. The method of claim 8, And the first and second display data and the first and second non-display data each include red, green, and blue data. The method of claim 5, The mask filter has a structure in which a blocking region in which a blocking pattern is formed and a transmission region between the blocking patterns are fixed, and the blocking region and the transmission region are repeated. The method of claim 5, The mask filter is First and second regions for switching the liquid crystal layer to a blocking mode and a transmission mode depending on whether a voltage is applied; And the first and second regions are alternately repeated.

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