KR100900061B1 - Display device having high-resolution and driving method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device having a high resolution capable of improving display quality by enabling high resolution driving of a display device that is difficult to manufacture small pixels, and a driving method thereof.

According to an exemplary embodiment of the present invention, a display device having a high resolution includes four subpixel regions arranged in two horizontal and two matrix forms, and a red subpixel disposed in a first subpixel region among the four subpixel regions. M horizontally pixels including a green subpixel disposed in a second subpixel region among the four subpixel regions, and a blue subpixel disposed in a third subpixel region among the four subpixel regions; A display module disposed in the form of n vertical columns; A red virtual subpixel signal, a green virtual subpixel signal, and a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and each position of the subpixels disposed in the display module A signal supply unit generating virtual pixel signals matching the subpixels with position information matching the information; The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A position display control unit for extracting a subpixel corresponding to 1: 1 to the subpixel and supplying the extracted subpixel to the matched subpixel; And a power supply unit supplying a constant voltage to the display module.

Description

Display device having high resolution and driving method thereof {DISPLAY DEVICE HAVING HIGH-RESOLUTION AND DRIVING METHOD THEREOF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a driving method thereof, and more particularly, to a display device having a high resolution capable of improving display quality by enabling high resolution driving of a display device that is difficult to manufacture small pixels, and a driving method thereof.

Recently, various displays have been developed with increasing interest in high performance of a device for displaying a graphic or video image.

The display device includes a liquid crystal display (LCD), a field emission display (FED), a plasma display panel (PDP), and a light emitting diode (LED) display device. There is this.

In general, the display module of the display device has a pixel structure as shown in FIG. 1.

Referring to FIG. 1, a display module of a display device includes a plurality of pixels 10 arranged in a matrix, and each pixel 10 includes a red subpixel R, a green subpixel G, and a blue subpixel. (B). Each of the subpixels R, G, and B is supplied with respective luminance signals, and the colors of the entire pixel 10 are mixed with colors generated in the subpixels R, G, and B according to the individual luminance signals. Is expressed.

Since the display quality of the display device is improved as the resolution is increased, the technology for forming more pixels 10 in the same area by making the sizes of the pixels 10 smaller is a key issue. By the way, in the case of LCD, FED, PDP, the small size of the pixels 10 is easy to manufacture, but since the LED display device is a device that acts as a kind of light bulb, there is a limit to the small size of the LED display device to other display devices Compared with the advantages of faster response speed, it is difficult to achieve high resolution.

In order to solve this problem, a time division virtual pixel method has been proposed.

The time division virtual pixel method implements virtual pixels using physically formed pixels, and divides time to drive both physical pixels and virtual pixels.

Referring to FIG. 2, the physical pixel groups 20a to 20d are pixels formed to actually serve as one pixel, like the pixel 10 shown in FIG. 1, and two red subpixels R and one green. Subpixel G and one blue subpixel B.

The first virtual pixel group 30a to 30f includes subpixels of the left and right adjacent physical pixel groups 20a to 20d, and the second virtual pixel group 40a to 40b includes the vertically adjacent physical pixel group. Subpixels 20a to 20d, and the third virtual pixel group 50a to 50c includes subpixels of the physical pixel groups 20a to 20d adjacent to each other vertically, horizontally, and horizontally.

That is, according to the time division virtual pixel method, since three virtual pixel groups 30a to 50c are added to the conventional physical pixel groups 20a to 20d, the number of pixel groups increases four times. Accordingly, in the time division virtual pixel scheme, the distance between the left, right, and top and bottom adjacent pixels is 50% of the physical pixel interval, respectively. do. In this case, since the physical pixel groups 20a to 20d and the virtual pixel groups 30a to 50c share the same pixels with each other, they are not driven simultaneously but sequentially driven. Therefore, in the time division virtual pixel scheme, four times as long to drive each pixel group is required. However, since the highest speed is generally used to supply a single signal to a pixel, it is not only technically difficult to drive a high-speed clock that supplies four signals quickly, but also causes an operation instability. have. In addition, when driving the virtual pixels 30a to 50c, since the pixels that are actually driven are the physical pixels 20a to 20d, the physical pixels 20a to 20d are driven in an overlapping manner so that the image quality is clear. The problem is that it looks cloudy.

Due to these problems, the time-division virtual pixel method is less effective than the theory, and its use is declining in the industry recently. Therefore, display devices, such as LED displays, which are difficult to manufacture small pixels, have a high resolution. New technologies are needed to make this happen.

Accordingly, an object of the present invention is to provide a display device having a high resolution capable of improving display quality by enabling high resolution driving of a display device that is difficult to manufacture small pixels, and a driving method thereof.

In order to achieve the above object, a display device having a high resolution according to an exemplary embodiment of the present invention includes four subpixel regions arranged in two horizontal and two vertical matrix forms, and a first subpixel among the four subpixel regions. A red subpixel disposed in a region, a green subpixel disposed in a second subpixel region among the four subpixel regions, and a blue subpixel disposed in a third subpixel region among the four subpixel regions. A display module in which pixels are arranged in a matrix form m horizontally and n vertically; A red virtual subpixel signal, a green virtual subpixel signal, and a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and each position of the subpixels disposed in the display module A signal supply unit generating virtual pixel signals matching the subpixels with position information matching the information; The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A position display control unit for extracting a subpixel corresponding to 1: 1 to the subpixel and supplying the extracted subpixel to the matched subpixel; And a power supply unit supplying a constant voltage to the display module.

According to another exemplary embodiment of the present invention, a display device having a high resolution includes four subpixel regions arranged in two horizontal and two vertical matrix forms and a red subpixel disposed in a first subpixel region among the four subpixel regions. A pixel, a green subpixel disposed in a second subpixel region of the four subpixel regions, a blue subpixel disposed in a third subpixel region of the four subpixel regions, and the four subpixel regions A display module disposed in a fourth subpixel area among the pixels including an additional subpixel having the same color as any one of the red, green, and blue subpixels in a horizontal m and n vertical matrix forms; A red virtual subpixel signal, a green virtual subpixel signal, a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and an additional virtual subpixel signal of the same color as the additional subpixel. A signal supply unit configured to generate virtual pixel signals matching the respective subpixels with position information corresponding to the position information of each of the subpixels disposed in the display module; The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A position display control unit for extracting a subpixel corresponding to 1: 1 to the subpixel and supplying the extracted subpixel to the matched subpixel; And a power supply unit supplying a constant voltage to the display module.

The subpixels in the display module are disposed at equal intervals from each other.

The position display control unit matches a subpixel with a virtual pixel signal having position information matched with each other among the virtual pixel signals and the subpixels, and any one of the virtual subpixel signals included in the matched virtual pixel signal. Virtual subpixel signal of-the position information in the matched virtual pixel signal of the virtual subpixel signal is equal to the position information of the matched subpixel in the pixel containing the matched subpixel, and the virtual subpixel A signal signal matcher 1: 1 with the matched subpixels, the pixel signal aligner for extracting the remaining virtual subpixel signals; A V-RAM in which the extracted virtual subpixel signal is recorded; And a pixel signal supply unit for aligning the virtual subpixel signal recorded in the V-RAM according to the position of the matched subpixel to supply the matched subpixel.

According to an embodiment of the present disclosure, a method of driving a display device having a high resolution includes four subpixel regions arranged in two horizontal and two vertical matrix forms and disposed in a first subpixel region among the four subpixel regions. A pixel comprising a red subpixel, a green subpixel disposed in a second subpixel region of the four subpixel regions, and a blue subpixel disposed in a third subpixel region of the four subpixel regions, is horizontal A driving method of a display device having a high resolution including a display module arranged in m and n matrix forms, the red virtual subpixel signal arranged in the same color order as the subpixels positioned in the pixel, and green A virtual subpixel signal and a blue virtual subpixel signal, the position information of each of the subpixels disposed in the display module; Generating virtual pixel signals matching each of the subpixels with matching position information; And matching a virtual pixel signal having a location information matched with each other among the virtual pixel signals and the subpixels and a subpixel, and virtual virtual pixel of any one of the virtual subpixel signals included in the matched virtual pixel signal. Signal-the positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in the pixel containing the matched subpixel, and the virtual subpixel signal is matched And correspondingly matching the subpixels 1: 1 to supply the matched subpixels.

The second step may include: matching a virtual pixel signal with a subpixel having position information matching among the virtual pixel signals and the subpixels; A virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal, wherein position information in the matched virtual pixel signal of the virtual subpixel signal is within a pixel including the matched subpixel Extracting the virtual subpixel signals equal to the position information of the matched subpixels, wherein the virtual subpixel signal corresponds 1: 1 with the matched subpixel, and removing the remaining virtual subpixel signals; Recording the extracted virtual subpixel signal; And supplying the recorded virtual subpixel signal to the subpixel that is aligned with the position of the matched subpixel.

According to the display device and the driving method thereof of the present invention, four times the resolution is realized compared to the resolution according to the actual driving of the pixel. Accordingly, the present invention enables high resolution driving even in a display device in which small pixels are difficult to be manufactured, such as an LED display device, thereby improving display quality of the display device.

In addition, according to the present invention, unlike the conventional time division virtual pixel method, since there is no overlapping pixel, the structure is much simpler, so that the implementation is easy and the image quality is clear. In addition, according to the present invention, since the time is not required 4 times as in the time division virtual pixel method, the operation is stable by the low speed clock, and the high speed operation is possible as the time is not required 4 times.

Other objects and advantages of the present invention in addition to the above object will be 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. 3 to 7.

3 is a diagram illustrating a display device according to an exemplary embodiment of the present invention.

Referring to FIG. 3, a display device according to an exemplary embodiment of the present invention includes a display module 100 displaying an image and a position display controller (LDC) for arranging and supplying pixel signals to the display module 100 ( 200, a signal supply unit 300 for converting an image signal into a digital signal to supply the LDC 200, and a power supply unit 400 for supplying power to the display module 100.

The display module 100 includes a plurality of pixels 110, and a plurality of display modules 100 are used according to the size of the display device. Each pixel 110 includes a red subpixel 111, a green subpixel 112, and a blue subpixel 113. In addition, the pixels 110 may further include an additional subpixel of any one of red, green, and blue subpixels, and FIG. 3 illustrates an example in which a red subpixel 114 is additionally included. These subpixels are arranged in a matrix form on the display module 100 and are arranged to have the same spacing as a whole. That is, the intervals P1 with the left and right neighboring subpixels are all the same, and the intervals P2 with the up and down neighboring subpixels are all the same. The subpixels 111 to 114 include light emitting devices having a color corresponding to the color of each subpixel, and in the case of an LED display device, the red, green, and blue subpixels each include red, green, and blue LEDs.

The signal supply unit 300 is a set-top box that converts signals such as an image signal for driving the display module 100 into digital signals and supplies them to the LDC 200. In comparison, the digital signal corresponding to the virtual resolution of 2 times and 4 times of the horizontal and vertical respectively is supplied to the LDC 200. For example, if the display module 100 is configured to have a resolution of 640 × 480, the signal supply unit 300 supplies a digital signal according to a virtual resolution of 1280 × 960 to the LDC 200. That is, the signal supply unit 300 generates a virtual pixel signal corresponding to four times the number of pixel signals required for the display module 100. In this case, one virtual pixel signal includes four virtual subpixel signals. The four virtual subpixel signals include the red virtual subpixel signal, the green virtual subpixel signal, the blue virtual subpixel signal, and the red, green, and blue virtual subpixel signals of the display module 100 in the same manner as the actual physical pixel configuration. An additional virtual subpixel signal of the same color as the additional subpixel is included. These virtual subpixel signals are arranged in the same color order as the subpixels.

The LDC 200 is individually connected to each display module 100, and arranges the signals supplied from the signal supply unit 300 to correspond to the positions of the subpixels and supplies them to the display module 100. In this case, since the virtual pixel signal supplied from the signal supply unit 300 is a signal generated to match the four times the resolution of the display module 100 as described above, in the LDC 200, the virtual pixel signals are displayed in the display module 100. Must be adjusted to match the actual pixel. To this end, the LDC 200 matches one virtual pixel signal to one subpixel of the display module 100.

The matching virtual pixel signal and the subpixel have the same position information as shown in FIG. 4.

FIG. 4A illustrates position information S11 to S44 of a virtual pixel signal in virtual resolution, and FIG. 4B illustrates position information P11 to P44 of subpixels in the display module 100. Referring to FIG. Drawing. In the drawing, the virtual pixel signal having the location information of S11 is matched to the subpixel of P11 having the same location information in the display module 100. At this time, since one virtual pixel signal includes four virtual subpixel signals R1, G, B, and R2, one of the virtual subpixel signals R1, G, B, and R2 must be extracted. To do this, the positional information of pixels of matching subpixels is examined. Referring to (b), it can be seen that the subpixel of P11 that matches the virtual pixel signal of S11 is located at the upper left in the pixel, and thus, the virtual subpixel signal at the same position is extracted. That is, the signal R1 located at the upper left of the virtual subpixel signals R1, G, B, and R2 is extracted and supplied to the subpixel of P11. In this case, as described above, since the color order of the virtual subpixel signals is arranged in the same order as the color order of the subpixel, the virtual subpixel signal and the subpixel at the same position have the same color information. The corresponding method of the virtual subpixel signal and the subpixel will be described in more detail with reference to the embodiment of FIG. 5.

In FIG. 5A, virtual pixel signals 510, 520, 530, and 540 are illustrated, and in FIG. 5B, one pixel 600 of the display module 100 is illustrated. Since one virtual pixel signal is matched to one subpixel of the display module 100, four virtual pixel signals 510, 520, 530, and 540 match one pixel 600. Each of these four virtual pixel signals 510, 520, 530, 540 is supplied to subpixels 601, 602, 603, 604 at the same position as their position within one pixel 600. At this time, the virtual subpixel signal other than the position corresponding to the subpixel among the virtual pixel signals is removed, and only the virtual subpixel signal at the corresponding position is supplied to the subpixel.

That is, the first red virtual subpixel signal 511 of the first virtual pixel signal 510 is supplied to the first red subpixel 601, and green and blue including the remaining second red virtual subpixel signal 514. The virtual subpixel signals 512 and 513 are removed.

The green virtual subpixel signal 522 of the second virtual pixel signal 520 is supplied to the green subpixel 602, and the remaining first red, blue, and second red virtual subpixel signals 521, 523, 524 is removed.

Among the third virtual pixel signals 530, the blue virtual subpixel signal 533 is supplied to the blue subpixel 603, and the remaining first red, green, and second red virtual subpixel signals 531, 532, 534 ) Is removed.

Similarly, among the fourth virtual pixel signals 540, the second red virtual subpixel signal 544 is supplied to the second red subpixel 604, and the remaining first red, green, and blue virtual subpixel signals 541. , 542, 543 are removed.

Since each virtual subpixel signal includes an individual luminance signal, the luminance signal corresponding to four times the actual resolution is supplied to the subpixels of the present invention by the above-described driving method of the present invention. That is, the luminance resolution represented by the subpixels according to the present invention is four times the actual resolution. In this case, since only one virtual subpixel signal of the virtual pixel signals corresponds to the actual subpixel, the virtual subpixel signals that are eliminated may theoretically appear to decrease the color expression capability of the display device. However, even in the prior art in which the pixel signal and the pixel correspondence ratio are 1: 1, almost 90% or more of the colors represented by adjacent pixels are the same color, and thus, one virtual subpixel signal is extracted from each of the four virtual pixel signals. Therefore, in the present invention, which implements color through one pixel, the color representation ability is not greatly reduced. In addition, the human eye is, in fact, sensitive in distinguishing luminance, but dull in distinguishing color. Using this point, in actual digital broadcasting, the standard of the YUV ratio representing the ratio of the luminance signal, the first color component, and the second color component is defined as 2: 1: 1, and 4: 1: 1 as a compressed video for broadcasting. The luminance signal is more important than the color signal, such as transmitting up to the image of the. Therefore, according to the display device and the driving method of the present invention, the user sees an image having improved display quality according to the luminance resolution increased by four times.

In addition, when comparing the present invention and the conventional time division virtual pixel method, in the present invention, since there are no sub-pixels that are used repeatedly, the structure is simple, the image quality is clear, and the clock is not necessary because the time is not required 4 times. It is possible to operate with stable operation and high speed driving is possible as it does not take 4 times time.

6A is a diagram illustrating another arrangement example of subpixels formed in one pixel.

The subpixels shown in FIG. 3 have an arrangement structure as shown in FIG. 6B. That is, when one pixel is divided into subpixel areas 110a through 110d having a 2 × 2 matrix form, one subpixel is disposed in each of the subpixel areas 110a through 110d. However, in another arrangement example of FIG. 6A, subpixels are disposed only in three subpixel regions 110a through 110c among the four subpixel regions 110a through 110d. That is, only red, green, and blue subpixels are disposed in one pixel, and no additional subpixels are disposed. In this case, the virtual pixel signal does not include the additional virtual subpixel signal to have the same structure as the subpixel.

FIG. 7 is a configuration diagram of the LDC 200 shown in FIG. 3.

Referring to FIG. 7, the LDC 200 may include a data receiver 210, a RAM write logic 220, a pixel signal aligner 230, a V-RAM 240, and read logic 250. , And a pixel signal supply unit 260.

The data receiver 210 receives a digital signal from the signal supply unit 300, converts the digital signal into a standard parallel signal, and supplies the digital signal to the RAM write logic 220. The RAM write logic 220 receives a standard parallel signal from the data receiver 210, generates a recordable address in RAM, and generates RAM timing required for writing. The pixel signal aligner 230 removes and writes the unnecessary virtual subpixel signals to the V-RAM 240 so that the virtual subpixel signals can be selectively supplied to actual pixels. Read logic 250 generates RAM read timing to read the signals written to V-RAM 240. The pixel signal supply unit 260 aligns pixel signals according to pixel positions and supplies the pixel signals to the subpixels 111 to 114 of the display module 100.

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.

1 is a diagram illustrating a pixel structure of a general display module.

2 is a diagram illustrating a pixel configuration of a time division virtual pixel method.

3 is a diagram illustrating a display device according to an exemplary embodiment of the present invention.

4 is a diagram for explaining position information of a virtual pixel signal and an actual subpixel;

FIG. 5 is a diagram for explaining matching between virtual pixel signals and actual subpixels. FIG.

6A illustrates another example of subpixel arrangement.

FIG. 6B illustrates the subpixel arrangement shown in FIG. 3. FIG.

7 is a configuration diagram of the LDC shown in FIG.

<Brief description of symbols for the main parts of the drawings>

10, 20a ~ 20d, 110, 600: Pixel 111 ~ 114, 601 ~ 604: Subpixel

30a to 30f, 40a and 40b, 50a to 50c: virtual pixels

100: display module 110a ~ 110d: subpixel area

200: LDC 210: data receiving unit

220: RAM recording logic 230: Pixel signal sorter

240: V-RAM 250: Reading Logic

260: pixel signal supply unit 300: signal supply unit

400: power supply unit 510 to 540: virtual pixel signal

511 ~ 514, 521 ~ 524, 531 ~ 534, 541 ~ 544: Virtual subpixel signal

Claims (6)

Four subpixel regions arranged in two horizontal and two matrix forms, a red subpixel disposed in a first subpixel region of the four subpixel regions, and a second subpixel of the four subpixel regions. A display module in which pixels including a green subpixel disposed in an area and a blue subpixel disposed in a third subpixel area among the four subpixel areas are arranged in a matrix form m horizontally and vertically n; A red virtual subpixel signal, a green virtual subpixel signal, and a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and each position of the subpixels disposed in the display module A signal supply unit generating virtual pixel signals matching the subpixels with position information matching the information; The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A position display control unit for extracting a subpixel corresponding to 1: 1 to the subpixel and supplying the extracted subpixel to the matched subpixel; And A power supply unit supplying a constant voltage to the display module Display device having a high resolution comprising a. Four subpixel regions arranged in two horizontal and two matrix forms, a red subpixel disposed in a first subpixel region of the four subpixel regions, and a second subpixel of the four subpixel regions. A green subpixel disposed in a region, a blue subpixel disposed in a third subpixel region among the four subpixel regions, and a red subpixel disposed in a fourth subpixel region among the four subpixel regions And a display module in which pixels including additional subpixels having the same color as any one of the blue subpixels are arranged in a matrix form of m horizontally and n vertically; A red virtual subpixel signal, a green virtual subpixel signal, a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and an additional virtual subpixel signal of the same color as the additional subpixel. A signal supply unit configured to generate virtual pixel signals matching the respective subpixels with position information corresponding to the position information of each of the subpixels disposed in the display module; The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A position display control unit for extracting a subpixel corresponding to 1: 1 to the subpixel and supplying the extracted subpixel to the matched subpixel; And A power supply unit supplying a constant voltage to the display module Display device having a high resolution comprising a. The method according to claim 1 or 2, And the subpixels in the display module are disposed at equal intervals from each other. The method according to claim 1 or 2, The position display control unit, The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A one-to-one correspondence with the subpixels-a pixel signal aligner for extracting and removing the remaining virtual subpixel signals; A V-RAM in which the extracted virtual subpixel signal is recorded; And A pixel signal supply unit for aligning the virtual subpixel signal recorded in the V-RAM according to the position of the matched subpixel and supplying the matched subpixel to the matched subpixel Display device having a high resolution, comprising a. Four subpixel regions arranged in two horizontal and two matrix forms, a red subpixel disposed in a first subpixel region of the four subpixel regions, and a second subpixel of the four subpixel regions. And a display module in which pixels including a green subpixel disposed in an area and a blue subpixel disposed in a third subpixel area among the four subpixel areas are arranged in a matrix form m horizontally and n vertically. In a driving method of a display device having a high resolution, A red virtual subpixel signal, a green virtual subpixel signal, and a blue virtual subpixel signal disposed in the same color order as the subpixels positioned in the pixel, and each position of the subpixels disposed in the display module Generating virtual pixel signals matching the subpixels with position information matching the information; And The virtual pixel signal having a position information matching each other among the virtual pixel signals and the subpixels matches a subpixel, and the virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal. The positional information in the matched virtual pixel signal of the virtual subpixel signal is equal to the positional information of the matched subpixel in a pixel containing the matched subpixel, wherein the virtual subpixel signal is matched A second step of extracting a subpixel corresponding to the subpixel and supplying the subpixel to the matched subpixel Method of driving a display device having a high resolution comprising a. The method of claim 5, The second step, Matching a virtual pixel signal with a subpixel having positional information matched with each other among the virtual pixel signals and the subpixels; A virtual subpixel signal of any one of the virtual subpixel signals included in the matched virtual pixel signal, wherein position information in the matched virtual pixel signal of the virtual subpixel signal is within a pixel including the matched subpixel Extracting the virtual subpixel signals equal to the position information of the matched subpixels, wherein the virtual subpixel signal corresponds 1: 1 with the matched subpixel, and removing the remaining virtual subpixel signals; Recording the extracted virtual subpixel signal; And Aligning the recorded virtual subpixel signal according to the position of the matched subpixel to supply the matched subpixel Method of driving a display device having a high resolution, comprising a.

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