KR102385576B1 - Display driving device and subpixel driving method - Google Patents

Abstract

The present invention discloses a display driving apparatus and a subpixel driving method. The method comprises the steps of: converting a color image signal into a gray scale image signal represented by a minimum gray scale and a maximum gray scale; selecting, according to the pixel structure, a subpixel overlapping unit including a plurality of subpixels arranged along a row direction; In a plurality of successive frame periods, data jitter is performed using an inner subpixel and an adjacent outer subpixel in the subpixel overlapping unit to convert the gray scale image signal to a sub having an equivalent intermediate gray scale generated by the data jitter. converting a rendered image signal including pixels; and driving the plurality of sub-pixels using a rendered image signal. This method can suppress the occurrence of color artifacts by performing jitter processing in a plurality of successive frame periods using a plurality of sub-pixels to obtain an equivalent intermediate gray scale.

Description

Display driving device and subpixel driving method

This application claims priority to Chinese Patent Application No. 201810939798.4, entitled "Display driving device and subpixel driving method" filed on August 17, 2018, and the contents throughout the application are referred to and cited.

The present invention relates to the field of image processing and technology, and more particularly, to a display driving apparatus and a sub-pixel driving method.

When an image displayed on a display screen is observed, image quality is related to the viewer's viewing angle. For example, when the viewer's viewing angle follows the normal direction of the surface of the display screen, the picture quality is highest. When the viewing angle deviates from the normal direction, the image quality gradually deteriorates. The main reason for the degradation is due to color artifacts, i.e., the luminance of the red, green, and blue subpixels can all be reduced as the viewing angle deviates from the normal direction, but with different degrees of reduction, the observer's perceived color is Deviates from the preset value to form color artifacts.

The color artifact is not only present in the observation of images at high viewing angles, but is also a problem present in the low power mode of the display screen. A driving circuit of the display screen may be configured to operate in a normal display mode and a low power mode, and display data is processed by employing different display driving channels, respectively. In the low-power mode of the display screen, the display data represented by multi-bits can be converted into display data represented by 1-bits, and the luminance value of each sub-pixel is set to 1 or 0, so that the color image is displayed on the maximum gray scale and minimum gray scale It is converted to a grayscale image represented by the sub-pixels of the scale. The degree of change in luminance of the red, green, and blue sub-pixels perceived by the observer is different. Even if the viewing angle does not change, the color perceived by the viewer may deviate from the preset value, forming color artifacts.

Color artifacts can be reduced by performing subpixel rendering (SPR) on display data. In the normal display mode, the SPR driving channel includes a plurality of subpixel overlapping units, and a subpixel overlapping unit is a pixel unit including one or two subpixels. Subpixel rendering can not only improve image quality at large viewing angles, but also extend the viewing angle range of the display screen. However, subpixel rendering can create new problems: color edges may be created at the edges of the image, and random color artifacts may be present in some areas of the image.

Accordingly, a more improved sub-pixel driving method is expected that considers both power consumption control and image quality of the display screen.

The present invention was created to solve the above problems, and an object of the present invention is to obtain an equivalent intermediate gray scale by performing jitter processing in successive frame periods using a plurality of sub-pixels to reduce the occurrence of color artifacts. intended to be suppressed.

According to a first aspect of the present invention, there is disclosed a method of driving subpixels for a display screen comprising a plurality of pixel units arranged in a pixel structure and each comprising a plurality of subpixels for displaying different colors, the method comprising: , converting a color image signal into a gray scale image signal expressed in a minimum gray scale and a maximum gray scale; selecting, according to the pixel structure, a subpixel overlapping unit including a plurality of subpixels arranged along a row direction; In a plurality of successive frame periods, data jitter (dithering) is performed using the inner sub-pixel and the adjacent outer sub-pixel in the sub-pixel overlapping unit to convert the gray-scale image signal into the equivalent generated by the data jitter converting to a rendered image signal comprising subpixels having a equivalent intermediate grayscale; and driving the plurality of sub-pixels using a rendered image signal.

The pixel structure is an array structure including a row direction and a column direction, and selecting the subpixel overlapping unit includes: determining the subpixel overlapping unit along the row direction; and obtaining a quantity ratio (S) of the subpixel overlapping unit and an equivalent pixel unit including a group of subpixels consisting of three colors of red, green and blue.

The jitter period of the data jitter is an integer in which the product of the number of frames (N) and the quantity ratio (S) is an integer greater than or equal to 1, and includes a plurality of consecutive frame periods, and includes the steps of: obtaining a quantity ratio (S); Preferably, the method further includes acquiring the jitter period between the performing steps.

the quantity ratio (S) of the subpixel overlap unit is one of 1/2, 1/3 and 2/3, and the number of frames (N) included in the jitter period is a corresponding one of 2, 6 and 6; Preferably, the equivalent intermediate gray scale is a corresponding one of 1/2, 1/3, and 2/3 of the maximum gray scale.

Preferably, the outer sub-pixel is a sub-pixel adjacent to one or both sides of the sub-pixel overlap unit, and is used to supplement sub-pixels that do not contain a color in the sub-pixel overlap unit.

The performing data jitter may include: maintaining at least one subpixel of an inner subpixel and an outer subpixel of the subpixel overlap unit at a minimum gray scale irrespective of the image signal in at least one frame week of the plurality of frame periods It is preferable to be

Preferably, the data jitter suppresses generation of color artifacts while reducing power consumption of the display screen.

According to a second aspect of the present invention, there is provided a first driving channel for processing a received color image signal as a first driving signal; a second driving channel for processing the received color image signal as a second driving signal; a display driving device comprising a selection unit used to select one of the first driving channel and the second driving channel according to a first mode selection signal of the display screen and a second mode selection signal having a power consumption smaller than that of the first mode The second mode of the display screen has lower power consumption than the first mode, and the second driving channel performs jitter processing on the image signal in a plurality of successive frame periods to obtain an equivalent intermediate gray scale.

The second driving channel includes: a data conversion module for converting the color image signal into a gray scale image signal represented by a minimum gray scale and a maximum gray scale; a data jitter module for generating a rendered image signal by performing jitter processing on the gray scale image signal in a plurality of successive frame periods; and a voltage selection module for selecting one of a minimum gray scale and a maximum gray scale according to a binary value of the rendered image signal, wherein a subpixel of the rendered image signal has an equivalent intermediate gray scale generated by data jitter.

A display driving apparatus and a subpixel driving method according to an embodiment of the present invention use a plurality of adjacent subpixels as a pixel overlap unit, and perform jitter processing in a plurality of successive frame periods to obtain an equivalent intermediate gray scale. The successive multiple frame periods form a jitter period. In the low-power mode of the display screen, it converts a color image into a gray-scale image that is represented by sub-pixels of the maximum gray scale and intermediate gray scale. This improved sub-pixel rendering allows the equivalent luminance value of the sub-pixel to be reduced in the low-power mode, and the power consumption can be further reduced, so that the difference in the luminance value of the sub-pixels of different colors detected by the observer is also By reducing it, it is possible to suppress the occurrence of color artifacts.

In the accompanying drawings in order to make the above and other objects, features and advantages of the present invention more clear through the description of the embodiments of the present invention with reference to the accompanying drawings,
1 shows a schematic block diagram of a display driving apparatus according to the present invention.
2 shows a flowchart of a subpixel driving method according to the present invention.
3A and 3B show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a first type.
4A and 4B show a first sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention.
5A and 5B show a second sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention.
6A and 6B show a third sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention.
7A and 7B show the first sub-pixel overlapping unit of the sub-pixel driving method according to the second embodiment of the present invention.
8A and 8B show a second sub-pixel overlapping unit of a sub-pixel driving method according to a second embodiment of the present invention.
9A and 9B show a third sub-pixel overlapping unit of a sub-pixel driving method according to a second embodiment of the present invention.
10A and 10B show a pixel structure and a pixel diffusion type schematic diagram of a display screen of the second type.
11 shows a sub-pixel overlapping unit of a sub-pixel driving method according to a third embodiment of the present invention.
12A and 12B show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a third type.
13 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention.
14 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention.
15 shows a third sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention.
16A and 16C show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a fourth type.
17 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a fifth embodiment of the present invention.
18 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a fifth embodiment of the present invention.
19A and 19C show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a fifth type.
20 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a sixth embodiment of the present invention.
21 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a sixth embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In the various accompanying drawings, like elements are denoted by the same or similar reference numerals. For ease of understanding, each part in the accompanying drawings may not be drawn to scale.

Hereinafter, the present invention will be described with reference to the accompanying drawings and embodiments.

1 shows a schematic block diagram of a display driving apparatus according to the present invention. The display driving device 100 is used to drive a display screen, and the display screen includes a plurality of pixel units each including a plurality of sub-pixels for displaying different colors. The display driving apparatus 100 includes a selection unit 101 , a first driving channel 110 , and a second driving channel 120 .

The selection unit 101 is used to select one of the first driving channel 110 and the second driving channel 120 according to the mode selection signal of the display screen. The first driving channel 110 and the second driving channel 120 are used to process the received color image signal into the first driving signal and the second driving signal, respectively, and enter a normal display mode and a low power mode, respectively.

The first driving channel 110 includes a first voltage conversion module 111 , a mode evaluation module 112 , a pixel compensation module 113 , and a second voltage conversion module 114 . The first voltage conversion module 111 converts the non-linear gamma image signal into a linear image signal. The mode evaluation module 112 performs edge detection on the image, for example. The pixel compensation module 113 improves image quality by, for example, compensating for edge information of the image. The second voltage conversion module 114 converts the linear image signal back into a non-linear gamma image signal and provides it as a first driving signal.

The second driving channel includes a data conversion module 121 , a data jitter module 122 , and a voltage selection module 123 . The data conversion module 121 converts the received color image signal into a gray scale image signal represented by a minimum gray scale and a maximum gray scale. The data jitter module 122 converts the gray scale image signal into a rendered image signal by performing jitter processing on the gray scale image signal in a plurality of successive frame periods, and subpixels of the rendered image signal are generated by data jitter. has an equivalent intermediate gray scale. The voltage selection module 123 selects one of the minimum gray scale and the maximum gray scale according to the binary value of the rendered image signal to obtain a plurality of sub-pixels for driving the display screen with the second driving signal.

According to the display driving apparatus according to the embodiment of the present invention, in the low-power mode of the display screen, a color image is converted into a gray-scale image represented by sub-pixels having a maximum gray scale and an intermediate gray scale. The data jitter module performs jitter processing in successive multiple frame periods to obtain an equivalent intermediate gray scale, so that the equivalent luminance value of a sub-pixel is reduced in a low power mode, and power consumption can be further reduced, accordingly , it is possible to suppress the occurrence of color artifacts by reducing the difference in luminance values of subpixels of different colors sensed by the observer.

2 shows a flowchart of a subpixel driving method according to the present invention.

In step S01, the received color image signal is converted into a gray scale image signal expressed by the minimum gray scale and the maximum gray scale. This step generates, for example, the image signal required by the low power mode of the display screen.

In step S02, a subpixel overlapping unit is selected according to the pixel structure of the display screen. The pixel structure is an array structure including a row direction and a column direction. For example, the subpixel overlap unit is determined along the row direction.

In this embodiment, the inner subpixels of the subpixel overlap unit include only one group of subpixels, for example consisting of some color of red, green and blue. An inner subpixel of a subpixel overlap unit and an outer subpixel adjacent thereto may form an equivalent pixel unit. An equivalent pixel unit includes a group of subpixels consisting of three red, green and blue subpixels.

The quantity ratio (S) of the subpixel overlapping unit is the ratio of the equivalent pixel unit thereto. For example, if three adjacent subpixel overlapping units include two equivalent pixel units, the quantity ratio S is equal to 2/3.

In step S03, in a plurality of successive frame periods, data jitter is performed using the inner subpixels in the subpixel overlapping unit and the adjacent outer subpixels to convert the gray scale image signal into a rendering image signal, wherein The subpixels of the rendered image signal have an equivalent intermediate gray scale created by data jitter.

The outer sub-pixel adopted in the data jitter is a sub-pixel adjacent to one or both sides of the sub-pixel overlap unit, and the outer sub-pixel is used to supplement the sub-pixel whose color is not included in the sub-pixel overlap unit.

The jitter period (Td) employed in data jitter includes a number of consecutive frame periods (Tf). For example, the jitter period Td is obtained according to the quantity ratio S of the subpixel overlapping units. The product of the number of frames (N) included in the jitter period (Td) and the quantity ratio (S) is an integer greater than or equal to 1.

For example, the quantity ratio (S) of the subpixel overlap unit is one of 1/2, 1/3, and 2/3, and the number of frames included in the jitter period (N) is a corresponding one of 2, 6, and 6 one, and the equivalent intermediate gray scale is a corresponding one of 1/2, 1/3 and 2/3 of the maximum gray scale.

In step S04, a plurality of sub-pixels of the display screen are driven using the rendered image signal.

The sub-pixel driving method according to the embodiment of the present invention reduces the equivalent luminance value of the sub-pixel in a low-power mode by performing jitter processing in a plurality of successive frame periods to obtain an equivalent intermediate gray scale, thereby reducing power consumption. Accordingly, it is possible to suppress the occurrence of color artifacts by reducing the difference in the luminance values of subpixels of different colors sensed by the observer.

3A and 3B show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a first type.

As shown in FIG. 3A , the width W of the subpixel overlapping units 201 to 203 is the width of two subpixels, respectively. For the sub-pixel overlap unit 201 , the sub-pixel overlap unit 201 in the first row includes one red sub-pixel and one green sub-pixel adjacent to each other, and the sub-pixel overlap unit 201 in the second row contains the middle blue subpixel, adjacent 1 1/2 green subpixel and 1 1/2 red subpixel, thus inferring. Thus, in each row, three subpixel overlapping units adjacent to each other include two red subpixels, two green subpixels and two blue subpixels.

As shown in FIG. 3B , the subpixel overlapping units 201 to 203 in the first row perform bilateral diffusion, that is, the subpixel overlapping unit and the adjacent subpixel units on both sides perform jitter processing together, and the second The subpixel overlapping units 201 to 203 in the row perform one-side diffusion, that is, the subpixel overlapping unit and the subpixel unit adjacent to one side perform jitter processing together, thereby inferring.

In this embodiment, the quantity ratio S of the subpixel overlap unit 201 is equal to 2/3, the number of frames N in the jitter period Td is 6, and the quantity ratio S and the number of frames ( The product of N) is an integer of 2.

4A and 4B show a first sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention. This subpixel driving method is used, for example, in a display screen of the first type shown in Figs. 3A and 3B.

As shown in Fig. 4A, the data jitter of both diffusions will be described by taking the subpixel overlap unit 201 in the first row as an example. A first row of the sub-pixel overlap unit 201 includes a red sub-pixel R11 and a green sub-pixel G11, both of which have one side adjacent to each other. The blue sub-pixel B11 is positioned on the other side of the red sub-pixel R11 and the blue sub-pixel B12 is positioned on the other side of the green sub-pixel G11. In six consecutive frame periods (Frame0 to Frame5), the red subpixel R11 lights a total of four frame periods in the frame periods Frame0, Frame1, Frame4 and Frame5, and the green subpixel G11 is A total of four frame periods are lit in the frame periods Frame1 to Frame4, the blue subpixel B11 lights a total of two frame periods in the frame periods Frame0 and Frame5, and the blue subpixel B12 is In the frame period (Frame2 and Frame3), a total of two frame periods are turned on. Accordingly, the two subpixels of the subpixel overlap unit 201 and the two subpixels adjacent thereto are a total of four subpixels, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

As shown in Fig. 4B, the data jitter of one-side diffusion will be described using the subpixel overlap unit 201 in the second row as an example. The green subpixel G21 and the blue subpixel B21 are selected in the second row of the subpixel overlapping unit 201 , and both have one side adjacent to each other. The red sub-pixel R21 is positioned on the other side of the blue sub-pixel B21. In six consecutive frame periods (Frame0 to Frame5), the green subpixel G21 lights a total of four frame periods in the frame periods Frame0, Frame2, Frame3 and Frame5, and the blue subpixel B21 turns on A total of four frame periods are turned on in the frame periods Frame0, Frame1, Frame3, and Frame4, and the red subpixel R21 lights a total of four frame periods in the frame periods Frame1, Frame2, Frame4 and Frame5. Accordingly, the two subpixels of the subpixel overlap unit 201 and one subpixel adjacent thereto are three subpixels in total, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

5A and 5B show a second sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention. This subpixel driving method is used, for example, in a display screen of the first type shown in Figs. 3A and 3B.

As shown in Fig. 5A, the data jitter of both diffusions will be described by taking the subpixel overlap unit 202 of the first row as an example. A first row of the sub-pixel overlapping unit 202 includes a blue sub-pixel B11 and a red sub-pixel R11, both of which have one side adjacent to each other. The green sub-pixel G11 is positioned on the other side of the blue sub-pixel B11 and the green sub-pixel G12 is positioned on the other side of the red sub-pixel R11. In six consecutive frame periods (Frame0 to Frame5), the blue subpixel B11 lights a total of four frame periods in the frame periods Frame0, Frame1, Frame4 and Frame5, and the red subpixel R11 is A total of four frame periods are lit in the frame periods Frame1 to Frame4, the green subpixel G11 lights a total of two frame periods in the frame periods Frame0 and Frame5, and the green subpixel G12 is In the frame period (Frame2 and Frame3), a total of two frame periods are turned on. Accordingly, the two subpixels of the subpixel overlap unit 202 and the two subpixels adjacent thereto are a total of four subpixels, so that in six successive frame periods, the equivalent gray scale is intermediate to a maximum gray scale of 2/3 Implement gray scale.

As shown in Fig. 5B, the data jitter of one side diffusion will be described by taking the subpixel overlap unit 202 of the second row as an example. The red subpixel R21 and the green subpixel G21 are selected in the second row of the subpixel overlapping unit 202 , and both have one side adjacent to each other. The blue sub-pixel B21 is positioned on the other side of the green sub-pixel G21. In six consecutive frame periods (Frame0 to Frame5), the red subpixel R21 lights a total of four frame periods in the frame periods Frame0, Frame2, Frame3 and Frame5, and the green subpixel G21 turns on A total of four frame periods are turned on in the frame periods Frame0, Frame1, Frame3, and Frame4, and the blue subpixel B21 lights a total of four frame periods in the frame periods Frame1, Frame2, Frame4, and Frame5. Accordingly, the two subpixels of the subpixel overlap unit 202 and one subpixel adjacent thereto are three subpixels in total, so that in six consecutive frame periods, the equivalent gray scale is halfway to the maximum gray scale of 2/3 Implement gray scale.

6A and 6B show a third sub-pixel overlapping unit of the sub-pixel driving method according to the first embodiment of the present invention. This subpixel driving method is used, for example, in a display screen of the first type shown in Figs. 3A and 3B.

As shown in Fig. 6A, the data jitter of both diffusions will be described by taking the subpixel overlap unit 203 in the first row as an example. A first row of the sub-pixel overlapping unit 203 includes a green sub-pixel G11 and a blue sub-pixel B11, both of which have one side adjacent to each other. The red sub-pixel R11 is positioned on the other side of the green sub-pixel G11 and the red sub-pixel R12 is positioned on the other side of the blue sub-pixel B11. In six consecutive frame periods (Frame0 to Frame5), the green subpixel G11 lights a total of four frame periods in the frame periods Frame0, Frame1, Frame4 and Frame5, and the blue subpixel B11 turns on A total of four frame periods are lit in the frame periods Frame1 to Frame4, the red subpixel R11 lights a total of two frame periods in the frame periods Frame0 and Frame5, and the red subpixel R12 is In the frame period (Frame2 and Frame3), a total of two frame periods are turned on. Accordingly, the two subpixels of the subpixel overlap unit 203 and the two subpixels adjacent thereto are a total of four subpixels, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

As shown in Fig. 6B, the data jitter of one-side diffusion will be described by taking the subpixel overlap unit 203 in the second row as an example. The blue subpixel B21 and the red subpixel R21 are selected in the second row of the subpixel overlapping unit 203 , and both have one side adjacent to each other. The green sub-pixel G21 is positioned on the other side of the red sub-pixel R21. In six consecutive frame periods (Frame0 to Frame5), the blue sub-pixel B21 lights a total of four frame periods in the frame periods Frame0, Frame2, Frame3, and Frame5, and the red subpixel R21 is A total of four frame periods are turned on in the frame periods Frame0, Frame1, Frame3, and Frame4, and the green subpixel G21 lights a total of four frame periods in the frame periods Frame1, Frame2, Frame4, and Frame5. Accordingly, two subpixels of the subpixel overlap unit 203 and one subpixel adjacent thereto are a total of three subpixels, so that in six successive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

The subpixel driving method according to the second embodiment of the present invention is basically the same as that of the first embodiment. When the lighting count of sub-pixels in successive frame periods remains unchanged, the lighting order of sub-pixels in successive frame periods is changed. Hereinafter, differences between the second embodiment will be described with reference to the first embodiment, and descriptions of the same points will be omitted.

7A and 7B show the first sub-pixel overlapping unit of the sub-pixel driving method according to the second embodiment of the present invention.

As shown in FIG. 7A, compared with FIG. 4A, in the data jitter of both diffusions, the blue subpixel B11 lights a total of two frame periods in the frame periods Frame0 and Frame1, and the blue subpixel B12 ) turns on a total of two frame periods in the frame periods Frame4 and Frame5, and the number and order of lighting of the red subpixel R11 and the green subpixel G11 are changed.

As shown in FIG. 7B, compared with FIG. 4B, in the data jitter of one diffusion, the green subpixel G11 lights a total of four frame periods in the frame periods Frame1 to Frame4, and the blue subpixel B21 ) and the red subpixel R21 light a total of four frame periods in the frame periods Frame0, Frame1, Frame4, and Frame5.

Accordingly, the two subpixels of the subpixel overlap unit 201 and one subpixel adjacent thereto are three subpixels in total, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

8A and 8B show a second sub-pixel overlapping unit of a sub-pixel driving method according to a second embodiment of the present invention.

As shown in Fig. 8A, compared with Fig. 5A, in the data jitter of both diffusions, the green subpixel G11 lights a total of two frame periods in the frame periods Frame0 and Frame1, and the green subpixel G12 ) lights a total of two frame periods in the frame periods Frame4 and Frame5, and the number and order of lighting of the blue subpixel B11 and the red subpixel R11 are changed.

As shown in FIG. 8B, compared with FIG. 5B, in the data jitter of one diffusion, the green subpixel G21 lights a total of four frame periods in the frame periods Frame1 to Frame4, and the red subpixel R21 ) and the blue sub-pixel B21 illuminate a total of four frame periods in the frame periods Frame0, Frame1, Frame4, and Frame5.

Accordingly, the two subpixels of the subpixel overlap unit 202 and one subpixel adjacent thereto are three subpixels in total, so that in six consecutive frame periods, the equivalent gray scale is halfway to the maximum gray scale of 2/3 Implement gray scale.

9A and 9B show a third sub-pixel overlapping unit of a sub-pixel driving method according to a second embodiment of the present invention.

As shown in Fig. 9A, compared with Fig. 6A, in the data jitter of both diffusions, the red subpixel R11 lights a total of two frame periods in the frame periods Frame0 and Frame1, and the red subpixel R12 ) lights up a total of two frame periods in the frame periods Frame4 and Frame5, the green subpixel G12 lights up a total of four frame periods in the frame periods Frame1 to Frame4, and the blue subpixel B11 turns on In the frame period (Frame2 to Frame5), a total of four frame periods are turned on.

As shown in FIG. 9B, compared with FIG. 6B, in the data jitter of one diffusion, the blue subpixel B11 lights a total of four frame periods in the frame periods Frame0 to Frame3, and the red subpixel R21 ) lights a total of four frame periods in the frame periods Frame1 to Frame4, and the green subpixel G21 lights a total of four frame periods in the frame periods Frame2 to Frame5.

Accordingly, two subpixels of the subpixel overlap unit 203 and one subpixel adjacent thereto are a total of three subpixels, so that in six successive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

10A and 10B show a pixel structure and a pixel diffusion type schematic diagram of a display screen of the second type.

As shown in FIG. 10A , the width W of the subpixel overlapping units 301 and 302 is the width of two subpixels, respectively. Taking the subpixel overlapping unit 301 as an example, the subpixel overlapping unit 301 of the first row includes one adjacent red subpixel and one green subpixel, and the subpixel overlapping unit 301 of the second row contains one adjacent blue subpixel and one green subpixel, thus inferring. Thus, in each row, two subpixel overlapping units adjacent to each other include one red subpixel, one blue subpixel and two green subpixels.

In the subpixel overlapping unit 301 of the second row, two adjacent subpixels are adjacent to each other in the row direction (direction indicated by an arrow in the drawing), and the distance of one subpixel height is staggered in the column direction.

As shown in Fig. 10B, the sub-pixel overlap units 301 and 302 in the first and second rows all perform one-sided diffusion, that is, the sub-pixel overlap unit and two adjacent sub-pixel units are jittered together. , and inferred from it.

In this embodiment, the quantity ratio S of the subpixel overlapping unit 301 is equal to 1/2 or 1, the number of frames N in the jitter period Td is 2, and the quantity ratio S and frames The product of a number (N) is 1 or 2, which is an integer.

11 shows a sub-pixel overlapping unit of a sub-pixel driving method according to a third embodiment of the present invention. This subpixel driving method is used for the second type of display screen shown in Figs. 10A and 10B, and the subpixel overlapping units 301 and 302 are all one-sided diffusion.

As shown in the figure, the data jitter of one side diffusion will be described taking the subpixel overlap unit 301 of the first row as an example. The red subpixel R11 and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 301 , and both have one side adjacent to each other. The blue sub-pixel B11 is positioned on the other side of the green sub-pixel G11. In two consecutive frame periods (Frame0 to Frame1), the red subpixel R11 lights up one frame period, and the green subpixel G11 turns on a total of two frames in the frame periods Frame0 and Frame1. The period is turned on, and the blue sub-pixel B11 turns on a total of one frame period in the frame period Frame1. Accordingly, two subpixels of the subpixel overlap unit 301 and one subpixel adjacent thereto are three subpixels in total, and in two successive frame periods, the equivalent gray scale is halfway through the maximum gray scale Implement gray scale.

12A and 12B show a schematic diagram of a pixel structure and a pixel diffusion type of a display screen of a third type.

As shown in FIG. 12A , the width W of the sub-pixel overlapping units 401 to 402 is the width of one sub-pixel, respectively. In each row, three subpixel overlapping units adjacent to each other include two red subpixels, two blue subpixels and two green subpixels.

As shown in Fig. 12B, the subpixel overlapping units 401 to 403 of the first and second rows all perform one-sided diffusion, that is, the subpixel overlapping unit and its adjacent subpixel unit perform jitter processing together. and inferred from this.

In this embodiment, the quantity ratio S of the subpixel overlap unit 401 is equal to 2/3, the number of frames N in the jitter period Td is 6, and the quantity ratio S and the number of frames ( The product of N) is an integer of 2.

13 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention. This sub-pixel driving method is used for the third type display screen shown in Figs. 12A and 12B, and the sub-pixel overlapping unit 401 is one-sided diffusion.

As shown in the figure, the data jitter of one-side diffusion will be described taking the subpixel overlap unit 401 of the first row as an example. The blue subpixel B11, the red subpixel R11 and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 401, and the triangles are adjacent to each other and consist of a triangle. The blue sub-pixel B21 is positioned on the other side of the red sub-pixel R11. In six consecutive frame periods (Frame0 to Frame5), the red subpixel R11 lights a total of four frame periods among the frame periods Frame0, Frame1, Frame4 and Frame5, and the green subpixel turns on the frame period (Frame0, Frame1, Frame4, and Frame5). A total of four frame periods among Frame0, Frame2, Frame3, and Frame4) are turned on, and the blue subpixel B11 turns on a total of two frame periods among the frame periods Frame1 and Frame6, and the blue subpixel B12 turns on a total of two frame periods. turns on a total of two frame periods among frame periods (Frame2 and Frame3). Accordingly, three subpixels of the subpixel overlap unit 401 and one subpixel adjacent thereto are a total of four subpixels, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

14 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention. This subpixel driving method is used for the third type display screen shown in Figs. 12A and 12B, and the subpixel overlapping unit 402 is one-sided diffusion.

As shown in the figure, the data jitter of one-side diffusion will be described by taking the subpixel overlap unit 402 of the first row as an example. The blue subpixel B11, the red subpixel R11 and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 402, and the triangles are adjacent to each other and consist of a triangle. The blue sub-pixel B21 is positioned on the other side of the red sub-pixel R11. In six consecutive frame periods (Frame0 to Frame5), the red subpixel R11 lights a total of four frame periods among the frame periods Frame0, Frame1, Frame4 and Frame5, and the green subpixel turns on the frame period (Frame0, Frame1, Frame4, and Frame5). A total of four frame periods among Frame1 to Frame4) are turned on, a blue sub-pixel B11 turns on a total of two frame periods among the frame periods Frame1 and Frame6, and a blue sub-pixel B12 turns on a frame period ( A total of two frame periods among Frame2 and Frame3) are turned on. Accordingly, three subpixels of the subpixel overlap unit 402 and one subpixel adjacent thereto are a total of four subpixels, so that in six successive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

15 shows a third sub-pixel overlapping unit of a sub-pixel driving method according to a fourth embodiment of the present invention. This sub-pixel driving method is used for the third type display screen shown in Figs. 12A and 12B, and the sub-pixel overlapping unit 403 is one-sided diffusion.

As shown in the figure, the data jitter of one side diffusion will be described taking the subpixel overlap unit 403 in the first row as an example. The blue subpixel B11, the red subpixel R11, and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 403, and the triangles are adjacent to each other and consist of a triangle. The blue sub-pixel B21 is positioned on the other side of the red sub-pixel R11. In six consecutive frame periods (Frame0 to Frame5), the red subpixel R11 lights a total of four frame periods among the frame periods Frame1 to Frame5, and the green subpixel turns on the frame period Frame0, Frame1, A total of four frame periods among Frame4 and Frame5) are turned on, a blue subpixel B11 lights a total of two frame periods among frame periods Frame2 and Frame3, and a blue subpixel B12 turns on a frame period ( A total of two frame periods among Frame0 and Frame5) are turned on. Accordingly, three subpixels of the subpixel overlap unit 403 and one subpixel adjacent thereto are a total of four subpixels, so that in six consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 2/3 Implement gray scale.

16A and 16C show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a fourth type.

As shown in FIG. 16A , the width W of the subpixel overlapping units 501 to 502 is the width of 1.5 subpixels, respectively. In each row, two subpixel overlapping units adjacent to each other include one red subpixel, one blue subpixel and two green subpixels.

16B and 16C, the sub-pixel overlap units 501 and 502 in the first and second rows both perform one-sided diffusion, that is, the sub-pixel overlap unit and its adjacent sub-pixel unit process jitter together. , and inferred from it.

In this embodiment, the quantity ratio S of the subpixel overlap unit 501 is equal to 1/2 or 1, the number of frames N in the jitter period Td is 2, and the quantity ratio S and frames The product of a number (N) is 1 or 2, which is an integer.

17 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a fifth embodiment of the present invention. This subpixel driving method is used for the display screen of the fourth type shown in Figs. 16A and 16C, and the subpixel overlapping unit 501 is one-sided diffusion.

As shown in the figure, the data jitter of one side diffusion will be described taking the subpixel overlap unit 501 of the first row as an example. The red subpixel R11 and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 501, both are adjacent to each other and the pixel size of the red subpixel R11 is the green subpixel G11 larger than the pixel size of The blue sub-pixel B11 is positioned on the other side of the green sub-pixel G11, and the pixel size of the red sub-pixel R11 is the same as the pixel size of the blue sub-pixel B11. In two successive frame periods (Frame0 and Frame1), the red subpixel R11 lights a total of one frame period of the frame period Frame0, and the green subpixel G11 turns on the frame period Frame0 and Frame1. ) lights in a total of two frame periods, and the blue sub-pixel B11 lights up a total of one frame period in the frame period Frame1. Accordingly, two subpixels of the subpixel overlapping unit 501 and one subpixel adjacent thereto are three subpixels in total, and in two successive frame periods, the equivalent gray scale is halfway through the maximum gray scale Implement gray scale.

18 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a fifth embodiment of the present invention. This sub-pixel driving method is used in the display screen of the fourth type shown in Figs. 16A to 16C, and the sub-pixel overlapping unit 502 is one-sided diffusion.

As shown in the figure, the data jitter of one side diffusion will be described taking the subpixel overlap unit 502 of the first row as an example. The blue subpixel B11 and the green subpixel G11 are selected in the first row of the subpixel overlapping unit 502, both are adjacent to each other and the pixel size of the blue subpixel B11 is the green subpixel G11 larger than the pixel size of The red sub-pixel R11 is positioned on the other side of the green sub-pixel G11 and the pixel size of the blue sub-pixel B11 is the same as the pixel size of the red sub-pixel R11. In two successive frame periods (Frame0 and Frame1), the blue sub-pixel B11 lights a total of one frame period among the frame periods Frame0, and the green sub-pixel G11 turns on the frame period Frame0 and Frame1. ) lights in a total of two frame periods, and the red sub-pixel R11 lights up a total of one frame period in the frame period Frame1. Accordingly, two subpixels of the subpixel overlap unit 502 and one subpixel adjacent thereto are three subpixels in total, and in two successive frame periods, the equivalent gray scale is halfway through the maximum gray scale Implement gray scale.

19A and 19C show a pixel structure and a pixel diffusion type schematic diagram of a display screen of a fifth type.

As shown in FIG. 19A , the width W of the subpixel overlapping units 601 to 602 is 1.5 subpixels each. In each row, two subpixel overlapping units adjacent to each other include one red subpixel, one blue subpixel and one green subpixel.

As shown in FIGS. 19B and 19C , the subpixel overlap unit 601 in the first row and the second row performs one-sided diffusion, that is, the subpixel overlap unit and the subpixel unit adjacent to one side perform jitter processing together. and the subpixel overlap unit 602 in the first row and the second row performs one-sided diffusion, that is, the subpixel overlap unit and the subpixel unit adjacent to both sides perform jitter processing together, thereby inferring.

In this embodiment, the quantity ratio S of the subpixel overlap unit 601 is equal to 1/2, the number of frames N in the jitter period Td is 4, and the quantity ratio S and the number of frames ( The product of N) is an integer of 2.

20 shows a first sub-pixel overlapping unit of a sub-pixel driving method according to a sixth embodiment of the present invention. This sub-pixel driving method is used in the fifth type display screen shown in Figs. 19A to 19C, and the sub-pixel overlapping unit 601 is one-sided diffusion.

As shown in the figure, the data jitter of one side diffusion will be described taking the subpixel overlap unit 601 of the first row as an example. The red subpixel R11 and the green subpixel G11 are selected in the first row of the subpixel overlap unit 601 , and both are adjacent to each other. The blue sub-pixel B11 is positioned on the other side of the green sub-pixel G11. In four successive frame periods (Frame0 to Frame3), the red subpixel R11 lights a total of two frame periods among the frame periods Frame0 and Frame2, and the green subpixel G11 turns on the frame period Frame1 and Frame3) illuminate a total of two frame periods, and the blue sub-pixel B11 lights a total of two frame periods among the frame periods Frame0 and Frame2. Accordingly, the two subpixels of the subpixel overlap unit 601 and one subpixel adjacent thereto are three subpixels in total, and in four consecutive frame periods, the equivalent gray scale is intermediate to the maximum gray scale of 1/2. Implement gray scale.

21 shows a second sub-pixel overlapping unit of a sub-pixel driving method according to a sixth embodiment of the present invention. This sub-pixel driving method is used for the fifth type display screen shown in Figs. 19A to 19C, and the sub-pixel overlapping unit 602 is bilateral diffusion.

As shown in the figure, the data jitter of both diffusions will be described by taking the subpixel overlapping unit 602 in the first row as an example. The blue subpixel B11 and the red subpixel R11 are selected in the first row of the subpixel overlap unit 602, and both are adjacent to each other. The green sub-pixel G11 is positioned on the other side of the blue sub-pixel B11 and the green sub-pixel G12 is positioned on the other side of the red sub-pixel R11. In four consecutive frame periods (Frame0 to Frame3), the blue subpixel B11 and the red subpixel R11 illuminate a total of two frame periods among the frame periods Frame0 and Frame2, and the green subpixel (G11) lights a total of one frame period of the frame period (Frame1), and the green sub-pixel (G12) lights a total of one frame period of the frame period (Frame3). Accordingly, the two subpixels of the subpixel overlap unit 602 and one subpixel adjacent thereto are a total of four subpixels, and in four consecutive frame periods, the equivalent gray scale is halfway through the maximum gray scale Implement gray scale.

According to the above description of the embodiments of the present invention, these embodiments have not been described in detail down to every minor detail, and the present invention is not limited to the specific embodiments described above. It goes without saying that various modifications and changes can be made in accordance with the foregoing. Selecting and specifically describing these embodiments in the present specification more clearly interpret the principles and practical applications of the present invention to those of ordinary skill in the art, so that those skilled in the art can better apply the present invention and understand the present invention It is intended for use with modifications on the basis of the invention. The invention is limited solely by the appended claims, their full scope and equivalents.

Claims (9)

A subpixel driving method for a display screen comprising a plurality of pixel units arranged in a pixel structure and each comprising a plurality of subpixels for displaying different colors, the method comprising:
converting a color image signal into a gray scale image signal represented by a minimum gray scale and a maximum gray scale;
selecting, according to the pixel structure, a subpixel overlapping unit including a plurality of subpixels arranged along a row direction;
By performing data jitter using an inner subpixel and an adjacent outer subpixel in the subpixel overlapping unit in a plurality of successive frame periods, the gray scale image signal is converted to an equivalent intermediate gray scale generated by the data jitter converting a rendered image signal including sub-pixels having and
driving the plurality of sub-pixels using the rendered image signal
A sub-pixel driving method for a display screen, comprising: The method of claim 1,
The pixel structure is an array structure including a row direction and a column direction, and the step of selecting a subpixel overlapping unit includes:
determining the subpixel overlap unit along a row direction; and
obtaining the quantity ratio (S) of the sub-pixel overlap unit and the equivalent pixel unit including a group of sub-pixels consisting of three colors of red, green and blue;
A sub-pixel driving method for a display screen, comprising: 3. The method of claim 2,
The jitter period of the data jitter is an integer in which the product of the number of frames (N) and the quantity ratio (S) is an integer greater than or equal to 1, and includes a plurality of consecutive frame periods, and includes the steps of: obtaining a quantity ratio (S); The sub-pixel driving method for a display screen according to claim 1, further comprising: obtaining the jitter period between the performing steps. 4. The method of claim 3,
the quantity ratio (S) of the subpixel overlap unit is one of 1/2, 1/3, and 2/3, and the number of frames (N) included in the jitter period is a corresponding one of 2, 6 and 6; and the equivalent intermediate gray scale is a corresponding one of 1/2, 1/3 and 2/3 of the maximum gray scale. According to claim 1,
The outer sub-pixel is a sub-pixel adjacent to one or both sides of the sub-pixel overlap unit, and is used to supplement the sub-pixel containing no color in the sub-pixel overlap unit. Way. According to claim 1,
The performing data jitter may include: maintaining at least one subpixel of an inner subpixel and an outer subpixel of the subpixel overlap unit at a minimum gray scale in at least one frame week of the plurality of frame periods irrespective of the image signal A sub-pixel driving method for a display screen, characterized in that it becomes. According to claim 1,
and the data jitter suppresses generation of color artifacts while reducing power consumption of the display screen. In the display driving device,
a first driving channel for processing the received color image signal as a first driving signal;
a second driving channel for processing the received color image signal as a second driving signal; and
a selection unit for selecting one of the first driving channel and the second driving channel based on a first mode selection signal of a display screen and a second mode selection signal having a smaller power consumption than the first mode
including,
The second driving channel is
To obtain an equivalent intermediate gray scale by performing jitter processing on an image signal in a number of consecutive frame periods
Display driving device comprising a. 9. The method of claim 8,
The second driving channel includes: a data conversion module for converting the color image signal into a gray scale image signal represented by a minimum gray scale and a maximum gray scale;
a data jitter module for generating a rendered image signal by performing jitter processing on the gray scale image signal in a plurality of successive frame periods; and
A voltage selection module for selecting one of a minimum gray scale and a maximum gray scale according to a binary value of the rendered image signal having subpixels having an equivalent intermediate gray scale generated by data jitter
Display driving device comprising a.

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