KR102648334B1 - Digital driving method and display panel of display panel - Google Patents

Abstract

The present application provides a digital driving method of a display panel and a display panel, wherein the display panel includes subpixels 110 arranged in an array of m rows and n columns, a plurality of scan lines (S1, S2, S3, S4.... ..) and a plurality of data lines (D1, D2, D3, D4......), each scan line is connected to one row of subpixels, and each data line is connected to one column of subpixels (110 ), where m and n are all integers greater than or equal to 1; The digital driving method of a display panel includes the steps of simultaneously providing a scan pulse signal to a plurality of scan lines and a first data voltage to a plurality of data lines (210); and providing a second data voltage to a plurality of data lines one by one, and providing a second data voltage to one data line, while providing a scan pulse signal to the scan line connected to the subpixel that needs to be written in the second data voltage. It includes a step 220 of providing simultaneously.

Description

Digital driving method and display panel of display panel

Embodiments of the present application relate to the field of display technology, for example, to a digital driving method of a display panel and a display panel.

This application claims priority of the Chinese patent application with application number 201910754575.5 filed with the Chinese Intellectual Property Office on August 15, 2019, the entire contents of which are incorporated by reference into this application.

With the advancement of display technology, digital drive is becoming more and more widely used due to its advantages of low image noise and fast switching speed.

However, in the digital drive scanning algorithm in the related art, the scanning time of the subpixels in each row is related to the number of rows of the display panel, and for a display panel with a relatively large number of rows of subpixels, the scanning time of the subpixels in each row is very Because it is short, the display effect is reduced.

The present application provides a digital driving method of a display panel and a display panel, so that the scanning duration length of the pixels in each row is independent of the number of rows of subpixels in the display panel, thereby improving the display effect.

In a first aspect, an embodiment of the present application provides a method of digitally driving a display panel, wherein the display panel includes subpixels, a plurality of scan lines, and a plurality of data lines arranged in an array of m rows and n columns, each A scanning line is connected to one row of subpixels, and each data line is connected to one column of subpixels, where m, n are all integers greater than or equal to 1; The digital driving method of the display panel is:

Simultaneously providing a scan pulse signal to a plurality of scan lines and simultaneously providing a first data voltage to a plurality of data lines; and

While providing the second data voltage to a plurality of data lines one line at a time, and providing the second data voltage to one data line, a scan pulse signal is simultaneously applied to the scan line connected to the subpixel to which the second data voltage is to be written. It includes a step of providing.

As a second aspect, an embodiment of the present application further provides a display panel, which is driven by the driving method of the display panel provided by the first aspect.

An embodiment of the present application provides a digital driving method of a display panel and a display panel, wherein the display panel includes subpixels arranged in an array of m rows and n columns, a plurality of scan lines, and a plurality of data lines, each scan line is connected to one row of subpixels, and each data line is connected to one column of subpixels, where m, n are all integers greater than or equal to 1; A method of digitally driving a display panel includes simultaneously providing a scan pulse signal to a plurality of scan lines and simultaneously providing a first data voltage to a plurality of data lines; and providing a second data voltage to a plurality of data lines one line at a time, and providing a scan pulse signal to a scan line connected to the subpixel to which the second data voltage is to be written while providing the second data voltage to one data line. simultaneously providing; including, ensuring that the scanning time of the subpixels in each row is independent of the number of subpixel rows in the display panel, and that the scanning time of the subpixels in each row is short due to the number of rows in the display panel being too large. Prevent display abnormalities.

1 is a structural schematic diagram of a display panel provided by an embodiment of the present application.
Figure 2 is a flowchart of a method of digitally driving a display panel provided by an embodiment of the present application.
Figure 3 is an operation timing diagram of digital driving of a display panel provided by an embodiment of the present application.
Figure 4 is a structural schematic diagram of a digital driving pixel circuit provided by an embodiment of the present application.
Figure 5 is a flowchart of a method of digitally driving another display panel provided by an embodiment of the present application.
Figure 6 is a flowchart of a method of digitally driving another display panel provided by an embodiment of the present application.

In the digital drive scanning algorithm in the related art, the scanning time of the pixels of each row is related to the number of rows of the display panel, so for a display panel with a relatively large number of rows, the scanning time of the pixels of each row is very short, resulting in a display effect There is a situation where it falls. According to the applicant's research, digital drive scanning algorithms generally use a row-by-row scanning method, scanning one row of subpixels and then scanning the next row of subpixels. For example, in the case of the subfield scanning method, one frame is generally divided into a plurality of subframes, and within each subframe, one scan is performed for all subpixels in the display panel, row by row, so that each row The time to scan a subpixel is very short, and when scanning a subpixel, the data voltage corresponding to the subpixel is generally written. However, the time to write the data voltage to the subpixel is very short, so the time to write the data voltage is very short. If the time is not met and the data voltage is not completely written, an error occurs in the gray scale display and the display effect deteriorates.

An embodiment of the present application provides a method for digitally driving a display panel, Figure 1 is a structural schematic diagram of a display panel provided by an embodiment of the present application, and Figure 2 is a schematic diagram of the display panel provided by an embodiment of the present application. It is a flowchart of a digital driving method, and FIG. 3 is an operation timing diagram of digital driving of a display panel provided by an embodiment of the present application. Referring to FIGS. 1, 2, and 3, the display panel includes subpixels 110 arranged in an array of m rows and n columns, a plurality of scan lines (S1, S2, S3, S4...), and It includes a plurality of data lines (D1, D2, D3, D4...), each scan line is connected to one row of subpixels, and each data line is connected to one column of subpixels, where: m and n are all integers greater than or equal to 1; The method of digitally driving a display panel includes steps 210 to 220.

In step 210, a scan pulse signal is simultaneously provided to a plurality of scan lines, and a first data voltage is simultaneously provided to a plurality of data lines.

Referring to FIG. 1 , the display panel may further include a scan driving circuit 120, a data driving circuit 130, a data processor 140, and a timing controller 150. The displayed data stream is input to the data processor 140, and the timing controller 150 controls the driving timing of the scan driving circuit 120 and the data driving circuit 130, respectively. For example, when driving a display panel using a digital driving method, the data voltage provided to the data line generally includes only the black state data voltage and the bright state data voltage, and the dark state data voltage and the bright state data voltage. The state data voltage may be a fixed value. In the digital driving method of the display panel, the screen of one frame can be divided into a plurality of sub-frames, and FIG. 3 exemplarily shows the driving timing within two sub-frames. Referring to FIG. 3, each sub-frame Within the frame, a data writing step (t1) and a driving light emitting step (t2) are included, wherein in different sub-frames within one frame, the time length of the driving light emitting step (t2) may be different, illustratively: When dividing one frame into four sub-frames, the time ratio of the driving light emission stages of the four sub-frames may be 1:2:4:8. Here, within one subframe, when the dark state data voltage is finally written to the subpixel 110 in the data writing stage, the subpixel 110 does not emit light in the driving light emission stage of the subframe; Within one subframe, when the bright state data voltage is finally written to the subpixel 110 in the data writing stage, the subpixel 110 emits light in the driving light emission stage of the corresponding subframe. By controlling whether the subpixel 110 emits light within different subframes, the subpixel 110 controls the length of time the subpixel 110 emits light within one frame (i.e., the subpixel 110 within different subframes through control). ) is controlled by inputting different data voltages), and realizes the display of different gray scales. Here, the first data voltage may be a dark state data voltage or a bright state data voltage.

The scan pulse signal can control the writing of the data voltage, and Figure 4 is a structural schematic diagram of a digital driving pixel circuit provided by an embodiment of the present application. Referring to Figure 4, the corresponding digital driving pixel circuit includes a first transistor. (T1), second transistor (T2), third transistor (T3), storage capacitor (Cst), data voltage input terminal (Vdata), light emitting element (D5), scan signal input terminal (Scan) and emission control signal input terminal (EM) ), and includes a first power supply voltage input terminal (VDD) and a second power voltage input terminal (VSS). Here, the scan signal input terminal (Scan) may be connected to the scan line, and the data voltage input terminal (Vdata) may be connected to the data line. Referring to FIG. 4, the scan pulse signal is used to control the conduction of the first transistor T1, and therefore, when the first transistor T1 is conducted, the data voltage of the data line is transmitted through the first transistor T1. It can be written to the gate of the second transistor (T2), and the second transistor (T2) is used as a driving transistor of the corresponding pixel circuit. It should be explained that the digital driving method provided by this embodiment is not only applied to the display panel including the pixel circuit shown in Figure 4, and the display panel of the pixel circuit shown in Figure 4 only uses a scanning pulse signal. This is to explain that can be used to control whether or not a data voltage can be written to the subpixel 110.

After providing a scan pulse signal to a scan line, a data voltage can be written to the subpixel 110 electrically connected to the scan line; If a scan pulse signal is not provided to the scan line, a data voltage cannot be written to the subpixel 110 electrically connected to the scan line. Exemplarily, referring to FIG. 3 , the full screen data signal Data includes two voltages, where the low voltage level may indicate the first data voltage. In this step, by simultaneously providing a scanning pulse signal to a plurality of scanning lines, that is, by simultaneously scanning all rows of pixels in the display panel and simultaneously providing the first data voltage to the data lines, the first data voltage is applied to the display panel. It is written to each subpixel 110 simultaneously. Here, Scan1, Scan2, Scan3, Scan4, Scan5, Scan6, Scan7...Scanm in FIG. 3 are the 1st, 2, 3, 4, 5, 6, 7...m rows, respectively. A scan signal input to a subpixel may be displayed, and referring to FIG. 3, the scan pulse signal may be a low-voltage level pulse signal. Therefore, step 210 in FIG. 2 corresponds to the step indicated by t11 in the drawing. And in this step, the subpixels 110 in all rows are scanned simultaneously, and writing of the first data voltage is completed.

In step 220, while providing the second data voltage to a plurality of data lines one line at a time and providing the second data voltage to one data line, a scan line connected to the subpixel to which the second data voltage is to be written Provides a scanning pulse signal simultaneously.

For example, since the data voltage to be written to different subpixels 110 within one subframe may be different, after the first data voltage is written to the subpixel 110 in step 210, In the display panel, a new data voltage must be written to the subpixel 110 corresponding to the second data voltage, and the writing method is to write the second data voltage to the subpixel 110 corresponding to the second data voltage in the display panel. It may be written column by column. When writing the second data voltage, the second data voltage is provided to a plurality of data lines one line at a time, and while providing the second data voltage to one data line, the subpixel to which the second data voltage is to be written ( By simultaneously providing a scan pulse signal to the scan line connected to the corresponding data line, the subpixel 110 on which the second data voltage is to be written is turned on in the subpixel 110 electrically connected to the corresponding data line, Since the data voltage is ensured to be written, and the scan pulse signal is not provided to the scan line connected to the subpixel 110 to which the first data voltage is to be written, the subpixel 110 to which the first data voltage is to be written is The first data voltage written in step 210 can be maintained. Referring to FIGS. 2 and 3, step 220 in FIG. 2 corresponds to the step t12 in FIG. 3, and with reference to FIGS. 1 and 3, the subpixels of the three rows in the front of the display panel 110 is described as an example. As an example, there is no subpixel 110 in the first column to which the second data voltage should be written, and in the subpixel 110 in the second column, there is no subpixel 110 in the first row, The second data voltage must be written to the subpixels 110 located in the 3rd and 7th rows, and the subpixels 110 in the 3rd column must be written to the 1st, 2nd, 4th, and mth rows. A second data voltage must be written to the subpixel 110; When providing the second data voltage to the subpixel r1 in the first row electrically connected to the first data line D1, not all scan pulse signals are provided to the plurality of scan lines; When providing the second data voltage to the subpixel r2 in the second column electrically connected to the second data line D2, the subpixels 110 in the first, third, and seventh rows are electrically connected to the second data line D2. simultaneously providing a scan pulse signal to the scan line and writing a second data voltage to the subpixels 110 located in the first, third, and seventh rows of the subpixels 110 in the second column; When providing the second data voltage to the third column subpixel r3 electrically connected to the third data line D3, the first, second, fourth, and mth row subpixels 110 A scan pulse signal is provided to a scan line electrically connected to a scan line, and a second data voltage is applied from the subpixel 110 in the second column to the subpixels 110 located in the first, second, fourth, and mth rows. Enter . In this step, rather than using the method of scanning the subpixels 110 row by row (after scanning the subpixels 110 in one row, the subpixel 110 in the next row is scanned), one data While providing the second data voltage to the line, the subpixel 110 electrically connected to the corresponding data line simultaneously scans the row in which the subpixel 110 to be written is located, so that the subpixel 110 in each row is The scanning time for the subpixels 110 is independent of the number of rows of the subpixels 110 in the display panel, and depends on the number of columns of the subpixels 110 in the display panel and the second data voltage at the subpixels 110 in each row. It is related to the number of corresponding subpixels 110. Since the scanning time of the subpixels 110 in each row is independent of the number of rows of the subpixels 110, the scanning time for the subpixels 110 in each row is relatively large due to the relatively large number of rows of the subpixels 110 in the display panel. A situation where the time is too short does not occur, and a display abnormal situation caused by the scan time of the subpixels 110 of each row being short due to too many display panel rows in the related technology is prevented.

The digital driving method of a display panel provided by an embodiment of the present application includes simultaneously providing a scan pulse signal to a plurality of scan lines and providing a first data voltage to a plurality of data lines simultaneously; While providing the second data voltage to the plurality of data lines one by one and providing the second data voltage to one of the data lines, the scan line connected to the subpixel to which the second data voltage is to be written is provided. Through simultaneously providing the scanning pulse signals, the scanning time of the subpixels in each row becomes independent of the number of subpixel rows in the display panel, and because the number of rows in the display panel in the related art is too large, the subpixels in each row (110 ) prevents display abnormalities caused by a short scanning time.

In one embodiment, m>n+1.

Display panels in related technologies, especially mobile phones, are generally vertical display panels, and in a vertical display panel, the number of rows (m) of subpixels 110 is generally much larger than the number of columns (n) of subpixels 110. In a vertical display panel, display abnormalities due to too many rows of subpixels 110 are particularly serious. In an embodiment of the present application, by simultaneously providing a scan pulse signal to a plurality of scan lines and simultaneously providing a first data voltage to a plurality of data lines, the first voltage is simultaneously provided in all subpixels 110 of all display panels. Realizes writing data voltage; While providing the second data voltage to a plurality of data lines one line at a time and providing the second data voltage to one data line, a scan pulse is applied to the scan line connected to the subpixel 110 where the second data voltage is to be written. By simultaneously providing signals, the time for writing the data voltage to each subpixel 110 can be extended. Illustratively, if, within one subframe, the total scanning time for all subpixels 110 in the display panel is T, then when using a conventional scanning method, the scanning time of the subpixels 110 in each row (each (time corresponding to the width of the scan pulse signal) is T/m, and when using the conventional scanning algorithm, the data voltage of one row of subpixels 110 is generally written simultaneously, and the data voltage in each subpixel 110 is The time at which the voltage is written is T/m. However, when using the digital driving scan algorithm provided by the embodiment of the present application, the time corresponding to the width of each scan pulse signal is T/(n+1), and the time corresponding to the width of each scan pulse signal is one This is the same as the time at which the data voltage is written to the subpixel 110 of . Since m>n+1, T/m<T/(n+1), therefore, the digital driving method provided by this embodiment can widen the width of the single scan pulse signal, and correspondingly, each row The time for scanning the subpixel 110 becomes longer, and the time for writing the data voltage to the subpixel 110 becomes longer. As a result, the data voltage corresponding to the subpixel 110 can be sufficiently written, and each sub By allowing the pixel 110 to normally display gray scale, the display effect is improved.

In one embodiment, the first data voltage is a bright state data voltage and the second data voltage is a dark state data voltage.

As described above, in the digital driving method, the data voltage written to the subpixel 110 generally includes only the bright state data voltage and the dark state data voltage. A scanning pulse signal is simultaneously provided to a plurality of scan lines, and a bright state data voltage is simultaneously provided to a plurality of data lines, so that the bright state data voltage is initially written to all subpixels 110 in the display panel, and some subpixels are initially written. When the data voltage corresponding to the pixel 110 is a dark state data voltage, the dark state data voltage is provided to each data line, and while the dark state data voltage is provided to one data line, the data line and the corresponding data line are electrically connected. By performing a scan on the row where the subpixel 110 where the dark state data voltage is to be written is located in the connected subpixel 110, the scanning time of each row is independent of the number of rows of subpixels 110 in the display panel. , Prevents display abnormalities caused by a short scanning time of the subpixels 110 in each row due to the large number of rows of the display panel.

In one embodiment, the first data voltage is a dark state data voltage and the second data voltage is a bright state data voltage.

For example, a scan pulse signal is simultaneously provided to a plurality of scan lines and a dark state data voltage is simultaneously provided to a plurality of data lines, so that the dark state data voltage is initially written to all subpixels 110 in the display panel. When the data voltage corresponding to some subpixels 110 is a bright state data voltage, the bright state data voltage is provided to each data line, and while the bright state data voltage is provided to one data line, By performing a scan on the row where the subpixel 110 where the bright state data voltage is to be written is located in the subpixel 110 electrically connected to the data line, the scanning time of each row is reduced by the subpixel 110 in the display panel. It is independent of the number of rows, and prevents display abnormalities caused by a short scanning time of the subpixels 110 in each row due to the large number of rows of the display panel.

Figure 5 is a flowchart of a digital driving method of another display panel provided by an embodiment of the present application. Referring to Figure 5, the digital driving method includes steps 310 to 320.

In step 310, at the start of each subframe, a scan pulse signal is simultaneously provided to a plurality of scan lines, and a first data voltage is simultaneously provided to a plurality of data lines.

By way of example, the start stage of each subframe may be the time at which each subframe is entered, and after entering one subframe, a scan pulse signal is simultaneously provided to a plurality of scan lines, and a scan pulse signal is simultaneously provided to a data line. By providing 1 data voltage at the same time, the time of each sub-frame is fully utilized, so that there is sufficient time to write the second data voltage later, so that the data voltage can be sufficiently written to the subpixel 110, Ensure excellent display effects.

In step 320, while providing the second data voltage to a plurality of data lines one by one and providing the second data voltage to one data line, a scan line connected to the subpixel to which the second data voltage is to be written Provides a scanning pulse signal simultaneously.

In one embodiment, each subpixel 110 includes a digital driving pixel circuit. Referring to FIG. 4, the digital driving pixel circuit includes a light emitting element D5 and a light emission control module electrically connected to the light emitting element D5. 410), where the third transistor T3 is used as the light emission control module 410.

Figure 6 is a flowchart of a digital driving method of another display panel provided by an embodiment of the present application. Referring to Figure 6, the digital driving method includes steps 510 to 530.

In step 510, a scan pulse signal is simultaneously provided to a plurality of scan lines, and a first data voltage is simultaneously provided to a plurality of data lines.

In step 520, while providing the second data voltage to a plurality of data lines one by one and providing the second data voltage to one data line, a scan line connected to the subpixel to which the second data voltage is to be written Simultaneously provides a scanning pulse signal to; Within one subframe, when the second data voltage is provided to a plurality of data lines one by one, the light emission control module in the digital driving pixel circuit of each subpixel is controlled to turn off.

In step 530, after providing the second data voltage to all data lines, the light emission control module in the digital driving pixel circuit of each subpixel is controlled to turn on.

Referring to FIGS. 3 and 4 , for example, when the third transistor T3 is a P-type transistor, when the second data voltage is provided to a plurality of data lines one line at a time, the light emission control signal input terminal EM is supplied. By inputting a high voltage level, the light emission control module in the digital driving pixel circuit of each subpixel 110 is controlled to turn off, so that when the second data voltage is written to the subpixel 110, the subpixel 110 emits light. After providing the second data voltage to all data lines, a low voltage level is input to the emission control signal input terminal (EM), so that the emission control module in the digital driving pixel circuit of each subpixel 110 is By controlling it to turn on, after all the data voltages corresponding to the subpixels 110 in the display panel are written, the subpixels 110 corresponding to the bright state data voltage in the full screen are made to emit light together. This allows the subpixel 110 to conveniently control the emission time within the subframe, ensuring normal gray scale display, and is advantageous for improving the display effect.

What needs to be explained is that while simultaneously providing scan pulse signals to a plurality of scan lines and simultaneously providing the first data voltage to a plurality of data lines, the light emission control module is controlled to turn off, so that when writing the first data voltage Prevents the display effect from being affected by the light emitting element D5 emitting light.

Referring to FIG. 3, the method of driving the display panel further includes the following steps.

Within any one subframe, a signal output to at least one scan line includes at least two scan pulse signals.

For example, within any one subframe, the number of scan pulse signals output to one scan line is the number of subpixels in which the second data voltage is to be written among the rows of the subpixels 110 electrically connected to the scan line. It is determined by the number of pixels 110. Within any one sub-frame, a signal output to at least one scan line includes at least two scan pulse signals, whereby two sub-pixels 110 of at least one row of sub-pixels 110 are 2 Data voltage can be written. Additionally, since the signal output to at least one scan line includes at least two scan pulse signals, the scan time for one row of subpixels 110 becomes relatively longer, and it takes longer to sufficiently write the second data voltage. It is advantageous and ensures excellent display effects.

Referring to FIG. 3, in one embodiment, the digital driving method includes a first step (t11) and a second step (t12).

In the first step (t11), the scan pulse signals provided to the plurality of scan lines all overlap.

In the second step (t12), there is overlap in the scan pulse signals provided to at least two scan lines.

Exemplarily, in the first step, scan pulse signals are simultaneously provided to a plurality of scan lines, and the scan pulse signals provided to the scan lines are all overlapped. Within one subframe, all data voltages corresponding to subpixels located in different rows of the same column may be the second data voltage, and in that case, a scan pulse signal is applied to the subpixels corresponding to the second data voltage in the same column. must be provided simultaneously, there is overlap in the scan pulse signals provided to at least two scan lines, so that the second data voltage ensures normal writing to at least two subpixels 110 in the same column, and achieves a display effect. Secure.

Referring to Figure 3, in the second step (t12) of one embodiment, the scan pulse signal provided to the scan line includes scan pulse signals of different pulse widths.

For example, in some display screens, all of the data voltages corresponding to subpixels in adjacent columns of the same row may be the second data voltage, and therefore, when the second data voltage is provided to the data lines one by one, some rows In the case of pixels, at least two scan pulse signals must be provided in succession, so the width after a plurality of scan pulse signals are overlapped becomes wider, and the scan pulse signals provided to the scan line include scan pulse signals with different pulse widths. do. Therefore, when the scan pulse signal provided to the scan line includes scan pulse signals of different pulse widths, and the data voltages corresponding to adjacent subpixels in the same row are all second data voltages, the second data voltage is normally written. This ensures excellent display effects.

An embodiment of the present application further provides a display panel, a structural schematic diagram of the display panel may refer to Figure 1, and the display panel is driven by a method of driving a display panel provided by any embodiment of the present application. The display panel provided by an embodiment of the present application is driven by a method of driving a display panel provided by any embodiment of the present application, and the display panel includes subpixels arranged in an array of m rows and n columns, and a plurality of scan lines. and a plurality of data lines, where each scan line connects one row of subpixels, and each data line connects one column of subpixels, where m and n are all integers greater than or equal to 1. The display panel further includes a scan driving circuit, a data driving circuit, a data processor, and a timing controller, wherein a displayed data stream is input to the data processor, and the timing controller drives the scan driving circuit and the data driving circuit. Each timing is controlled. Simultaneously providing a scan pulse signal to a plurality of scan lines, simultaneously providing a first data voltage to a plurality of data lines, providing a second data voltage to each of the plurality of data lines, and providing a second data voltage to one of the data lines. While providing the second data voltage, a scan pulse signal is simultaneously provided to the scan line connected to the subpixel on which the second data voltage is to be written, so that the scan time of the subpixel in each row is adjusted to the subpixel in the display panel. It is independent of the number of pixel rows, and prevents display abnormalities caused by a short scanning time of the subpixels 110 in each row due to too many rows of the display panel in related technologies.

Claims (16)

In the digital driving method of the display panel,
The display panel includes subpixels, a plurality of scan lines, and a plurality of data lines arranged in an array of m rows and n columns, each of the scan lines is connected to the subpixel of one row, and each of the data lines is connected to the subpixels in one row, where m and n are both integers greater than or equal to 1;
The digital driving method of the display panel is:
Simultaneously providing scan pulse signals to the plurality of scan lines and simultaneously providing a first data voltage to the plurality of data lines;
The scan line connected to the subpixel to which the second data voltage is to be written while providing the second data voltage to the plurality of data lines one by one and providing the second data voltage to one of the data lines. It includes simultaneously providing a scanning pulse signal to
Here, the screen of one frame is divided into a plurality of sub-frames, each of the sub-frames includes a data writing stage and a driving light-emitting stage, and in different sub-frames of the display screen of one frame, the driving light-emitting stage The time length is different, and the data writing step includes a first step and a second step; In the first step, the scan pulse signals provided to the plurality of scan lines are all overlapped; In the second step, there is overlap in the scan pulse signals provided to at least two of the scan lines;
The digital driving method of the display panel is to control whether subpixels emit light within different subframes, thereby realizing displays of different gray scales by controlling the length of time each subpixel emits light within one frame. A digital driving method of a display panel further comprising: According to clause 1,
m>n+1,
Here, the first data voltage is a bright state data voltage, and the second data voltage is a dark state data voltage; The first data voltage is a dark state data voltage, and the second data voltage is a bright state data voltage. According to clause 2,
A digital driving method of a display panel, wherein the dark state data voltage and the bright state data voltage are each fixed values. According to clause 1,
Dividing a display screen of one frame into a plurality of sub-frames, simultaneously providing scan pulse signals to the plurality of scan lines, and simultaneously providing a first data voltage to the plurality of data lines include:
At the start of each sub-frame, simultaneously providing a scan pulse signal to the plurality of scan lines and simultaneously providing the first data voltage to the plurality of data lines. Digital driving method. According to clause 4,
A digital driving method of a display panel, characterized in that the start stage of each sub-frame is the time at which each sub-frame is entered. According to clause 1,
Each of the sub-pixels includes a digital driving pixel circuit, where the digital driving pixel circuit includes a light-emitting element and a light-emitting control module electrically connected to the light-emitting element, and applies a second data voltage to the plurality of data lines. Providing a scan pulse signal one line at a time, while providing the second data voltage to one data line, simultaneously providing a scan pulse signal to the scan line connected to the subpixel to which the second data voltage is to be written,
Controlling the light emission control module in the digital driving pixel circuit of each subpixel to be turned off when the second data voltage is provided to the plurality of data lines one line at a time within any one subframe. It includes steps;
After providing the second data voltage to all data lines,
It further includes controlling a light emission control module in the digital driving pixel circuit of each sub-pixel to be turned on,
Here, the digital driving pixel circuit further includes a first transistor, a second transistor, a storage capacitor, a data voltage input terminal, a scanning signal input terminal, an emission control signal input terminal, a first power supply voltage input terminal, and a second power supply voltage input terminal. Digital driving method of a display panel. According to clause 4,
A digital driving method of a display panel, wherein within any one of the sub-frames, a signal output to at least one scan line includes at least two scan pulse signals. According to clause 1,
In the second step, the scan pulse signal provided to the scan line includes scan pulse signals of different pulse widths. A display panel driven by the display panel driving method according to any one of claims 1 to 8. According to clause 9,
It includes subpixels, a plurality of scan lines, and a plurality of data lines arranged in an array of m rows and n columns, wherein each scan line is connected to the subpixels of one row, and each of the data lines is connected to the subpixels of one row. Connected to a subpixel, where m and n are both integers greater than or equal to 1,
The display panel further includes a scan driving circuit, a data driving circuit, a data processor, and a timing controller, wherein a displayed data stream is input to the data processor, and the timing controller drives the scan driving circuit and the data driving circuit. A display panel characterized by individual control of timing. delete delete delete delete delete delete