CN102236223B - Monitor and its display panel - Google Patents

Abstract

The invention relates to a display and a display panel thereof. The data lines are arranged substantially perpendicular to the scan lines. The pixels are respectively and electrically connected with the corresponding data lines and the corresponding scanning lines, and the pixels are arranged in a matrix mode. The data lines are divided into a plurality of groups. Each group is arranged between two adjacent rows of pixels and is provided with N data lines, wherein N is a positive integer greater than or equal to 3. At least a first group of the data lines in the groups crosses a part of the scanning lines. The remaining data lines of the first group span all the scan lines.

Description

Monitor and its display panel

technical field

The present invention relates to a display and its display panel, and in particular to a crosstalk-reduced display and its display panel.

Background technique

In recent years, with the vigorous development of semiconductor technology, portable electronic products and flat panel display products are also emerging. Among the many types of flat panel displays, liquid crystal displays (Liquid Crystal Display, TFT-LCD) have become the mainstream of display products due to their advantages of low voltage operation, no radiation scattering, light weight and small size.

FIG. 1 is a schematic diagram of a display panel of a conventional liquid crystal display. As shown in FIG. 1 , each pixel P of the display panel 100 is coupled to the corresponding scanning line 110 and data line 120 through an active device (that is, a thin film transistor) TR, and only a pixel P is arranged between every two columns of pixels. A data line 120 . In other words, the same row of pixels will share one data line 120 . In addition, the frame rate of the LCD shown in Figure 1 is generally 60Hz (Hertz), that is, the frame rate is updated 60 times per second, and the faster the frame rate, the better the image quality of the LCD.

In order to display a clearer dynamic image quality, there are liquid crystal displays with an image update frequency of 120 Hz and 240 Hz currently on the market. However, as the picture update frequency increases, the charging time of each pixel P is relatively reduced, where the charging time=(1/picture update frequency)/the total number of scanning lines. For example, assuming that the resolution of the display panel 100 is 1920*1080 (Full HD), and it is applied under the condition that the frame update frequency is 120Hz, the charging time of each pixel P is 1/(120*1080)≒7us . At this time, the charging time of each pixel P is still within the allowable range, but if the frame update frequency is further increased, the charging time of the pixels P will be too low, resulting in insufficient charging.

To be more clear, assuming that the resolution of the display panel 100 is also 1920*1080, but it is applied under the condition that the frame update frequency is 240Hz, the charging time of each pixel P will be shortened to 1/(240*1080)≒ 3.5us. Due to the short charging time, the pixels cannot be charged to the correct voltage level, and because of this, each pixel P cannot reflect the correct gray scale (that is, the image is distorted), thereby reducing the image quality of the liquid crystal display. In view of this, a driving method called hG2D (half gate, two data) was developed.

Referring to FIG. 2 , the display panel 200 is constructed according to the hG2D driving method, and two data lines 210 are arranged between two rows of pixels. As shown in FIG. 2 , in each column of pixels, two adjacent pixels P up and down are coupled to different data lines 210 . At this time, two rows of pixels can be charged at the same scanning time, that is, the charging time of each pixel P in the display panel 200 is twice the charging time of each pixel P in the display panel 100 .

For example, assuming that the resolution of the display panel 200 is 1920*1080 and it is applied under the condition that the frame update frequency is 240 Hz, the charging time of each pixel P is 2*1/(240*1080)≒7 us. In this way, the problem of insufficient charging time for each pixel P can be solved when the Full HD display panel is applied to a picture update frequency of 240Hz, but if the picture update frequency is increased or the display panel resolution is increased, each pixel P The problem of insufficient charging time will occur again.

FIG. 3 and FIG. 4 are schematic diagrams of display panels of liquid crystal displays in US Pat. Nos. US6809719B2 and 20080068524, respectively, wherein US6809719B2 is the closest prior art. According to the above, if the picture update frequency or resolution is higher than that of the display panel 200, for example, the picture update frequency is 360Hz, 480Hz or the resolution is 4K2K (ie 3840*2160), even if the charging time of each pixel P increases to two After doubling, it will still be obviously insufficient. Therefore, the display panels 300 and 400 mentioned in US Patent Nos. 6809719 and 20080068524 respectively can increase the charging time of each pixel P.

Taking the display panel 300 as an example, each pixel P includes a liquid crystal capacitor _CL and a storage capacitor C _S , and three data lines 310 are arranged between every two rows of pixels. Therefore, in each column of pixels, every three adjacent pixels P are respectively coupled to different data lines 310, so that three rows of pixels can be charged at the same scanning time, and thus the power of each pixel P in the display panel 300 can be charged. The charging time is three times that of each pixel P in the display panel 100 . Taking the display panel 400 as an example, four data lines 410 are arranged between every two columns of pixels. Therefore, in each column of pixels, every four adjacent pixels P are respectively coupled to different data lines 410, so that four rows of pixels can be charged in the same scanning time, and thus the power of each pixel P in the display panel 400 The charging time is four times that of each pixel P in the display panel 100 .

Based on the above, the display panel 300 can be regarded as a driving manner of three data lines (3-data), and the display panel 400 can be regarded as a driving manner of four data lines (4-data). However, in the above-mentioned display panels 300 and 400, some pixels P have to cross other data lines 310 or 410 to be coupled to the corresponding data lines 310 or 410, such as A and B shown in FIG. 3 and FIG. 4 . At this time, the cross-connection of the line will form unnecessary cross-over capacitance (cross-over capacitance), and then produce the interference (crosstalk) phenomenon of partial color shift of the picture. In addition, if the driving method of 3-data or 4-data does not connect the pixel P and the data line 310 or 410 through the line jumper, it needs to be completed by using the four-side driving method, that is, the upper and lower ends of the display panel will be The control panel is configured so that the cost of the display panel increases.

Contents of the invention

The invention provides a display panel, which can increase the charging time of pixels.

The invention provides a display which can avoid cross-connection of lines to avoid interference phenomenon of the display panel.

The invention provides a display panel, which includes a plurality of scan lines, a plurality of data lines and a plurality of pixels. The data lines are generally arranged perpendicular to the scan lines. The pixels are respectively electrically connected to the corresponding data lines and scan lines, and the pixels are arranged in a matrix. Wherein, the data lines are divided into a plurality of groups, each group is arranged between two adjacent columns of pixels and has N data lines, and N is a positive integer greater than or equal to 3. Part of the data lines of at least a first group of the groups spans part of the scan lines, and the rest of the data lines of the first group span all the scan lines.

The present invention further provides a display, which includes a display panel and a backlight module. The backlight module is used to provide the light source required by the display panel. The display panel includes a plurality of scan lines, a plurality of data lines and a plurality of pixels. The data lines are generally arranged perpendicular to the scan lines. The pixels are respectively electrically connected to the corresponding data lines and scan lines, and the pixels are arranged in a matrix. Wherein, the data lines are divided into a plurality of groups, each group is arranged between two adjacent columns of pixels and has N data lines, and N is a positive integer greater than or equal to 3. Part of the data lines of at least a first group of the groups spans part of the scan lines, and the rest of the data lines of the first group span all the scan lines.

In an embodiment of the present invention, when N is 3, the first group includes the first data line, the second data line and the third data line. The first data line straddles the part of the scan lines for receiving the first data signal and transmitting the first data signal to a part of the even pixels in the first row of pixels corresponding to two adjacent rows of pixels in the first group. The second data line straddles the part of the scan lines for receiving the second data signal and transmitting the second data signal to a part of odd pixels in the second row of pixels corresponding to two adjacent rows of pixels in the first group. The third data line crosses all the scan lines for receiving the third data signal and transmitting the third data signal to the remaining even pixels in the first row of pixels and the remaining odd pixels in the second row of pixels.

In an embodiment of the present invention, the part of even pixels in the above-mentioned first column of pixels does not cross the second and third data lines to receive the first data signal, and the part of odd pixels in the above-mentioned second column of pixels do not cross the first and third data lines to receive the second data signal, and the remaining even pixels of the above-mentioned first column of pixels and the remaining odd pixels of the second column of pixels do not straddle the first and second The data line is used to receive the first data signal.

In an embodiment of the present invention, when N is 4, the first group includes the first data line, the second data line, the third data line and the fourth data line. The first data line straddles the part of the scan lines for receiving the first data signal and transmitting the first data signal to a part of the even pixels in the first row of pixels corresponding to two adjacent rows of pixels in the first group. The second data line straddles the part of the scan lines for receiving the second data signal and transmitting the second data signal to a part of odd pixels in the second row of pixels corresponding to two adjacent rows of pixels in the first group. The third data line crosses all the scan lines for receiving the third data signal and transmitting the third data signal to the remaining even pixels of the first row of pixels. The fourth data line straddles all the scan lines for receiving the fourth data signal and transmitting the fourth data signal to the remaining odd pixels of the second row of pixels.

In an embodiment of the present invention, the part of the even pixels in the above-mentioned first row of pixels does not cross the second, third and fourth data lines to receive the first data signal, and the above-mentioned part of the second row of pixels Part of the odd pixels do not cross the first, third and fourth data lines to receive the second data signal, and the remaining even pixels of the above-mentioned first row of pixels do not cross the first, second and fourth data lines to receive the second data signal. For receiving the third data signal, the remaining odd pixels in the second row of pixels do not straddle the first, second and third data lines to receive the fourth data signal.

In an embodiment of the present invention, when N is 4, the first group includes the first data line, the second data line, the third data line and the fourth data line. The first data line straddles the part of the scan lines for receiving the first data signal and transmitting the first data signal to a part of the even pixels in the first row of pixels corresponding to two adjacent rows of pixels in the first group. The second data line straddles the part of the scanning lines for receiving the second data signal and transmitting the second data signal to a part of the even pixels in the second row of pixels of the two adjacent rows of pixels corresponding to the first group. The third data line crosses all the scan lines for receiving the third data signal and transmitting the third data signal to the remaining even pixels of the first row of pixels. The fourth data line crosses all the scan lines for receiving the fourth data signal and transmitting the fourth data signal to the remaining even pixels of the second row of pixels.

In an embodiment of the present invention, the part of the even pixels in the above-mentioned first row of pixels does not cross the second, third and fourth data lines to receive the first data signal, and the above-mentioned part of the second row of pixels Part of the even pixels do not cross the first, third and fourth data lines to receive the second data signal, and the remaining even pixels of the above-mentioned first row of pixels do not cross the first, second and fourth data lines to receive the second data signal. For receiving the third data signal, the remaining even pixels of the above-mentioned second row of pixels do not straddle the first, second and third data lines to receive the fourth data signal.

In an embodiment of the present invention, when N is 4, the first group includes the first data line, the second data line, the third data line and the fourth data line. The first data line straddles the part of the scan lines for receiving the first data signal and transmitting the first data signal to a part of odd pixels in the first row of pixels corresponding to two adjacent rows of pixels in the first group. The second data line straddles the part of the scan lines for receiving the second data signal and transmitting the second data signal to a part of odd pixels in the second row of pixels corresponding to two adjacent rows of pixels in the first group. The third data line crosses all the scan lines for receiving the third data signal and transmitting the third data signal to the remaining odd pixels in the first row of pixels. The fourth data line straddles all the scan lines for receiving the fourth data signal and transmitting the fourth data signal to the remaining odd pixels of the second row of pixels.

In an embodiment of the present invention, the part of the odd pixels in the above-mentioned first row of pixels does not straddle the second, third and fourth data lines to receive the first data signal, and the above-mentioned second row of pixels Part of the odd pixels do not cross the first, third and fourth data lines to receive the second data signal, and the remaining odd pixels of the above-mentioned first row of pixels do not cross the first, second and fourth data lines to receive the second data signal. For receiving the third data signal, the remaining odd pixels in the second row of pixels do not straddle the first, second and third data lines to receive the fourth data signal.

In an embodiment of the present invention, the i-th scanning line is electrically connected to all pixels in the i-th row of pixels for correspondingly receiving scanning signals, and i is a positive integer.

Based on the above, in the display and its display panel of the present invention, the data lines on the display panel are divided into multiple groups, and the data lines in each group are adjacent and do not cross pixels. In each group, some data lines straddle some scan lines, and the remaining data lines straddle all scan lines. Therefore, all the pixels in each row of pixels are respectively coupled to some data lines in the two groups, and the pixels and the data lines can be directly coupled. In this way, it is avoided that the lines are crossed to form a crossover capacitance, thereby avoiding the interference phenomenon of local color shift caused by the crossover capacitance.

In order to make the above-mentioned features and advantages of the present invention more comprehensible, the following specific embodiments are described in detail together with the accompanying drawings.

Description of drawings

1 and 2 are schematic diagrams of a display panel of a conventional liquid crystal display, respectively.

FIG. 3 and FIG. 4 are schematic diagrams of display panels of liquid crystal displays in US Pat. Nos. 6,809,719 and 2,008,006,8524, respectively.

FIG. 5A is a system block diagram of a display 500 according to an embodiment of the present invention.

FIG. 5B is a schematic structural diagram of a liquid crystal display panel 501 according to an embodiment of the present invention.

FIG. 5C is a schematic diagram of driving waveforms of the liquid crystal display panel 501 according to an embodiment of the present invention.

FIG. 5D is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention.

FIG. 6A is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention.

FIG. 6B is a schematic diagram of driving waveforms of a liquid crystal display panel 501 according to another embodiment of the present invention.

FIG. 7 is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention.

FIG. 8 is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention.

Figure number:

100, 200, 300, 501: display panel

110, G51～G59, G61～G69, G6a～G6c: scanning line

120, 210, 310, 410, S51～S59, S61～S69, S6a～S6c, S71～S79, S7a～S7c, S81～S89, S8a～S8c: Data cable

500: display

503: Gate driver

505: Source driver

507: Timing controller

509: Backlight module

C _L : Liquid crystal capacitance

C _S : storage capacitor

D51～D59, D61～D69, D6a～D6c, D71～D79, D7a～D7c, D81～D89, D8a～D8c: data signal

GP51～GP53, GP61～GP63, GP71～GP73, GP81～GP83: group

P, PX: pixel

TR: active element

Detailed ways

Reference will now be made in detail to embodiments of the invention, examples of which are illustrated in the accompanying drawings. In addition, wherever possible, elements/components/symbols with the same reference numerals are used in the drawings and embodiments to represent the same or similar parts.

FIG. 5A is a system block diagram of a display 500 according to an embodiment of the present invention. Please refer to FIG. 5A, a display 500 includes a display panel (display panel) 501, a gate driver (gate driver) 503, a source driver (source driver) 505, a timing controller (timing controller, T-con) 507, and a backlight module (backlight module) 509. Wherein, the display 500 may be a thin film transistor liquid crystal display (TFT LCD), so the display panel 501 will correspond to a thin film transistor display panel.

In addition, the backlight module 509 is used to provide the light source required by the display panel 501; and the timing controller 507 is used to control the operation of the gate driver 503 and the source driver 505, so that the gate driver 503 and the source driver 505 respectively generate A scan signal (scan signal) and a data signal (data signal) are used to drive the display panel 501 .

To be more clear, FIG. 5B is a schematic structural diagram of a liquid crystal display panel 501 according to an embodiment of the present invention. Please refer to FIG. 5A and FIG. 5B together. The display panel 501 may include a plurality of scan lines G51 - G59 , a plurality of data lines S51 - S59 , and a plurality of pixels PX arranged in an array. Wherein, the numbers of scan lines and data lines shown in FIG. 5B are for illustration, not the actual structure of the display panel 501 , and the present invention is not limited thereto.

The data lines S51 - S59 are substantially perpendicular to the scan lines G51 - G59 . The scanning line G51 is electrically connected to all the pixels PX in the first row of pixels, the scanning line G52 is electrically connected to all the pixels PX in the second row of pixels, and so on, and the remaining scanning lines G53-G59 are correspondingly electrically connected to the first All the pixels PX in the 3rd to 9th row of pixels. In addition, the scan lines G51 , G52 and G57 receive the same scan signal, the scan lines G53 , G54 and G58 receive the same scan signal, and the scan lines G55 , G56 and G59 receive the same scan signal, which will be described in detail later.

As shown in FIG. 5B , the data lines S51 - S59 can be divided into groups GP51 , GP52 and GP53 . Among them, the group GP51 has data lines S51-S53, the group GP52 has data lines S54-S56, and the group GP53 has data lines S57-S59. In this embodiment, the group GP52 is arranged between the pixels in the first column and its adjacent pixels in the second column. First look at the group GP51 , the data line S51 crosses the scan lines G51 - G56 for receiving the data signal D51 . The data line S52 crosses the scan lines G51 - G59 for receiving the data signal D52 and transmitting the data signal D52 to the odd pixels in the 7th - 9th row of the 1st column of pixels adjacent to the group GP51 . The data line S53 crosses the scan lines G51 - G56 for receiving the data signal D53 and transmitting the data signal D53 to the odd pixels in the first - sixth rows of the first column of pixels.

Then see the group GP52, the data line S54 spans the scanning lines G51-G56 to receive the data signal D54, and transmit the data signal D54 to the pixels in the 1st-6th row in the first column adjacent to the group GP52 even pixels. The data line S55 crosses the scan lines G51-G59, and is used to receive the data signal D55 and transmit the data signal D55 to the even pixels in the 7th-9th rows and the 2nd column pixels in the 1st column of pixels adjacent to the group GP52 Odd pixels in the 7th to 9th rows. The data line S56 crosses the scan lines G51 - G56 for receiving the data signal D56 and transmitting the data signal D56 to the odd pixels in the first - sixth rows of the second column of pixels.

Looking at the group GP53 again, the data line S57 straddles the scan lines G51-G56 to receive the data signal D57 and transmit the data signal D57 to the pixels in the 1st-6th row in the second column adjacent to the group GP53. even pixels. The data line S58 crosses the scan lines G51 - G59 and is used for receiving the data signal D58 and transmitting the data signal D58 to the even pixels in the 7th - 9th rows of the pixels in the second column. The data line S59 straddles the scan lines G51 - G56 for receiving the data signal D59.

Based on the above, the odd pixels in the first to sixth rows of the pixels in the first column can be directly coupled to the data line S53 to receive the data signal D53 without crossing the data lines S51 and S52. The odd pixels in the 7th to 9th rows of the 1st column of pixels can be directly coupled to the data line S52 to receive the data signal D52 without crossing the data lines S51 and S53. The even pixels in the 1st to 6th rows of the 1st column of pixels can be directly coupled to the data line S54 to receive the data signal D54 without crossing the data lines S55 and S56. The odd pixels in the 1st to 6th rows in the second column of pixels can be directly coupled to the data line S56 to receive the data signal D56 without crossing the data lines S54 and S55.

On the other hand, the even pixels in the 7th to 9th rows of the pixels in the first column and the odd pixels in the 7th to 9th rows of the second column of pixels can be directly coupled to the data line S55 to receive the data signal D55 without horizontal Across the data lines S54 and S56. Even pixels in rows 1 to 6 in the second column of pixels can be directly coupled to the data line S57 to receive the data signal D57 without crossing the data lines S58 and S59 . The even pixels in the 7th to 9th rows of the 2nd column of pixels can be directly coupled to the data line S58 to receive the data signal D58 without crossing the data lines S57 and S59. Thereby, cross-connection of lines can be avoided, and interference (crosstalk) caused by cross-connection capacitors can be reduced.

FIG. 5C is a schematic diagram of driving waveforms of the liquid crystal display panel 501 according to an embodiment of the present invention. Please refer to FIG. 5B and FIG. 5C together. According to the above, the scanning lines G51, G52 and G57 receive the same scanning signal, the scanning lines G53, G54 and G58 receive the same scanning signal, and the scanning lines G55, G56 and G59 receive the same scanning signal. Therefore, the pixels PX coupled to the scan lines G51 , G52 and G57 are turned on at the same time. At this time, the pixels PX in the first row will receive the data signals D53 and D56 respectively, the pixels PX in the second row will receive the data signals D54 and D57 respectively, and the pixels PX in the seventh row will receive the data signals D52 and D57 respectively. D55.

Next, the pixels PX coupled to the scan lines G53 , G54 and G58 are simultaneously turned on. At this time, the pixels PX in the third row will receive the data signals D53 and D56 respectively, the pixels PX in the fourth row will receive the data signals D54 and D57 respectively, and the pixels PX in the eighth row will receive the data signals D55 and D57 respectively. D58. Afterwards, the pixels PX coupled to the scan lines G55 , G56 and G59 are simultaneously turned on. At this time, the pixels PX in the fifth row will receive the data signals D53 and D56 respectively, the pixels PX in the sixth row will receive the data signals D54 and D57 respectively, and the pixels PX in the ninth row will receive the data signals D52 and D57 respectively. D55. In this way, three rows of pixels are turned on during the same scanning period, so as to increase the charging time of each pixel PX, thereby suppressing the problem that the pixel PX cannot respond to the correct gray scale due to insufficient charging time.

For example, when the display panel 501 is a FULL HD display panel, the display panel 501 is configured with 1080 scan lines. At this time, the 1st to 720th scanning lines in the display panel 501 are regarded as a scanning area, and the pixels coupled to the 1st to 720th scanning lines turn on two rows of pixels during one scanning period. In addition, the 721st to 1080th scan lines in the display panel 501 are regarded as another scan area, and the pixels coupled to the 721st to 1080th scan lines turn on a row of pixels during one scan period. Therefore, three rows of pixels are turned on during one scanning period, so that the charging time of each pixel PX can be increased three times that of the conventional driving method.

Furthermore, assuming that the display panel 501 is driven by a column inversion driving method, since the pixels PX coupled to the data lines S51-S59 are not adjacent to each other and are separated from each other by one pixel PX, and are in the same group The positions of the pixels PX coupled to the data lines in different columns of pixels will also be different. As shown in FIG. 5B , if the data signals D51 - D53 and D57 - D59 in the current frame period are positive, and the data signals D54 - D56 are negative, then the display panel 501 is deemed to be driven by dot inversion. In addition, it is only necessary to switch the polarities of the data signals D51 to D59 during the next screen period. Therefore, during a frame period, the polarities of the data signals D51 - D59 remain fixed, thereby reducing the power consumption caused by the polarity switching of the data signals, thereby reducing the overall power consumption of the display 500 .

FIG. 5D is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention. Please refer to FIG. 5B and FIG. 5D together. The biggest difference in the structure of the display panel 501 shown in the two figures lies in the disconnection of the data lines S51 , S53 , S54 , S56 , S57 and S59 . In this embodiment, the disconnection of the data line S51 is located between the scan lines G57 and G58; the disconnection of the data line S53 is located between the scan lines G55 and G56; the disconnection of the data line S54 is located between the scan lines G57 and Between G58; the disconnection of the data line S56 is located between the scan lines G55 and G56; the disconnection of the data line S57 is located between the scan lines G57 and G58; and the disconnection of the data line S59 is located between the scan lines G55 and G56 between. In this way, the problem of unbalanced equivalent capacitance caused by the data lines S51 - S59 can be reduced.

FIG. 6A is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention. Please refer to FIG. 5A and FIG. 6A together. The display panel 501 includes a plurality of scan lines G61-G69 and G6a-G6c, a plurality of data lines S61-S69 and S6a-S6c, and a plurality of pixels PX arranged in an array. Wherein, the numbers of scan lines and data lines shown in FIG. 6A are for illustration, not the actual structure of the display panel 501 , and the present invention is not limited thereto. The data lines S61-S69 and S6a-S6c are substantially perpendicular to the scan lines G61-G69 and G6a-G6c.

The scanning line G61 is electrically connected to all the pixels PX in the first row of pixels, and the scanning line G61 is electrically connected to all the pixels PX in the second row of pixels, and so on, and the remaining scanning lines G63-G69 and G6a-G6c are correspondingly All the pixels PX in the 3rd to 12th rows of pixels are electrically connected. Moreover, the scanning lines G61, G62, G67 and G68 receive the same scanning signal, the scanning lines G63, G64, G69 and G6a receive the same scanning signal, and the scanning lines G65, G66, G6b and G6c receive the same scanning signal.

As shown in FIG. 6A , the data lines S61 - S69 and S6 a - S6 c are divided into groups GP61 , GP62 and GP63 . Among them, the group GP61 has the data lines S61-S64, the group GP62 has the data lines S65-S68, and the group GP63 has the data lines S69 and S6a-S6c. In this embodiment, the group GP62 is arranged between the pixels in the first row and its adjacent pixels in the second row.

Looking at the group GP61 first, the data line S61 crosses the scan lines G61 - G66 for receiving the data signal D61. The data line S62 crosses the scan lines G61 - G69 and G6a - G6c for receiving the data signal D62 . The data line S63 crosses the scan lines G61-G69 and G6a-G6c, and is used to receive the data signal D63 and transmit the data signal D63 to the odd pixels in the 7th-12th rows of the 1st column of pixels. The data line S64 crosses the scan lines G61 - G66 for receiving the data signal D64 and transmitting the data signal D64 to the odd pixels in the 1st - 6th row of the 1st column of pixels adjacent to the group GP61 .

Then see the group GP62, the data line S65 spans the scanning lines G61-G66 to receive the data signal D65, and transmit the data signal D65 to the pixels in the 1st-6th row in the first column adjacent to the group GP62 even pixels. The data line S66 crosses the scan lines G61-G69 and G6a-G6c, and is used to receive the data signal D66 and transmit the data signal D66 to the even pixels in the 7th-12th rows of the pixels in the first column. The data line S67 straddles the scan lines G61-G69 and G6a-G6c, and is used to receive the data signal D67 and transmit the data signal D67 to the odd pixels in the 7th-12th rows of the pixels in the second column adjacent to the group GP62. The data line S68 crosses the scan lines G61 - G66 for receiving the data signal D68 and transmitting the data signal D68 to the odd pixels in the first - sixth rows of the second column of pixels.

Looking at the group GP63 again, the data line S69 crosses the scanning lines G61-G66 to receive the data signal D69 and transmit the data signal D69 to the pixels in the 1st-6th row in the second column adjacent to the group GP63. even pixels. The data line S6a crosses the scan lines G61-G69 and G6a-G6c, and is used for receiving the data signal D6a and transmitting the data signal D6a to the even pixels in the 7th-12th rows of the pixels in the second column. The data line S6b crosses the scan lines G61-G69 and G6a-G6c, and is used for receiving the data signal D6b. The data line S6c crosses the scan lines G61 - G66 for receiving the data signal D6c. As shown in FIG. 6A, the pixel configuration structure shown in FIG. 6A can be regarded as a Z-type transistor configuration (Zigzag TFT arrangement), that is, the configuration side of the active element (not shown) of the pixel PX in each column is arranged from top to bottom. The sequence is "left, right, left, right...".

Based on the above, the odd pixels in the first to sixth rows of the first column of pixels can be directly coupled to the data line S64 to receive the data signal D64 without crossing the data lines S61 to S63 . The odd pixels in the 7th to 12th rows in the 1st column of pixels can be directly coupled to the data line S63 to receive the data signal D63 without crossing the data lines S61 , S62 and S64 . Even pixels in rows 1 to 6 in the first column of pixels can be directly coupled to the data line S65 to receive the data signal D65 without crossing the data lines S66 to S68 . The even pixels in the 7th to 12th rows of the 1st column of pixels can be directly coupled to the data line S66 to receive the data signal D66 without crossing the data lines S65 , S67 and S68 . The odd pixels in the 1st to 6th rows in the second column of pixels can be directly coupled to the data line S68 to receive the data signal D68 without crossing the data lines S65 to S67.

On the other hand, the odd pixels in the 7th to 12th rows in the second column of pixels can be directly coupled to the data line S67 to receive the data signal D67 without crossing the data lines S65 , S66 and S68 . The even pixels in the 1st to 6th rows of the pixels in the second column can be directly coupled to the data line S69 to receive the data signal D69 without crossing the data lines S6a-S6c. The even pixels in the 7th to 12th rows in the second column of pixels can be directly coupled to the data line S6a to receive the data signal D6a without crossing the data lines S69, S6b and S6c. In this way, cross-connection of lines can be avoided, and interference caused by cross-connection capacitors can be reduced.

FIG. 6B is a schematic diagram of driving waveforms of a liquid crystal display panel 501 according to another embodiment of the present invention. Please refer to FIG. 6A and FIG. 6B together. According to the above, scanning lines G61, G62, G67 and G68 receive the same scanning signal, scanning lines G63, G64, G69 and G6a receive the same scanning signal, and scanning lines G65, G66, G6b and G6c receive the same scanning signal. same scan signal. Therefore, the pixels PX coupled to the scan lines G61 , G62 , G67 and G68 are turned on at the same time. At this time, the pixels PX in the first row will receive data signals D64 and D68 respectively, the pixels PX in the second row will receive data signals D65 and D69 respectively, and the pixels PX in the seventh row will receive data signals D63 and D67 respectively. , the pixels PX in the eighth row receive the data signals D66 and D6a respectively.

Next, the pixels PX coupled to the scan lines G63 , G64 , G69 and G6a are simultaneously turned on. At this time, the pixels PX in the third row will receive the data signals D64 and D68 respectively, the pixels PX in the fourth row will receive the data signals D65 and D69 respectively, and the pixels PX in the ninth row will respectively receive the data signals D63 and D67 , the pixels PX in the tenth row receive the data signals D66 and D6a respectively. Furthermore, the pixels PX coupled to the scan lines GG65 , G66 , G6b and G6c are turned on at the same time. At this time, the pixels PX in the fifth row will receive the data signals D64 and D68 respectively, the pixels PX in the sixth row will receive the data signals D65 and D69 respectively, and the pixels PX in the eleventh row will respectively receive the data signals D63 and D67 , the pixels PX in the twelfth row receive the data signals D66 and D6a respectively. In this way, four rows of pixels are turned on during the same scanning period, so as to increase the charging time of each pixel PX, thereby suppressing the problem that the pixel PX cannot respond to the correct gray scale due to insufficient charging time.

For example, when the display panel 501 is a FULL HD display panel, the display panel 501 is configured with 1080 scan lines. At this time, the 1st to 540th scanning lines in the display panel 501 are regarded as a scanning area, and the pixels coupled to the 1st to 540th scanning lines turn on two rows of pixels during one scanning period. In addition, the 541st to 1080th scan lines in the display panel 501 are regarded as another scan area, and the pixels coupled to the 541st to 1080th scan lines turn on two rows of pixels during one scan period. Therefore, four rows of pixels are turned on during one scanning period, so that the charging time of each pixel PX can be increased four times that of the conventional driving method.

Furthermore, assuming that the display panel 501 is driven by a column inversion driving method, since the pixels PX coupled to the data lines S61-S69 and S6a-S6c are not adjacent and are separated by one pixel PX, Moreover, the positions of the pixels PX coupled to the data lines of the same group in different columns of pixels will also be different. As shown in FIG. 6A , if the data signals D61 - D64 , D69 and D6a - D6c in the current frame period are positive and the data signals D65 - D68 are negative, then the display panel 501 is deemed to be driven by dot inversion. In addition, it is only necessary to switch the polarities of the data signals D61 to D69 and D6a to D6c in the next frame period. Therefore, during one frame period, the polarities of the data signals D61 - D69 and D6a - D6c are kept constant, thereby reducing the power consumption caused by the polarity switching of the data signals, thereby reducing the overall power consumption of the display 500 .

FIG. 7 is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention. Please refer to FIG. 6A and FIG. 7 together. The biggest difference in the structure of the display panel 501 shown in the two figures lies in the data lines S77-S79 and S7a, and the coupling relationship between the data lines S71-S76, S7b and S7c and the pixel PX can be Corresponding descriptions refer to the data lines S61 - S66 , S6b and S6c , which will not be repeated here. In this embodiment, the data lines S71-S79 and S7a-S7c are divided into groups GP71, GP72 and GP73. Among them, the group GP71 has data lines S71-S74, the group GP72 has data lines S75-S78, and the group GP73 has data lines S79 and S7a-S7c. The group GP72 is arranged between the pixels in the first column and the adjacent pixels in the second column.

In this embodiment, the data line S77 straddles the scan lines G61-G69 and G6a-G6c, and is used to receive the data signal D77 and transmit the data signal D77 to the 7th-12th pixel in the second column adjacent to the group GP72. even pixels in the row. The data line S78 crosses the scan lines G61 - G66 and is used for receiving the data signal D78 and transmitting the data signal D78 to the even pixels in the first - sixth rows of the second column of pixels. The data line S79 crosses the scan lines G61 - G66 for receiving the data signal D79 and transmitting the data signal D79 to the odd pixels in the 1st - 6th row of the 2nd column of pixels adjacent to the group GP73 . The data line S7a crosses the scan lines G61-G69 and G6a-G6c, and is used for receiving the data signal D7a and transmitting the data signal D7a to the odd pixels in the 7th-12th row of the second column of pixels. As shown in Figure 7, the pixel configuration structure shown in Figure 7 can be regarded as a mirror Z-type transistor configuration (Mirror Zigzag TFT arrangement), that is, the configuration side of the transistor (not shown) of the pixel PX in the current column is from top to bottom. The lower order is "left, right, left, right...", and the arrangement sides of the transistors (not shown) of the pixels PX in the next column are symmetrically arranged in the order "right, left, left, left..." from top to bottom.

According to the above, the even pixels in the 1st to 6th rows in the second column of pixels can be directly coupled to the data line S78 to receive the data signal D78 without crossing the data lines S75 to S77. The even pixels in the 7th to 12th rows in the second column of pixels can be directly coupled to the data line S77 to receive the data signal D77 without crossing the data lines S75 , S76 and S78 . The odd pixels in the 1st to 6th rows in the second column of pixels can be directly coupled to the data line S79 to receive the data signal D79 without crossing the data lines S7a-S7c. The odd pixels in the 7th to 12th rows in the second column of pixels can be directly coupled to the data line S7a to receive the data signal D7a without crossing the data lines S79, S7b and S7c. In this way, cross-connection of lines can also be avoided, and interference caused by cross-connection capacitors can be reduced.

Referring to FIG. 7 and FIG. 6B , first, the pixels PX coupled to the scan lines G61 , G62 , G67 and G68 are turned on at the same time. At this time, the pixels PX in the first row will receive data signals D74 and D79 respectively, the pixels PX in the second row will receive data signals D75 and D78 respectively, and the pixels PX in the seventh row will receive data signals D73 and D7a respectively. , the pixels PX in the eighth row receive the data signals D76 and D77 respectively. Then, the pixels PX coupled to the scan lines G63, G64, G69 and G6a are turned on at the same time. At this time, the pixels PX in the third row will receive data signals D74 and D79 respectively, the pixels PX in the fourth row will receive data signals D75 and D78 respectively, and the pixels PX in the ninth row will receive data signals D73 and D7a respectively , the pixels PX in the tenth row receive the data signals D76 and D77 respectively. Furthermore, the pixels PX coupled to the scan lines GG65 , G66 , G6b and G6c are turned on at the same time. At this time, the pixels PX in the 5th row will receive the data signals D74 and D79 respectively, the pixels PX in the 6th row will receive the data signals D75 and D78 respectively, and the pixels PX in the 11th row will receive the data signals D73 and D7a respectively. , the pixels PX in the twelfth row receive the data signals D76 and D77 respectively. In this way, four rows of pixels are turned on during the same scanning period, so as to increase the charging time of each pixel PX, thereby suppressing the problem that the pixel PX cannot respond to the correct gray scale due to insufficient charging time.

In addition, according to the coupling relationship between the pixel PX and the data lines S71-S79 and S7a-S7c, if the data signals D73, D74, D77, D78, D7b and D7c in the current frame period are positive, and the data signals D71, D72, If D75, D76, D79 and D7a are negative polarity, then the display panel 501 can be driven by dot inversion. In addition, it is only necessary to switch the polarities of the data signals D71 to D79 and D7a to D7c in the next frame period. Therefore, during one frame period, the polarities of the data signals D71-D79 and D7a-D7c remain fixed, thereby reducing the power consumption caused by the polarity switching of the data signals, thereby reducing the overall power consumption of the display 500 .

FIG. 8 is a schematic structural diagram of a liquid crystal display panel 501 according to another embodiment of the present invention. Please refer to FIG. 6A and FIG. 8 together. The biggest difference in the structure of the display panel 501 shown in the two figures lies in the data lines S83-S86, and the coupling of the data lines S81, S82, S87-S89 and S8a-S8c to the pixel PX. For the corresponding relationship, refer to the description of the data lines S61 , S62 , S67 - S69 , and S6a - S6c , which will not be repeated here. In this embodiment, the data lines S81-S89 and S8a-S8c are divided into groups GP81, GP82 and GP83. Among them, the group GP81 has data lines S81-S84, the group GP82 has data lines S85-S88, and the group GP83 has data lines S89 and S8a-S8c; and the group GP82 is arranged on the first row of pixels adjacent to it between 2 columns of pixels.

In this embodiment, the data line S83 straddles the scan lines G61-G69 and G6a-G6c to receive the data signal D83 and transmit the data signal D83 to the 7th-12th pixels in the first column adjacent to the group GP81. even pixels in the row. The data line S84 crosses the scan lines G61 - G66 for receiving the data signal D84 and transmitting the data signal D84 to the even pixels in the first - sixth rows of the first column of pixels. The data line S85 crosses the scan lines G61 - G66 for receiving the data signal D85 and transmitting the data signal D85 to the odd pixels in the 1st - 6th row of the pixels in the 1st column adjacent to the group GP82 . The data line S86 crosses the scan lines G61-G69 and G6a-G6c, and is used to receive the data signal D86 and transmit the data signal D86 to the odd pixels in the 7th-12th rows of the 1st column of pixels. As shown in FIG. 8 , the pixel configuration shown in FIG. 8 can be regarded as another mirror Z-type transistor configuration.

According to the above, the even pixels in the first to sixth rows of the first column of pixels can be directly coupled to the data line S84 to receive the data signal D84 without crossing the data lines S81 to S83. The even pixels in the 7th to 12th rows in the 1st column of pixels can be directly coupled to the data line S83 to receive the data signal D83 without crossing the data lines S81 , S82 and S84 . The odd pixels in the 1st to 6th rows of the 1st column of pixels can be directly coupled to the data line S85 to receive the data signal D85 without crossing the data lines S86 to S88. The odd pixels in the 7th to 12th rows of the 1st column of pixels can be directly coupled to the data line S86 to receive the data signal D86 without crossing the data lines S86 , S87 and S88 . In this way, cross-connection of lines can also be avoided, and interference caused by cross-connection capacitors can be reduced.

Referring to FIG. 8 and FIG. 6B , first, the pixels PX coupled to the scan lines G61 , G62 , G67 and G68 are turned on at the same time. At this time, the pixels PX in the first row will receive data signals D85 and D88 respectively, the pixels PX in the second row will receive data signals D84 and D89 respectively, and the pixels PX in the seventh row will receive data signals D86 and D87 respectively. , the pixels PX in the eighth row receive the data signals D83 and D8a respectively. Then, the pixels PX coupled to the scan lines G63, G64, G69 and G6a are turned on at the same time. At this time, the pixels PX in the third row will receive data signals D85 and D88 respectively, the pixels PX in the fourth row will receive data signals D84 and D89 respectively, and the pixels PX in the ninth row will receive data signals D86 and D87 respectively. , the pixels PX in the tenth row receive the data signals D83 and D8a respectively. Furthermore, the pixels PX coupled to the scan lines GG65 , G66 , G6b and G6c are turned on at the same time. At this time, the pixels PX in the 5th row will receive the data signals D85 and D88 respectively, the pixels PX in the 6th row will receive the data signals D84 and D89 respectively, and the pixels PX in the 11th row will receive the data signals D86 and D87 respectively. , the pixels PX in the twelfth row receive the data signals D83 and D8a respectively. Thereby, four rows of pixels are turned on during the same scanning period, so as to increase the charging time of each pixel PX, thereby suppressing the problem that the pixel PX cannot reflect the correct gray scale due to insufficient charging time.

In addition, according to the coupling relationship between the pixel PX and the data lines S81-S89 and S8a-S8c, if the data signals D81, D82, D85, D86, D89 and D8a in the current frame period, and the data signals D83, D84, D87, D88 , D8b and D8c are positive and negative, then the display panel 501 can be driven in a dot inversion mode. In addition, it is only necessary to switch the polarities of the data signals D81 to D89 and D8a to D8c in the next frame period. Therefore, during one frame period, the polarities of the data signals D81 - D89 and D8a - D8c are kept constant, so as to reduce the power consumption caused by the polarity switching of the data signals, thereby reducing the overall power consumption of the display 500 .

To sum up, in the display and its display panel of the embodiment of the present invention, all the pixels in each column of pixels are respectively coupled to multiple data lines, so multiple rows of pixels can be turned on simultaneously in each scanning period, thereby increasing the number of pixels per row. The charging time of one pixel. Moreover, since each data line and the pixel are not cross-connected, the interference caused by the cross-connected capacitance can be reduced. Furthermore, since the pixels coupled to each data line are not adjacent, the data signal received by each data line will remain constant during a frame period, thereby reducing the overall power consumption of the display.

Although the present invention has been disclosed as above with the embodiments, it is not intended to limit the present invention. Anyone with ordinary knowledge in the technical field can make some changes and modifications without departing from the spirit and scope of the present invention. Therefore, the scope of protection of the present invention should be defined by the claims.

Claims (20)

1. a display panel comprises:

The multi-strip scanning line;

Many data lines, arrange with described sweep trace is vertical substantially; And

A plurality of pixels, be electrically connected with corresponding data line and sweep trace respectively, and described pixel arranges with matrix-style,

Wherein, described data line is divided into a plurality of groups, and each group is configured between two adjacent columns pixels and has N bar data line, it is characterized in that,

The segment data line of at least one first three groups of group to the of described group is across part of scanning line, and the remainder data line of described the first three groups of group to the is across all sweep traces, and N is more than or equal to 3 positive integer;

Partial pixel in described two adjacent columns pixels is electrically connected the data line in the segment data line described in the first three groups of group to the, and not across all data line except this data line of the first three groups of group to the, rest of pixels in described two adjacent columns pixels is electrically connected the data line in the remainder data line described in the first three groups of group to the, and not across all data line except this data line of the first three groups of group to the.

2. display panel as claimed in claim 1, is characterized in that, wherein, when N is 3, described the first group comprises one first data line, one second data line and one the 3rd data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group, and

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal to remaining dual pixel of described first row pixel and remaining strange pixel of described secondary series pixel.

3. display panel as claimed in claim 2, it is characterized in that, the described part dual pixel of wherein said first row pixel not across described second with described the 3rd data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel not across described first with described the 3rd data line to receive described the second data-signal, and described remaining strange pixel of described remaining dual pixel of described first row pixel and described secondary series pixel not across described first with described the second data line to receive described the 3rd data-signal.

4. display panel as claimed in claim 1, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining dual pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining strange pixel to described secondary series pixel.

5. display panel as claimed in claim 4, it is characterized in that, the described part dual pixel of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining dual pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining strange pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

6. display panel as claimed in claim 1, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part dual pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining dual pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining dual pixel to described secondary series pixel.

7. display panel as claimed in claim 6, it is characterized in that, the described part dual pixel of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the described part dual pixel of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining dual pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining dual pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

8. display panel as claimed in claim 1, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part strange pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining strange pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining strange pixel to described secondary series pixel.

9. display panel as claimed in claim 8, it is characterized in that, the strange pixel of described part of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining strange pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining strange pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

10. display panel as claimed in claim 1, is characterized in that, wherein i bar sweep trace is electrically connected all pixels in the capable pixel of i, and in order to receive accordingly the one scan signal, i is positive integer.

11. a display comprises:

One display panel comprises:

The multi-strip scanning line;

Many data lines, arrange with described sweep trace is vertical substantially; And

A plurality of pixels, with corresponding data line and sweep trace, be electrically connected respectively, and described pixel is arranged with matrix-style; And

One backlight module, in order to provide described display panel required light source;

Wherein, described data line is divided into a plurality of groups, and each group is configured between two adjacent columns pixels and has N bar data line, it is characterized in that,

The segment data line of at least one first three groups of group to the of described group is across part of scanning line, and the remainder data line of described the first three groups of group to the is across all sweep traces, and N is more than or equal to 3 positive integer;

Partial pixel in described two adjacent columns pixels is electrically connected the data line in the segment data line described in the first three groups of group to the, and not across all data line except this data line of the first three groups of group to the, rest of pixels in described two adjacent columns pixels is electrically connected the data line in the remainder data line described in the first three groups of group to the, and not across all data line except this data line of the first three groups of group to the.

12. display as claimed in claim 11, is characterized in that, wherein, when N is 3, described the first group comprises one first data line, one second data line and one the 3rd data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group, and

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal to remaining dual pixel of described first row pixel and remaining strange pixel of described secondary series pixel.

13. display as claimed in claim 12, it is characterized in that, the described part dual pixel of wherein said first row pixel not across described second with described the 3rd data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel not across described first with described the 3rd data line to receive described the second data-signal, and described remaining strange pixel of described remaining dual pixel of described first row pixel and described secondary series pixel not across described first with described the second data line to receive described the 3rd data-signal.

14. display as claimed in claim 11, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining dual pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining strange pixel to described secondary series pixel.

15. display as claimed in claim 14, it is characterized in that, the described part dual pixel of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining dual pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining strange pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

16. display as claimed in claim 11, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part dual pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part dual pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining dual pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining dual pixel to described secondary series pixel.

17. display as claimed in claim 16, it is characterized in that, the described part dual pixel of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the described part dual pixel of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining dual pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining dual pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

18. display as claimed in claim 11, is characterized in that, wherein, when N is 4, described the first group comprises one first data line, one second data line, one the 3rd data line and one the 4th data line, wherein

Described the first data line, across described part of scanning line, in order to receive one first data-signal, and transmits the part strange pixel of described the first data-signal to a first row pixel of the corresponding two adjacent columns pixels of described the first group,

Described the second data line, across described part of scanning line, in order to receive one second data-signal, and transmits the part strange pixel of described the second data-signal to a secondary series pixel of the corresponding two adjacent columns pixels of described the first group,

Described the 3rd data line, across described whole sweep traces, in order to receive one the 3rd data-signal, and transmits described the 3rd data-signal remaining strange pixel to described first row pixel, and

Described the 4th data line, across described whole sweep traces, in order to receive one the 4th data-signal, and transmits described the 4th data-signal remaining strange pixel to described secondary series pixel.

19. display as claimed in claim 18, it is characterized in that, the strange pixel of described part of wherein said first row pixel is not across described second, the described the 3rd with described the 4th data line to receive described the first data-signal, the strange pixel of described part of described secondary series pixel is not across described first, the described the 3rd with described the 4th data line to receive described the second data-signal, described remaining strange pixel of described first row pixel is not across described first, described second with described the 4th data line to receive described the 3rd data-signal, and described remaining strange pixel of described secondary series pixel is not across described first, described second with described the 3rd data line to receive described the 4th data-signal.

20. display as claimed in claim 11, is characterized in that, wherein i bar sweep trace is electrically connected all pixels in the capable pixel of i, and in order to receive accordingly the one scan signal, i is positive integer.

Images