CN102236223B

CN102236223B - Displayer and display panel thereof

Info

Publication number: CN102236223B
Application number: CN2010101650348A
Authority: CN
Inventors: 黄郁升; 徐雅玲; 侯鸿龙
Original assignee: AU Optronics Corp
Current assignee: AU Optronics Corp
Priority date: 2010-04-20
Filing date: 2010-04-20
Publication date: 2013-12-11
Anticipated expiration: 2030-04-20
Also published as: CN102236223A

Abstract

The invention relates to a displayer and a display panel thereof. The display panel provided by the invention comprises multiple scanning lines, multiple data lines and multiple pixels, wherein the data lines and the scanning lines are generally in perpendicular arrangement; the pixels are respectively in electrical connection with the corresponding data lines and scanning lines; the pixels are ranked in a matrix mode; the data lines are divided into multiple groups, and each group is provided with N data lines between the two adjacent rows of pixels; the N is the positive integer larger than or equal to 3; the partial data lines of at least a first group in the groups stretch across the partial scanning lines; and the residual data lines of the first group stretch across all the scanning lines.

Description

Display and display panel thereof

Technical field

The invention relates to a kind of display and display panel thereof, and particularly relevant for a kind of display and display panel thereof that reduces interference (crosstalk).

Background technology

In recent years, along with semiconductor science and technology is flourish, portable electronic product and flat-panel screens product also rise thereupon.And, in the middle of the type of numerous flat-panel screens, liquid crystal display (Liquid Crystal Display, TFT-LCD), based on the advantage such as its low voltage operating, radiationless line scattering, lightweight and volume be little, has become the main flow of display product immediately.

The schematic diagram of the display panel that Fig. 1 is conventional liquid crystal.As shown in Figure 1, each pixel P of display panel 100 can see through active member (that is thin film transistor (TFT)) TR and be coupled to corresponding sweep trace 110 and data line 120, and only can configure a data line 120 between every two row pixels.In other words, same row pixel can be shared a data line 120.In addition, the picture update rate of liquid crystal display as shown in Figure 1 (frame rate) is generally the 60Hz(hertz), p.s. frame updating 60 times, wherein the frame updating frequency represents that the quality of image of liquid crystal display is better sooner.

In order to show dynamic image quality more clearly, the liquid crystal display that existing employing frame updating frequency is 120Hz and 240Hz on the market at present.But, along with the frame updating frequency improves, the duration of charging of each pixel P just reduces relatively, wherein the duration of charging=sum of (1/ frame updating frequency)/sweep trace.For instance, the resolution of supposing display panel 100 is 1920*1080(Full HD), and be applied under condition that the frame updating frequency is 120Hz, the duration of charging of each pixel P is 1/ (120*1080) ≒ 7us.Now, the duration of charging of each pixel P also in the scope of license, but as improve the frame updating frequency again, the duration of charging of pixel P can be too low and cause the phenomenon of undercharge.

Clearer, suppose that the resolution of display panel 100 is similarly 1920*1080, but be applied under condition that the frame updating frequency is 240Hz, the duration of charging of each pixel P will shorten to 1/ (240*1080) ≒ 3.5us.Because the duration of charging is too short, cause pixel can't be charged to correct voltage quasi position, also, because of like this, each pixel P can't reflect correct GTG (that is image distortion), thereby reduces the quality of image of liquid crystal display.In view of this, a kind of hG2D(half gate by name, two data) type of drive just be developed.

Please refer to Fig. 2, display panel 200 forms for the type of drive construction according to hG2D, and it configures two data lines 210 between two row pixels.As shown in Figure 2, in each row pixel, two neighbouring pixel P are couple to the data line 210 of different bars.Now, can to two row pixels, be charged same sweep time, that is the twice that in display panel 200, the duration of charging of each pixel P is the duration of charging of each pixel P in display panel 100.

For instance, suppose that the resolution of display panel 200 is 1920*1080, and be applied under condition that the frame updating frequency is 240Hz, the duration of charging of each pixel P is 2*1/ (240*1080) ≒ 7us.Thus, can solve the display panel applications of Full HD when frame updating frequency 240Hz, the problem of the duration of charging deficiency of each pixel P, if but improve again the frame updating frequency or improve display panel resolution, the problem of each pixel P duration of charging deficiency can occur once again.

The display panel schematic diagram of the liquid crystal display of Fig. 3 and Fig. 4 are respectively U.S. Patent number No. US6809719B2 and No. 20080068524, wherein US6809719B2 is immediate prior art.According to above-mentioned, when if frame updating frequency or resolution are higher than display panel 200, for example the frame updating frequency is that 360Hz, 480Hz or resolution are 4K2K (being 3840*2160), even the duration of charging of each pixel P increases to twice afterwards or meeting is obviously not enough.Therefore, No. 6809719th, U.S. Patent number and No. 20080068524 mention that respectively display panel 300 and 400 can increase the duration of charging of each pixel P.

With display panel 300, each pixel P comprises liquid crystal capacitance C _land storage capacitors C _s, and three data lines 310 of configuration between every two row pixels.Therefore, in each row pixel, every three adjacent pixel P can be couple to respectively different pieces of information line 310, so that can be charged to three row pixels same sweep time, and then make three times of duration of charging that the duration of charging of each pixel P in display panel 300 is each pixel P in display panel 100.With display panel 400, four data lines 410 of configuration between every two row pixels.Therefore, in each row pixel, every four adjacent pixel P can be couple to respectively different pieces of information line 410, so that can be charged to the four lines pixel same sweep time, and then make four times of duration of charging that the duration of charging of each pixel P in display panel 400 is each pixel P in display panel 100.

Based on above-mentioned, display panel 300 can be considered the type of drive of three data lines (3-data), and display panel 400 can be considered the type of drive of four data lines (4-data).Yet, in above-mentioned display panel 300 and 400, the pixel P of part must stride across other data line 310 or 410 and just can be coupled to corresponding data line 310 or 410, example A place and B place as shown in Figures 3 and 4.Now, the cross-over connection meeting of circuit forms unnecessary flying capcitor (cross-over capacitance), and then produces interference (crosstalk) phenomenon of the local colour cast of picture.In addition, if the type of drive of 3-data or 4-data does not see through the circuit cross-line and couples pixel P and data line 310 or 410, the mode that needs to utilize four limits to drive completes, namely all can configuration control board at the two ends up and down of display panel, so that the cost of display panel can increase.

Summary of the invention

The invention provides a kind of display panel, can improve the duration of charging of pixel.

The invention provides a kind of display, can avoid bridging line to avoid the interference phenomenon of display panel.

The present invention proposes a kind of display panel, and it comprises multi-strip scanning line, many data lines and a plurality of pixel.These data lines arrange with these sweep traces are vertical substantially.These pixels are electrically connected with corresponding data line and sweep trace respectively, and these pixels are arranged with matrix-style.Wherein, these data lines are divided into a plurality of groups, and each group is configured between two adjacent columns pixels and has N bar data line, and N is more than or equal to 3 positive integer.In these groups, the segment data line of at least one the first group is across part of scanning line, and the remainder data line of the first group is across all sweep traces.

A kind of display of the another proposition of the present invention, it comprises display panel and backlight module.Backlight module is in order to provide display panel required light source.Display panel comprises multi-strip scanning line, many data lines and a plurality of pixel.These data lines arrange with these sweep traces are vertical substantially.These pixels are electrically connected with corresponding data line and sweep trace respectively, and these pixels are arranged with matrix-style.Wherein, these data lines are divided into a plurality of groups, and each group is configured between two adjacent columns pixels and has N bar data line, and N is more than or equal to 3 positive integer.In these groups, the segment data line of at least one the first group is across part of scanning line, and the remainder data line of the first group is across all sweep traces.

In one embodiment of this invention, when N is 3, the first group comprises the first data line, the second data line and the 3rd data line.The first data line is across described part of scanning line, in order to receive the first data-signal, and transmits the part dual pixel of the first row pixel of the corresponding two adjacent columns pixels of the first data-signal to the first group.The second data line is across described part of scanning line, in order to receive the second data-signal, and transmits the strange pixel of part of the secondary series pixel of the corresponding two adjacent columns pixels of the second data-signal to the first group.The 3rd data line, across described whole sweep traces, in order to receive the 3rd data-signal, and transmits the 3rd data-signal to remaining dual pixel of first row pixel and remaining strange pixel of secondary series pixel.

In one embodiment of this invention, the described part dual pixel of above-mentioned first row pixel not across the second and the 3rd data line to receive the first data-signal, the strange pixel of described part of above-mentioned secondary series pixel not across the first and the 3rd data line to receive the second data-signal, described remaining strange pixel of described remaining dual pixel of above-mentioned first row pixel and secondary series pixel not across first and second data line to receive the first data-signal.

In one embodiment of this invention, when N is 4, the first group comprises the first data line, the second data line, the 3rd data line and the 4th data line.The first data line is across described part of scanning line, in order to receive the first data-signal, and transmits the part dual pixel of the first row pixel of the corresponding two adjacent columns pixels of the first data-signal to the first group.The second data line is across described part of scanning line, in order to receive the second data-signal, and transmits the strange pixel of part of the secondary series pixel of the corresponding two adjacent columns pixels of the second data-signal to the first group.The 3rd data line, across described whole sweep traces, in order to receive the 3rd data-signal, and transmits the 3rd data-signal remaining dual pixel to the first row pixel.The 4th data line, across described whole sweep traces, in order to receive the 4th data-signal, and transmits the 4th data-signal remaining strange pixel to the secondary series pixel.

In one embodiment of this invention, the described part dual pixel of above-mentioned first row pixel not across second, third and the 4th data line to receive the first data-signal, the strange pixel of described part of above-mentioned secondary series pixel not across the first, the 3rd and the 4th data line to receive the second data-signal, described remaining dual pixel of above-mentioned first row pixel not across first, second and the 4th data line to receive the 3rd data-signal, described remaining strange pixel of above-mentioned secondary series pixel not across first, second and the 3rd data line to receive the 4th data-signal.

In one embodiment of this invention, when N is 4, the first group comprises the first data line, the second data line, the 3rd data line and the 4th data line.The first data line is across described part of scanning line, in order to receive the first data-signal, and transmits the part dual pixel of the first row pixel of the corresponding two adjacent columns pixels of the first data-signal to the first group.The second data line is across described part of scanning line, in order to receive the second data-signal, and transmits the part dual pixel of the secondary series pixel of the corresponding two adjacent columns pixels of the second data-signal to the first group.The 3rd data line, across described whole sweep traces, in order to receive the 3rd data-signal, and transmits the 3rd data-signal remaining dual pixel to the first row pixel.The 4th data line, across described whole sweep traces, in order to receive the 4th data-signal, and transmits the 4th data-signal remaining dual pixel to the secondary series pixel.

In one embodiment of this invention, the described part dual pixel of above-mentioned first row pixel not across second, third and the 4th data line to receive the first data-signal, the described part dual pixel of above-mentioned secondary series pixel not across the first, the 3rd and the 4th data line to receive the second data-signal, described remaining dual pixel of above-mentioned first row pixel not across first, second and the 4th data line to receive the 3rd data-signal, described remaining dual pixel of above-mentioned secondary series pixel not across first, second and the 3rd data line to receive the 4th data-signal.

In one embodiment of this invention, when N is 4, the first group comprises the first data line, the second data line, the 3rd data line and the 4th data line.The first data line is across described part of scanning line, in order to receive the first data-signal, and transmits the strange pixel of part of the first row pixel of the corresponding two adjacent columns pixels of the first data-signal to the first group.The second data line is across described part of scanning line, in order to receive the second data-signal, and transmits the strange pixel of part of the secondary series pixel of the corresponding two adjacent columns pixels of the second data-signal to the first group.The 3rd data line, across described whole sweep traces, in order to receive the 3rd data-signal, and transmits the 3rd data-signal remaining strange pixel to the first row pixel.The 4th data line, across described whole sweep traces, in order to receive the 4th data-signal, and transmits the 4th data-signal remaining strange pixel to the secondary series pixel.

In one embodiment of this invention, the strange pixel of described part of above-mentioned first row pixel not across second, third and the 4th data line to receive the first data-signal, the strange pixel of described part of above-mentioned secondary series pixel not across the first, the 3rd and the 4th data line to receive the second data-signal, described remaining strange pixel of above-mentioned first row pixel not across first, second and the 4th data line to receive the 3rd data-signal, described remaining strange pixel of above-mentioned secondary series pixel not across first, second and the 3rd data line to receive the 4th data-signal.

In one embodiment of this invention, i bar sweep trace is electrically connected all pixels in the capable pixel of i, and in order to receive accordingly sweep signal, i is positive integer.

Based on above-mentioned, display of the present invention and display panel thereof, by a plurality of groups respectively of many data lines on display panel, and the data line of each group can be adjacent and not across pixel.In each group, segment data line is across the part sweep trace, and the remainder data line is across all sweep traces.Therefore, in each row pixel, all pixels can couple respectively the part data line in two groups, and pixel and data line can directly couple.By this, avoid bridging line and form flying capcitor, and then avoiding causing because of flying capcitor the interference phenomenon of local colour cast.

For above-mentioned feature and advantage of the present invention can be become apparent, special embodiment below, and coordinate appended graphic being described in detail below.

The accompanying drawing explanation

Fig. 1 and Fig. 2 are respectively the display panel schematic diagram of a conventional liquid crystal.

The display panel schematic diagram of the liquid crystal display of Fig. 3 and Fig. 4 are respectively U.S. Patent number No. 6809719 and No. 20080068524.

Fig. 5 A illustrates the system block diagrams into the display 500 of one embodiment of the invention.

Fig. 5 B illustrates the structural representation into the display panels 501 of one embodiment of the invention.

Fig. 5 C illustrates the drive waveforms schematic diagram into the display panels 501 of one embodiment of the invention.

Fig. 5 D illustrates the structural representation into the display panels 501 of another embodiment of the present invention.

Fig. 6 A illustrates the structural representation into the display panels 501 of further embodiment of this invention.

Fig. 6 B illustrates the drive waveforms schematic diagram into the display panels 501 of further embodiment of this invention.

Fig. 7 illustrates the structural representation into the display panels 501 of yet another embodiment of the invention.

Fig. 8 illustrates the structural representation into the display panels 501 of the multiple embodiment of the present invention.

Drawing reference numeral:

100,200,300,501: display panel

110, G51～G59, G61～G69, G6a～G6c: sweep trace

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

500: display

503: gate drivers

505: source electrode driver

507: time schedule controller

509: backlight module

C _l: liquid crystal capacitance

C _s: storage capacitors

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 member

Embodiment

With detailed reference to embodiments of the invention, the example of described embodiment is described in the accompanying drawings.In addition, all may part, use the identical or similar portions of the element/member of same numeral/symbology in graphic and embodiment.

Fig. 5 A illustrates the system block diagrams into the display 500 of one embodiment of the invention.Please refer to Fig. 5 A, display 500 comprises display panel (display panel) 501, gate drivers (gate driver) 503, source electrode driver (source driver) 505, time schedule controller (timing controller, T-con) 507, and backlight module (backlight module) 509.Wherein, display 500 can be for Thin Film Transistor-LCD (TFT LCD), so display panel 501 can correspond to film transistor display panel.

In addition, backlight module 509 is in order to provide display panel 501 required light source; The running with source electrode driver 505 in order to control gate driver 503 of time schedule controller 507, use causing gate drivers 503 and source electrode driver 505 to produce respectively sweep signal (scan signal) to drive display panel 501 with data-signal (data signal).

Clearer, Fig. 5 B illustrates the structural representation into the display panels 501 of one embodiment of the invention.Please merge with reference to Fig. 5 A and Fig. 5 B, display panel 501 can comprise multi-strip scanning line G51～G59, many data line S51～S59, and a plurality of pixel PX arranged with array way.Wherein, the number of the sweep trace shown in Fig. 5 B and data line is in order to explanation, the practical structures of this non-display panel 501, and the present invention is not as limit.

Data line S51～S59 arranges with sweep trace G51～G59 is vertical substantially.Sweep trace G51 is electrically connected all pixel PX in the 1st row pixel, and sweep trace G52 is electrically connected all pixel PX in the 2nd row pixel, and by that analogy, all the other sweep trace G53～G59 are electrically connected all pixel PX in 3rd～9 row pixels accordingly.In addition, sweep trace G51, G52 and G57 receive same sweep signal, and sweep trace G53, G54 and G58 receive same sweep signal, and sweep trace G55, G56 and G59 receive same sweep signal, after appearance, describe in detail again.

As shown in Figure 5 B, data line S51～S59 can be divided into the GP51 of group, GP52 and GP53.Wherein, the GP51 of group has data line S51～S53, and the GP52 of group has data line S54～S56, and the GP53 of group has data line S57～S59.In the present embodiment, the GP52 of group is disposed between the 2nd row pixel that the 1st row pixel is adjacent.First see the GP51 of group, data line S51 is across sweep trace G51～G56, in order to receive data-signal D51.Data line S52 is across sweep trace G51～G59, and in order to receive data-signal D52, and data signal D52 is to the strange pixel in 7th～9 row in the 1st row pixel adjacent with the GP51 of group.Data line S53 is across sweep trace G51～G56, in order to receive data-signal D53, and the strange pixel in 1st～6 row in data signal D53 to the 1 row pixel.

Then see the GP52 of group, data line S54 is across sweep trace G51～G56, and in order to receive data-signal D54, and data signal D54 is to the dual pixel in 1st～6 row in the 1st row pixel adjacent with the GP52 of group.Data line S55 is across sweep trace G51～G59, and in order to receive data-signal D55, and data signal D55 is to the strange pixel in 7th～9 row in the dual pixel in 7th～9 row in the 1st row pixel adjacent with the GP52 of group and the 2nd row pixel.Data line S56 is across sweep trace G51～G56, in order to receive data-signal D56, and the strange pixel in 1st～6 row in data signal D56 to the 2 row pixels.

See the GP53 of group, data line S57 is across sweep trace G51～G56 again, and in order to receive data-signal D57, and data signal D57 is to the dual pixel in 1st～6 row in the 2nd row pixel adjacent with the GP53 of group.Data line S58 is across sweep trace G51～G59, in order to receive data-signal D58, and the dual pixel in 7th～9 row in data signal D58 to the 2 row pixels.Data line S59 is across sweep trace G51～G56, in order to receive data-signal D59.

Based on above-mentioned, the strange pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S53 to receive data-signal D53 and can be across data line S51 and S52.Strange pixel in the 1st row pixel in 7th～9 row can directly be coupled to data line S52 to receive data-signal D52 and can be across data line S51 and S53.Dual pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S54 to receive data-signal D54 and can be across data line S55 and S56.Strange pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S56 to receive data-signal D56 and can be across data line S54 and S55.

On the other hand, in the 1st row pixel in the dual pixel in 7th～9 row and the 2nd row pixel the strange pixel in 7th～9 row can directly be coupled to data line S55 to receive data-signal D55 and can be across data line S54 and S56.Dual pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S57 to receive data-signal D57 and can be across data line S58 and S59.Dual pixel in the 2nd row pixel in 7th～9 row can directly be coupled to data line S58 to receive data-signal D58 and can be across data line S57 and S59.By this, can avoid bridging line, reduce the interference (crosstalk) that flying capcitor causes.

Fig. 5 C illustrates the drive waveforms schematic diagram into the display panels 501 of one embodiment of the invention.Please merge with reference to Fig. 5 B and Fig. 5 C, according to above-mentioned, sweep trace G51, G52 and G57 receive same sweep signal, and sweep trace G53, G54 and G58 receive same sweep signal, and sweep trace G55, G56 and G59 receive same sweep signal.Therefore, the pixel PX coupled with sweep trace G51, G52 and G57 can be unlocked simultaneously.Now, the pixel PX of the 1st row can receive respectively data-signal D53 and D56, and the pixel PX of the 2nd row can receive respectively data-signal D54 and D57, and the pixel PX of the 7th row can receive respectively data-signal D52 and D55.

And then, the pixel PX coupled with sweep trace G53, G54 and G58 can be unlocked simultaneously.Now, the pixel PX of the 3rd row can receive respectively data-signal D53 and D56, and the pixel PX of the 4th row can receive respectively data-signal D54 and D57, and the pixel PX of eighth row can receive respectively data-signal D55 and D58.Afterwards, the pixel PX coupled with sweep trace G55, G56 and G59 can be unlocked simultaneously.Now, the pixel PX of the 5th row can receive respectively data-signal D53 and D56, and the pixel PX of the 6th row can receive respectively data-signal D54 and D57, and the pixel PX of the 9th row can receive respectively data-signal D52 and D55.By this, have three row pixels in same scan period and be unlocked, with this, increase the duration of charging of each pixel PX, so suppress because of the duration of charging not enough cause pixel PX can not react the problem of correct GTG.

For instance, when display panel that display panel 501 is FULL HD, display panel 501 can dispose 1080 sweep traces.Now, in display panel 501,1st～720 sweep traces can be considered as the one scan zone, and can open two row pixels a scan period with the pixel that 1st～720 sweep traces couple.In addition, in display panel 501,721st～1080 sweep traces can be considered as another scanning area, and can open one-row pixels a scan period with the pixel that 721st～1080 sweep traces couple.Therefore, a scan period, can open three row pixels, so that the duration of charging of each pixel PX can increase to three times of the conventional ADS driving method.

Moreover, suppose to utilize the type of drive that is listed as reversion (column inversion) to drive the words of display panel 501, neither adjacent and one of the space pixel PX of pixel PX coupled due to data line S51～S59, and the pixel PX position that the data line of same group couples in the different lines pixel also can be different.Shown in Fig. 5 B, if data-signal D51～D53 and D57～D59 during picture instantly are positive polarity, and data-signal D54～D56 is negative polarity, and display panel 501 is treated as with a reversion and driven.And the polarity of switch data signal D51～D59 gets final product during next picture.Therefore, during a picture, it is fixing that the polarity of data-signal D51～D59 can maintain, and with this, can reduce the power consumption that data-signal is caused in the polarity switching, thereby reduce the power consumption of display 500 integral body.

Fig. 5 D illustrates the structural representation into the display panels 501 of another embodiment of the present invention.Please merge with reference to Fig. 5 B and Fig. 5 D, the maximum difference of the structure of the display panel 501 shown in two figure is the gap of data line S51, S53, S54, S56, S57 and S59.In the present embodiment, the gap of data line S51 is between sweep trace G57 and G58; The gap of data line S53 is between sweep trace G55 and G56; The gap of data line S54 is between sweep trace G57 and G58; The gap of data line S56 is between sweep trace G55 and G56; The gap of data line S57 is between sweep trace G57 and G58; And the gap of data line S59 is between sweep trace G55 and G56.By this, can reduce the unbalanced problem of equivalent capacity that data line S51～S59 causes.

Fig. 6 A illustrates the structural representation into the display panels 501 of further embodiment of this invention.Please merge with reference to Fig. 5 A and Fig. 6 A, display panel 501 comprises multi-strip scanning line G61～G69 and G6a～G6c, many data line S61～S69 and S6a～S6c, and a plurality of pixel PX arranged with array way.Wherein, the sweep trace that Fig. 6 A illustrates and the number of data line are in order to explanation, the practical structures of this non-display panel 501, and the present invention is not as limit.Data line S61～S69 and S6a～S6c are substantially with sweep trace G61～G69 and G6a～G6c is vertical arranges.

Sweep trace G61 is electrically connected all pixel PX in the 1st row pixel, sweep trace G61 is electrically connected all pixel PX in the 2nd row pixel, by that analogy, all the other sweep trace G63～G69 and G6a～G6c are electrically connected all pixel PX in 3rd～12 row pixels accordingly.And sweep trace G61, G62, G67 and G68 receive same sweep signal, sweep trace G63, G64, G69 and G6a receive same sweep signal, and sweep trace G65, G66, G6b and G6c receive same sweep signal.

As shown in Figure 6A, data line S61～S69 and S6a～S6c are divided into the GP61 of group, GP62 and GP63.Wherein, the GP61 of group has data line S61～S64, and the GP62 of group has data line S65～S68, and the GP63 of group has data line S69 and S6a～S6c.In the present embodiment, the GP62 of group is disposed between the 2nd row pixel that the 1st row pixel is adjacent.

First see the GP61 of group, data line S61 is across sweep trace G61～G66, in order to receive data-signal D61.Data line S62 is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D62.Data line S63 is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D63, and the strange pixel in 7th～12 row in data signal D63 to the 1 row pixel.Data line S64 is across sweep trace G61～G66, and in order to receive data-signal D64, and data signal D64 is to the strange pixel in 1st～6 row in the 1st row pixel adjacent with the GP61 of group.

Then see the GP62 of group, data line S65 is across sweep trace G61～G66, and in order to receive data-signal D65, and data signal D65 is to the dual pixel in 1st～6 row in the 1st row pixel adjacent with the GP62 of group.Data line S66 is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D66, and the dual pixel in 7th～12 row in data signal D66 to the 1 row pixel.Data line S67 is across sweep trace G61～G69 and G6a～G6c, and in order to receive data-signal D67, and data signal D67 is to the strange pixel in 7th～12 row in the 2nd row pixel adjacent with the GP62 of group.Data line S68 is across sweep trace G61～G66, in order to receive data-signal D68, and the strange pixel in 1st～6 row in data signal D68 to the 2 row pixels.

See the GP63 of group, data line S69 is across sweep trace G61～G66 again, and in order to receive data-signal D69, and data signal D69 is to the dual pixel in 1st～6 row in the 2nd row pixel adjacent with the GP63 of group.Data line S6a is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D6a, and the dual pixel in 7th～12 row in data signal D6a to the 2 row pixels.Data line S6b is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D6b.Data line S6c is across sweep trace G61～G66, in order to receive data-signal D6c.As shown in Figure 6A, the pixel arrangement structure shown in Fig. 6 A can be considered Z-type transistor arrangement (Zigzag TFT arrangement), that is the configuration side of the active member of the pixel PX of each row (not illustrating) from top to bottom is sequentially " left and right, left and right ... "

Based on above-mentioned, the strange pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S64 to receive data-signal D64 and can be across data line S61～S63.Strange pixel in the 1st row pixel in 7th～12 row can directly be coupled to data line S63 to receive data-signal D63 and can be across data line S61, S62 and S64.Dual pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S65 to receive data-signal D65 and can be across data line S66～S68.Dual pixel in the 1st row pixel in 7th～12 row can directly be coupled to data line S66 to receive data-signal D66 and can be across data line S65, S67 and S68.Strange pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S68 to receive data-signal D68 and can be across data line S65～S67.

On the other hand, in the 2nd row pixel, the strange pixel in 7th～12 row can directly be coupled to data line S67 to receive data-signal D67 and can be across data line S65, S66 and S68.Dual pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S69 to receive data-signal D69 and can be across data line S6a～S6c.Dual pixel in the 2nd row pixel in 7th～12 row can directly be coupled to data line S6a to receive data-signal D6a and can be across data line S69, S6b and S6c.By this, can avoid bridging line, reduce the interference that flying capcitor causes.

Fig. 6 B illustrates the drive waveforms schematic diagram into the display panels 501 of further embodiment of this invention.Please merge with reference to Fig. 6 A and Fig. 6 B, according to above-mentioned, sweep trace G61, G62, G67 and G68 receive same sweep signal, and sweep trace G63, G64, G69 and G6a receive same sweep signal, and sweep trace G65, G66, G6b and G6c receive same sweep signal.Therefore, the pixel PX coupled with sweep trace G61, G62, G67 and G68 can be unlocked simultaneously.Now, the pixel PX of the 1st row can receive respectively data-signal D64 and D68, the pixel PX of the 2nd row can receive respectively data-signal D65 and D69, and the pixel PX of the 7th row can receive respectively data-signal D63 and D67, and the pixel PX of eighth row can receive respectively data-signal D66 and D6a.

And then, the pixel PX coupled with sweep trace G63, G64, G69 and G6a can be unlocked simultaneously.Now, the pixel PX of the 3rd row can receive respectively data-signal D64 and D68, the pixel PX of the 4th row can receive respectively data-signal D65 and D69, and the pixel PX of the 9th row can receive respectively data-signal D63 and D67, and the pixel PX of the 10th row can receive respectively data-signal D66 and D6a.Moreover the pixel PX coupled with sweep trace GG65, G66, G6b and G6c can be unlocked simultaneously.Now, the pixel PX of the 5th row can receive respectively data-signal D64 and D68, the pixel PX of the 6th row can receive respectively data-signal D65 and D69, and the pixel PX of the 11st row can receive respectively data-signal D63 and D67, and the pixel PX of the 12nd row can receive respectively data-signal D66 and D6a.By this, have the four lines pixel in same scan period and be unlocked, with this, increase the duration of charging of each pixel PX, so suppress because of the duration of charging not enough cause pixel PX can not react the problem of correct GTG.

For instance, when display panel that display panel 501 is FULL HD, display panel 501 can dispose 1080 sweep traces.Now, in display panel 501,1st～540 sweep traces can be considered as the one scan zone, and can open two row pixels a scan period with the pixel that 1st～540 sweep traces couple.In addition, in display panel 501,541st～1080 sweep traces can be considered as another scanning area, and can open two row pixels a scan period with the pixel that 541st～1080 sweep traces couple.Therefore, a scan period, can open the four lines pixel, so that the duration of charging of each pixel PX can increase to four times of the conventional ADS driving method.

Moreover, suppose to utilize the type of drive that is listed as reversion (column inversion) to drive the words of display panel 501, neither adjacent and one of the space pixel PX of pixel PX coupled due to data line S61～S69 and S6a～S6c, and the pixel PX position that the data line of same group couples in the different lines pixel also can be different.Shown in Fig. 6 A, if data-signal D61～D64, D69 and D6a～D6c during picture instantly are that positive polarity and data-signal D65～D68 are negative polarity, display panel 501 is treated as with a reversion and is driven.And the polarity of switch data signal D61～D69 and D6a～D6c gets final product during next picture.Therefore, during a picture, it is fixing that the polarity of data-signal D61～D69 and D6a～D6c can maintain, and with this, can reduce the power consumption that data-signal is caused in the polarity switching, thereby reduce the power consumption of display 500 integral body.

Fig. 7 illustrates the structural representation into the display panels 501 of yet another embodiment of the invention.Please merge with reference to Fig. 6 A and Fig. 7, the maximum difference of the structure of the display panel 501 shown in two figure is data line S77～S79 and S7a, and data line S71～S76, S7b and S7c and the relation that couples of pixel PX can be corresponding comparable data line S61～S66, S6b and the explanation of S6c, at this, repeat no more.In the present embodiment, data line S71～S79 and S7a～S7c are divided into the GP71 of group, GP72 and GP73.Wherein, the GP71 of group has data line S71～S74, and the GP72 of group has data line S75～S78, and the GP73 of group has data line S79 and S7a～S7c.And the GP72 of group is disposed between the 2nd row pixel that the 1st row pixel is adjacent.

In the present embodiment, data line S77 is across sweep trace G61～G69 and G6a～G6c, and in order to receive data-signal D77, and data signal D77 is to the dual pixel in 7th～12 row in the 2nd row pixel adjacent with the GP72 of group.Data line S78 is across sweep trace G61～G66, in order to receive data-signal D78, and the dual pixel in 1st～6 row in data signal D78 to the 2 row pixels.Data line S79 is across sweep trace G61～G66, and in order to receive data-signal D79, and data signal D79 is to the strange pixel in 1st～6 row in the 2nd row pixel adjacent with the GP73 of group.Data line S7a is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D7a, and the strange pixel in 7th～12 row in data signal D7a to the 2 row pixels.As shown in Figure 7, pixel arrangement structure shown in Fig. 7 can be considered mirror Z-type transistor arrangement (Mirror Zigzag TFT arrangement), that is the configuration side of working as the transistor (not illustrating) of the pixel PX be listed as from top to bottom is sequentially " left and right, left and right ... ", the configuration side of transistor (not illustrating) every the pixel PX of row can from top to bottom be sequentially symmetrically " and a left side, right left and right ... "

According to above-mentioned, the dual pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S78 to receive data-signal D78 and can be across data line S75～S77.Dual pixel in the 2nd row pixel in 7th～12 row can directly be coupled to data line S77 to receive data-signal D77 and can be across data line S75, S76 and S78.Strange pixel in the 2nd row pixel in 1st～6 row can directly be coupled to data line S79 to receive data-signal D79 and can be across data line S7a～S7c.Strange pixel in the 2nd row pixel in 7th～12 row can directly be coupled to data line S7a to receive data-signal D7a and can be across data line S79, S7b and S7c.By this, can avoid bridging line equally, reduce the interference that flying capcitor causes.

Please refer to Fig. 7 and Fig. 6 B in this, at first, the pixel PX coupled with sweep trace G61, G62, G67 and G68 can be unlocked simultaneously.Now, the pixel PX of the 1st row can receive respectively data-signal D74 and D79, the pixel PX of the 2nd row can receive respectively data-signal D75 and D78, and the pixel PX of the 7th row can receive respectively data-signal D73 and D7a, and the pixel PX of eighth row can receive respectively data-signal D76 and D77.Then, the pixel PX coupled with sweep trace G63, G64, G69 and G6a can be unlocked simultaneously.Now, the pixel PX of the 3rd row can receive respectively data-signal D74 and D79, the pixel PX of the 4th row can receive respectively data-signal D75 and D78, and the pixel PX of the 9th row can receive respectively data-signal D73 and D7a, and the pixel PX of the 10th row can receive respectively data-signal D76 and D77.Moreover the pixel PX coupled with sweep trace GG65, G66, G6b and G6c can be unlocked simultaneously.Now, the pixel PX of the 5th row can receive respectively data-signal D74 and D79, the pixel PX of the 6th row can receive respectively data-signal D75 and D78, and the pixel PX of the 11st row can receive respectively data-signal D73 and D7a, and the pixel PX of the 12nd row can receive respectively data-signal D76 and D77.By this, have the four lines pixel in same scan period and be unlocked, with this, increase the duration of charging of each pixel PX, so suppress because of the duration of charging not enough cause pixel PX can not react the problem of correct GTG.

In addition, the relation that couples according to pixel PX and data line S71～S79 and S7a～S7c, if data-signal D73, D74, D77, D78, D7b and D7c during picture instantly are positive polarity, and data-signal D71, D72, D75, D76, D79 and D7a are negative polarity, display panel 501 can be treated as with a reversion and drive.And the polarity of switch data signal D71～D79 and D7a～D7c gets final product during next picture.Therefore, during a picture, it is fixing that the polarity of data-signal D71～D79 and D7a～D7c can maintain, and with this, can reduce the power consumption that data-signal is caused in the polarity switching, thereby reduce the power consumption of display 500 integral body.

Fig. 8 illustrates the structural representation into the display panels 501 of the multiple embodiment of the present invention.Please merge with reference to Fig. 6 A and Fig. 8, the maximum difference of the structure of the display panel 501 shown in two figure is data line S83～S86, and data line S81, S82, S87～S89 and S8a～S8c and the relation that couples of pixel PX can be corresponding the explanation of comparable data line S61, S62, S67～S69 and S6a～S6c, at this, repeat no more.In the present embodiment, data line S81～S89 and S8a～S8c are divided into the GP81 of group, GP82 and GP83.Wherein, the GP81 of group has data line S81～S84, and the GP82 of group has data line S85～S88, and the GP83 of group has data line S89 and S8a～S8c; And the GP82 of group is disposed between the 2nd row pixel that the 1st row pixel is adjacent.

In the present embodiment, data line S83 is across sweep trace G61～G69 and G6a～G6c, and in order to receive data-signal D83, and data signal D83 is to the dual pixel in 7th～12 row in the 1st row pixel adjacent with the GP81 of group.Data line S84 is across sweep trace G61～G66, in order to receive data-signal D84, and the dual pixel in 1st～6 row in data signal D84 to the 1 row pixel.Data line S85 is across sweep trace G61～G66, and in order to receive data-signal D85, and data signal D85 is to the strange pixel in 1st～6 row in the 1st row pixel adjacent with the GP82 of group.Data line S86 is across sweep trace G61～G69 and G6a～G6c, in order to receive data-signal D86, and the strange pixel in 7th～12 row in data signal D86 to the 1 row pixel.As shown in Figure 8, the pixel arrangement structure shown in Fig. 8 can be considered another kind of mirror Z-type transistor arrangement.

According to above-mentioned, the dual pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S84 to receive data-signal D84 and can be across data line S81～S83.Dual pixel in the 1st row pixel in 7th～12 row can directly be coupled to data line S83 to receive data-signal D83 and can be across data line S81, S82 and S84.Strange pixel in the 1st row pixel in 1st～6 row can directly be coupled to data line S85 to receive data-signal D85 and can be across data line S86～S88.Strange pixel in the 1st row pixel in 7th～12 row can directly be coupled to data line S86 to receive data-signal D86 and can be across data line S86, S87 and S88.By this, can avoid bridging line equally, reduce the interference that flying capcitor causes.

Please refer to Fig. 8 and Fig. 6 B, at first, the pixel PX coupled with sweep trace G61, G62, G67 and G68 can be unlocked simultaneously.Now, the pixel PX of the 1st row can receive respectively data-signal D85 and D88, the pixel PX of the 2nd row can receive respectively data-signal D84 and D89, and the pixel PX of the 7th row can receive respectively data-signal D86 and D87, and the pixel PX of eighth row can receive respectively data-signal D83 and D8a.Then, the pixel PX coupled with sweep trace G63, G64, G69 and G6a can be unlocked simultaneously.Now, the pixel PX of the 3rd row can receive respectively data-signal D85 and D88, the pixel PX of the 4th row can receive respectively data-signal D84 and D89, and the pixel PX of the 9th row can receive respectively data-signal D86 and D87, and the pixel PX of the 10th row can receive respectively data-signal D83 and D8a.Moreover the pixel PX coupled with sweep trace GG65, G66, G6b and G6c can be unlocked simultaneously.Now, the pixel PX of the 5th row can receive respectively data-signal D85 and D88, the pixel PX of the 6th row can receive respectively data-signal D84 and D89, and the pixel PX of the 11st row can receive respectively data-signal D86 and D87, and the pixel PX of the 12nd row can receive respectively data-signal D83 and D8a.By this, have the four lines pixel in same scan period and be unlocked, with this, increase the duration of charging of each pixel PX, so suppress because of the duration of charging not enough cause pixel PX can't reflect the problem of correct GTG.

In addition, the relation that couples according to pixel PX and data line S81～S89 and S8a～S8c, if data-signal D81, D82, D85, D86, D89 and D8a during picture instantly, and data-signal D83, D84, D87, D88, D8b and D8c are that positive polarity is negative polarity, display panel 501 can be put inversion mode and drives.And the polarity of switch data signal D81～D89 and D8a～D8c gets final product during next picture.Therefore, during a picture, it is fixing that the polarity of data-signal D81～D89 and D8a～D8c can maintain, and with this, can reduce the power consumption that data-signal is caused in the polarity switching, thereby reduce the power consumption of display 500 integral body.

In sum, the display of the embodiment of the present invention and display panel thereof, all pixels in its each row pixel couple respectively many data lines, therefore in each scan period, can open the multirow pixel simultaneously, increase by this duration of charging of each pixel.And, due to each data line and pixel neither for cross-over connection, therefore can reduce the interference that flying capcitor causes.Moreover the pixel coupled due to each data line is not adjacent, so data-signal meeting maintenance during a picture that each data line receives is fixing, therefore can reduce the power consumption of display integral body.

Although the present invention discloses as above with embodiment; so it is not in order to limit the present invention; have and usually know the knowledgeable in technical field under any; without departing from the spirit and scope of the present invention; when doing a little change and retouching, therefore protection scope of the present invention is as the criterion when looking the claim scope person of defining.

Claims

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 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 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 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 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

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;

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;

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

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

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

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

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.