CN201222151Y - Liquid crystal display device and pixel structure thereof - Google Patents

Abstract

The utility model discloses a liquid crystal display device and a pixel structure thereof, wherein the pixel structure adopted by the liquid crystal display device comprises a first scanning line, a second scanning line, a data wire, a first thin film transistor, a first pixel electrode, a second thin film transistor, a second pixel electrode, a third thin film transistor, a charge shared capacitor and a fourth thin film transistor. The first scanning line and the data wire can apply first gray scale set voltage on the first pixel electrode and the second pixel electrode through the first thin film transistor and the second thin film transistor, the second scanning line and the data wire can apply the second gray scale set voltage on the charge shared capacitor through the third thin film transistor, and the fourth thin film transistor can conduct the second pixel electrode and the charge shared capacitor for redistributing voltage. The second scanning lines of all pixel structures can be connected to drive commonly as the second scanning line is applicable to all pixel structures in the liquid crystal display device, thereby saving driving IC.

Description

Liquid crystal indicator and dot structure thereof

Technical field

The utility model relates to a kind of liquid crystal indicator, more specifically, relates to the liquid crystal indicator and the dot structure thereof of a kind of vertical orientation (Vertical alignment) pattern, the visual angle that can improve liquid crystal indicator.

Background technology

LCD is one of the most widely used type in the current panel display apparatus.LCD generally includes two substrates: array base palte and colored optical filtering substrates, and the liquid crystal layer between two substrates, these two substrates have pixel electrode and the public electrode that is used to produce electric field.LCD is by putting on voltage electric field generating electrode to produce electric field and display image in liquid crystal layer.This electric field determined the orientation of liquid crystal molecule in the liquid crystal layer and controlled polarization of incident light, thereby control sees through the brightness of the light behind the Polarizer on the colored optical filtering substrates, realizes different demonstration contrasts.

Recently, in dissimilar LCD, the LCD with vertical alignment mode is because its high contrast and obtained using very widely than the reference viewing angle of broad.In vertical alignment mode, the arrangement mode of liquid crystal molecule is: when not having electric field to produce between pixel electrode and public electrode, the liquid crystal molecule main shaft is perpendicular to upper and lower base plate.As used herein, " reference viewing angle " expression is corresponding to the visual angle of 1: 10 contrast or be used for the limit angles of brightness counter-rotating between gray level.

In having the LCD of vertical alignment mode, in order to add with great visual angle, can in pixel electrode and public electrode, form otch, in addition, can in pixel electrode and public electrode, form the projection body, to widen reference viewing angle.Because otch and projection body can be used for controlling the vergence direction of liquid crystal molecule,, liquid crystal molecule is tilted in the direction of expectation therefore by utilizing otch and projection body.Can guarantee to obtain visual angle like this than broad.

Provide wide visual angle although have the liquid crystal indicator of vertically joining as pattern, the problem that exists is, compares its side visibility deterioration with its preceding visibility.For example, in the pixel electrode pattern of the vertical alignment liquid crystal display device that is provided with otch, the image in the liquid crystal indicator side becomes brighter.Under serious situation more, it is very little that the luminance difference between the high grade grey level can become, and causes image fault, makes the visual angle diminish.

The problem that various technology are used to solve above-mentioned visual angle has been proposed, comprise following technology: by a pixel is divided into two pixels, with these two sub-pixels with capacitive coupling and by voltage is applied directly to a sub-pixel and since capacitive coupling reduce the voltage in another sub-pixel and provide different voltage to these two sub-pixels, different transmissivities is provided, thereby improves the visual angle.

But because the transmissivity that can not accurately regulate two sub-pixels, add because one of them sub-pixel can't reach the highest gamma (Gamma) voltage, thus its brightness meeting decline, thus reduced contrast, can influence the visual angle again, thus above technology in practice not as effective in theory.Another problem of this technology is to add and is used for capacity coupled conductive component, so can reduce aperture opening ratio.

So on the basis of this technology, proposed another technology again: though also be that a pixel is divided into two sub-pixels, but this technology has doubled the quantity of grid line, two sub-pixels come the intended pixel electrode voltage by two switching devices respectively, like this pixel electrode voltage of two sub-pixels can accurately be controlled, and can reach the reasonable effect of improving the visual angle.But because each bar grid line is driven by grid line drive IC independently, like this number needs of drive IC will double, and has increased cost widely.

The utility model content

Technical problem to be solved in the utility model provides and a kind ofly can obtain the reasonable effect of improving the visual angle, can make the grid line driving circuit double again, thereby can not increase the liquid crystal indicator and the dot structure thereof of cost greatly.

The utility model is to solve the problems of the technologies described above the technical scheme that adopts to provide a kind of dot structure, comprises first sweep trace, second sweep trace, data line, the first film transistor, first pixel electrode, second thin film transistor (TFT), second pixel electrode, the 3rd thin film transistor (TFT), the shared electric capacity of electric charge and the 4th thin film transistor (TFT).First sweep trace, second sweep trace and data line, first to fourth thin film transistor (TFT), first and second pixel electrodes and electric charge are shared electric capacity and all are disposed on the substrate.Wherein, the first film transistor is electrically connected to first sweep trace and data line, and the first film transistor have one first the drain electrode, first pixel electrode be electrically connected to this first the drain electrode.Second thin film transistor (TFT) is electrically connected to first sweep trace and data line, and second thin film transistor (TFT) have second the drain electrode, second pixel electrode be electrically connected to this second the drain electrode.The 3rd thin film transistor (TFT) is electrically connected to second sweep trace and data line, and the 3rd thin film transistor (TFT) has the 3rd drain electrode, and electric charge is shared electric capacity and is electrically connected to the 3rd drain electrode.One of them is connected second pixel electrode source electrode of the 4th thin film transistor (TFT) and drain electrode, and another connects electric charge and shares electric capacity, and the grid of the 4th thin film transistor (TFT) is connected to a sub-scanning line.

In above-mentioned dot structure, the sub-scanning line for drive order after first sweep trace of another dot structure.

In above-mentioned dot structure, the first film transistor and second thin film transistor (TFT) are the crossover sites that is adjacent to first sweep trace and data line.In addition, the first film transistor AND gate second thin film transistor (TFT) has a shared source electrode.

In above-mentioned dot structure, the 3rd thin film transistor (TFT) and thin film transistor (TFT) are the crossover sites that is adjacent to first sweep trace and data line.

The utility model also proposes a kind of liquid crystal indicator, and it comprises first scanner driver, second scanner driver, data driver and thin-film transistor array base-plate.Wherein, dispose a plurality of above-mentioned dot structures on the thin-film transistor array base-plate.First scanner driver provides first scanning drive signal of each pixel of liquid crystal indicator.Second scanner driver provides second scanning drive signal of each pixel of liquid crystal indicator; Data driver provides the data-signal of each pixel of liquid crystal indicator.Wherein second sweep trace of partial pixel structure is to connect second a common scanning drive signal at least.

In above-mentioned liquid crystal indicator, on the thin-film transistor array base-plate is that dot structure is divided into a plurality of zones, and second sweep trace in each zone connects the second common scanning drive signal.

Dot structure of the present utility model and liquid crystal indicator, owing to do not need to be the independent configuration driven IC of second sweep trace in each row dot structure, but common driving that second sweep trace of all dot structures can be linked together, therefore compared with prior art, the utility model can be saved the closely drive IC of half at most, thereby saves cost.

Description of drawings

For above-mentioned purpose of the present utility model, feature and advantage can be become apparent, below in conjunction with accompanying drawing embodiment of the present utility model is elaborated, wherein:

Fig. 1 is the dot structure synoptic diagram of an embodiment of the utility model.

Fig. 2 is the equivalent circuit diagram of dot structure shown in Figure 1.

Fig. 3 is the structured flowchart of the liquid crystal indicator of an embodiment of the utility model.

Fig. 4 is the drive waveforms synoptic diagram according to an embodiment of the utility model.

Embodiment

Describe one exemplary embodiment of the present utility model below with reference to accompanying drawings in detail, make the utility model easily to put into practice by those skilled in the art.The utility model can be implemented with various forms, and is not limited thereto the one exemplary embodiment shown in the place.

Fig. 1 is the dot structure figure of an embodiment of the utility model.Fig. 2 is the equivalent circuit diagram of dot structure shown in Figure 1.This dot structure is disposed on the thin-film transistor array base-plate, and it comprises one first sweep trace 101, a data line 102, one second sweep trace 103, shares capacitor C 3 with electrode wires 104, a first film transistor T FT1, one second thin film transistor (TFT) TFT2, one the 3rd thin film transistor (TFT) TFT3, one the 4th thin film transistor (TFT) TFT4, one first pixel electrode Pa, one second pixel electrode Pb and electric charge altogether.Wherein sweep trace 101,103 extends along first direction, and data line 102 extends along second direction, and the two intersects with the definition pixel region.The first pixel electrode Pa and the second pixel electrode Pb are positioned at this pixel region, and wherein the area of the first pixel electrode Pa is for example smaller or equal to the area of the second pixel electrode Pb.

The first film transistor T FT1 and the second thin film transistor (TFT) TFT2 are positioned near the cross part of first sweep trace 101 and data line 102.The first film transistor T FT1 has first drain electrode 105a and the grid (not marking), and the second thin film transistor (TFT) TFT2 has second drain electrode 105b and the grid (not marking).The first film transistor T FT1 and the second thin film transistor (TFT) TFT2 common-source 105c.Please shown in Figure 2 in conjunction with reference, TFT1 and TFT2 are electrically connected to first sweep trace 101 and data line 102 by source electrode 105c and its grid respectively.Memory capacitance Csta and the liquid crystal capacitance Clca of the corresponding first pixel electrode Pa are combined as capacitor C s1, it is electrically connected to the first drain electrode 105a of TFT1, memory capacitance Cstb and the liquid crystal capacitance Clcb of the corresponding second pixel electrode Pb are combined as capacitor C s2, and it is electrically connected to the second drain electrode 105b of TFT2.

The 3rd thin film transistor (TFT) TFT3 and the second thin film transistor (TFT) TFT4 are positioned near the cross part of second sweep trace 103 and data line 102.The 3rd thin film transistor (TFT) TFT3 has the 3rd source electrode 106a, the 3rd drain electrode 106b and grid (not marking), please shown in Figure 2 in conjunction with reference, TFT3 is electrically connected to data line 102 by the 3rd source electrode 106a, electrically connect second sweep trace 103 by its grid, and the 3rd drain electrode 106b is connected to the shared capacitor C 3 of electric charge.The 4th thin film transistor (TFT) TFT4 has the 4th source electrode 107a, the 4th drain electrode 107b and grid (not marking), wherein shown in Figure 2 in conjunction with reference, for example connect electric charge and share electric capacity with the 4th source electrode 107a, connect the second pixel electrode Pb with the 4th drain electrode 107b, and the grid of the 4th thin film transistor (TFT) connects the sub-scanning line 101a outside the dot structure so far.

Specifically, this sub-scanning line be drive in the thin-film transistor array base-plate order after first sweep trace of next column dot structure.With reference to shown in Figure 2, be called G_n at this first sweep trace, and the sub-scanning line of next column dot structure is called G_n+1 with this dot structure, second sweep trace is called OL, and data line is called SL.From the equivalent electrical circuit of dot structure shown in Figure 2 as can be known, the first sweep trace G_n is used to open thin film transistor (TFT) TFT1 and TFT2, and the second sweep trace OL is exclusively used in unlatching thin film transistor (TFT) TFT3, sub-scanning line G_n+1 can also be used to open thin film transistor (TFT) TFT4 except the unlatching of first and second thin film transistor (TFT)s that are used for next dot structure.

Please refer to shown in Figure 3ly below, it illustrates the structure of the liquid crystal indicator of the dot structure with the foregoing description of the present utility model.This liquid crystal indicator comprises a display panels assembly 10, as shown in Figure 3, display panels assembly 10 comprises a thin-film transistor array base-plate 100, has a plurality of on it as the described dot structure of above-mentioned embodiment, and these dot structures are with arranged.In addition, though not shown, display panels 10 also comprises the colored filter substrate relative with array base palte 100, and is clipped in two liquid crystal layers between the substrate.

Have on the thin-film transistor array base-plate 100 many many first sweep traces that are used to transmit signal (as G_n, G_n+1, G_n+2), play the second sweep trace OL that is similar to the grid line function, and be used for transmission of data signals many data lines (as SL_m, SL_m+1, SL_m+2).These first sweep traces and second sweep trace extend parallel to each other on the first direction of substrate, and these data lines extend parallel to each other on the second direction that is substantially perpendicular on the first direction, to form the pixel region for the dot structure configuration.

Liquid crystal indicator comprises the grayscale voltage generator that a figure does not show, it produces two grayscale voltage collection corresponding to the pixel transmission rate, and two grayscale voltages are used to put on independently two the sub-pixel Pa and the Pb of a pixel.One data driver 20 is connected in each data line SL of LCD panel 10, thereby the grayscale voltage that two grayscale voltages of choosing above-mentioned grayscale voltage generator are concentrated imposes on pixel as data-signal, and data driver is selected data voltage from the grayscale voltage that produces by division reference gray level voltage.

First scanner driver 30 is connected in each above-mentioned first sweep trace, and (as G_n, G_n+1 G_n+2), thereby will be applied on first sweep trace with first scanning drive signal that is combined to form of grid cut-in voltage and gate off voltage.

Timing controller 40 connects the data driver 20 and first scanner driver 30, plays the effect of signal controlling.

In addition, liquid crystal indicator also comprises second scanner driver 50 that is specifically designed to the 3rd thin film transistor (TFT) TFT3 in the above-mentioned dot structure of opening and closing, and it connects the second above-mentioned sweep trace OL and is applied on second sweep trace with second scanning drive signal that will be exclusively used in opening and closing TFT3.

In order to realize colored demonstration, each pixel is shown the primary colors of appointment uniquely, and by the different color of being combined to form of different primary colors, primary colors generally includes redness, green and blue.

The display operation of liquid crystal mesogens display is described below.The input control signal that timing controller 40 receives picture signal R, G and B and is used to control demonstration from the outside.These picture signals have been represented the monochrome information of each pixel, just specific GTG.Input control signal generally comprises vertical synchronization and horizontal-drive signal, and data enable signal DE, timing controller 40 receives these signals and produces grid control signal and data controlling signal later on, and can pass to first scanner driver 30 and data driver 20 respectively.

Grid control signal (i.e. first scanning drive signal) comprises and is used to represent the signal that a frame scan begins and is used for the signal that the gated sweep line is opened the time.

Data controlling signal comprises the horizontal start signal of the data transmission that is used to represent delegation's sub-pixel, is used for providing to pixel the load signal of charging voltage, and data clock signal and polarity inversion signal etc.

Response is from the data controlling signal of timing controller 40, data driver 20 receives the view data that is used for one group of word pixel, and choose one of two gray scale voltage collection from the gray scale voltage generator, and therefrom choose the pairing gray scale voltage of view data, resulting voltage is applied on the relevant data line.

To apply the driving process of data voltage to dot structure according to what Fig. 2～Fig. 4 described an embodiment of the utility model in detail below.Fig. 4 is the drive waveforms synoptic diagram according to an embodiment of the utility model.For comparison purpose, the voltage with pixel Pa and Pb illustrates with data output (Data Output) waveform.

As Fig. 2～shown in Figure 4, data voltage Data Output is being put in the time durations an of pixel column (one of them pixel shown in Fig. 2), T1 between a first phase at first, apply the grid cut-in voltage to sweep trace G_n, close voltage and apply grid to sweep trace G_n+1 and OL, TFT1 and TFT2 are opened simultaneously, and making TFT3 and TFT4 be in closed condition, simultaneously be applied to first pixel electrode Pa and second pixel electrode Pb with the voltage corresponding to view data in the first GTG collecting voltage this moment.

Then at a second phase T2, apply grid to the first sweep trace G_n and G_n+1 and close voltage, and apply the grid cut-in voltage to sweep trace OL, TFT3 is opened, and making TFT1, TFT2 and TFT4 be in closed condition, be applied to electric charge shared capacitor C 3 with the voltage corresponding to view data in the second GTG collecting voltage this moment.

Afterwards, between a third phase, apply the grid cut-in voltage to the first sweep trace G_n+1 again, close voltage and apply grid to sweep trace G_n and OL, TFT4 is opened, and making TFT1, TFT2 and TFT3 be in closed condition, the electric charge on the capacitor C s2 of the shared capacitor C 3 of electric charge this moment and the second pixel electrode Pb is redistributed.Through after redistributing, the voltage Vb on second pixel electrode will be different from the voltage Va on first pixel electrode, shown in data output (Data output) waveform among Fig. 4.

Two above-mentioned gray scale voltage collection have been represented different gamma (Gamma) curve, and be applied in respectively on two the different subpixel Pa and Pb of a pixel, make that the gamma curve of a pixel is that these two kinds of gamma curve mix, when determining two gray scale voltage collection, determine that mixed gamma curve makes it near the reference gamma curve that is used for front elevation, can so just can further improve horizontal visual angle so that the gamma curve of mixed side-looking approaches the reference gamma curve of front elevation like this.

The number of scanning lines of this LCD is the twice of common liquid crystals display, the time that causes every sweep trace to be opened shortens, in order to prolong the duration of charging of pixel electrode, the opening time of G_n and OL can be overlapped, promptly G_n closes in a period of time after OL opens again.

By above-mentioned driving process as can be known, the second sweep trace OL all is suitable for all pixels in the liquid crystal panel.Therefore all OL in the panel can connect together and apply second scanning drive signal (as shown in Figure 3) jointly, also can individual drive; More can be divided into several zones, the OL in each zone connects together and applies scanning drive signal jointly.Like this compare the prior art that each sweep trace needs independent drive IC, the utility model can be saved the closely gate driving IC of half at most, thereby saves cost.

Though the utility model discloses as above with preferred embodiment; right its is not in order to limit the utility model; any those skilled in the art; in not breaking away from spirit and scope of the present utility model; when doing a little modification and perfect, therefore protection domain of the present utility model is worked as with being as the criterion that claims were defined.

Claims (7)

1. dot structure is characterized in that comprising:

One first sweep trace is disposed on the substrate;

One second sweep trace is disposed on the described substrate;

One data line is disposed on the described substrate;

One the first film transistor is disposed on the described substrate, and is electrically connected to described first sweep trace and described data line, and described the first film transistor has one first drain electrode;

One first pixel electrode is disposed on the described substrate, and is electrically connected to described first drain electrode;

One second thin film transistor (TFT) is disposed on the described substrate, and is electrically connected to described first sweep trace and described data line, and described second thin film transistor (TFT) has one second drain electrode;

One second pixel electrode is disposed on the described substrate, and is electrically connected to described second drain electrode;

One the 3rd thin film transistor (TFT) is disposed on the described substrate, and is electrically connected to described second sweep trace and described data line, and described the 3rd thin film transistor (TFT) has one the 3rd drain electrode;

One electric charge is shared electric capacity, is disposed on the described substrate, and is electrically connected to described the 3rd drain electrode;

One the 4th thin film transistor (TFT), be disposed on the described substrate, one of them is connected described second pixel electrode source electrode of described the 4th thin film transistor (TFT) and drain electrode, and another connects described electric charge and shares electric capacity, and the grid of described the 4th thin film transistor (TFT) is connected to a sub-scanning line.

2. dot structure as claimed in claim 1 is characterized in that, described sub-scanning line for drive order after first sweep trace of another dot structure.

3. dot structure as claimed in claim 1 is characterized in that, the described the first film transistor and second thin film transistor (TFT) are the crossover sites that is adjacent to described first sweep trace and described data line.

4. dot structure as claimed in claim 1 is characterized in that, described second thin film transistor (TFT) of described the first film transistor AND gate has a shared source electrode.

5. dot structure as claimed in claim 1 is characterized in that, described the 3rd thin film transistor (TFT) and the 4th thin film transistor (TFT) are the crossover sites that is adjacent to described first sweep trace and described data line.

6. liquid crystal indicator is characterized in that comprising:

First scanner driver provides first scanning drive signal of each pixel of liquid crystal indicator;

Second scanner driver provides second scanning drive signal of each pixel of liquid crystal indicator;

Data driver provides the data-signal of each pixel of liquid crystal indicator;

One thin-film transistor array base-plate disposes a plurality of dot structures on it, wherein each dot structure comprises:

One first sweep trace is disposed on the described substrate, and is electrically connected to described first scanner driver;

One second sweep trace is disposed on the described substrate, and is electrically connected to described second scanner driver;

One data line is disposed on the described substrate;

One the first film transistor is disposed on the described substrate, and is electrically connected to described first sweep trace and described data line, and described the first film transistor has one first drain electrode;

One first pixel electrode is disposed on the described substrate, and is electrically connected to described first drain electrode;

One second thin film transistor (TFT) is disposed on the described substrate, and is electrically connected to described first sweep trace and described data line, and described second thin film transistor (TFT) has one second drain electrode;

One second pixel electrode is disposed on the described substrate, and is electrically connected to described second drain electrode;

One the 3rd thin film transistor (TFT) is disposed on the described substrate, and is electrically connected to described second sweep trace and described data line, and described the 3rd thin film transistor (TFT) has one the 3rd drain electrode;

One electric charge is shared electric capacity, is disposed on the described substrate, and is electrically connected to described the 3rd drain electrode;

One the 4th thin film transistor (TFT), be disposed on the described substrate, one of them is connected described second pixel electrode source electrode of described the 4th thin film transistor (TFT) and drain electrode, another connects described electric charge and shares electric capacity, the grid of described the 4th thin film transistor (TFT) be connected to drive order after first sweep trace of another dot structure;

Wherein second sweep trace of partial pixel structure is to connect second a common scanning drive signal at least.

7. liquid crystal indicator as claimed in claim 6 is characterized in that, the described dot structure on the described thin-film transistor array base-plate is divided into a plurality of zones, and described second sweep trace in each zone connects the second common scanning drive signal.

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