CN203811939U

CN203811939U - Touch display device and driving circuit

Info

Publication number: CN203811939U
Application number: CN201320892047.4U
Authority: CN
Inventors: 莫良华; 蒋新喜; 刘军桥
Original assignee: FocalTech Systems Ltd
Current assignee: Dun Tai Electronics Co., Ltd.
Priority date: 2013-12-31
Filing date: 2013-12-31
Publication date: 2014-09-03
Anticipated expiration: 2023-12-31
Also published as: TWM491212U

Abstract

The utility model provides a touch display device and a driving circuit. The touch display device comprises a public electrode and a driving circuit, wherein the public electrode is positioned between a first base plate and a second base plate and is used as a touch sensing electrode at the touch sensing stage, and the driving circuit is used for providing a first signal for realizing touch detection for the public electrode at the touch sensing stage; the driving circuit is also used for providing a second signal for a grid electrode wire at the touch sensing stage, through the second signal, a thin film transistor can be in a closed state, and meanwhile, the charging and discharging electric quantity of a capacitor formed by the public electrode and the grid electrode wire can also be reduced; and/or the driving circuit is also used for providing a third signal at the touch sensing stage, and the charging and discharging electric quantity of the capacitor formed by the public electrode and a data wire can also be reduced through the third signal. The utility model also provides the corresponding driving circuit. The touch display device and the driving circuit have the advantages that the interference caused by stray capacitance on the touch detection can be reduced, and the precision of the touch detection can be improved.

Description

Touch display unit, driving circuit

Technical field

The utility model relates to touch technology field, relates in particular to a kind of touch display unit, driving circuit.

Background technology

Touch-screen is as a kind of input medium, is the simplest, convenient, natural a kind of man-machine interaction mode at present.

With reference to figure 1, show a kind of liquid crystal indicator with embedded touch-screen (In-cell touch panel) of prior art, described liquid crystal indicator comprises from bottom to top successively: thin film transistor (TFT) (TFT, Thin Film Transistor) substrate 1, liquid crystal layer (Liquid Crystal) 2 and colored filter (CF, Color Filter) substrate 3, wherein, TFT substrate comprises: the first glass substrate 11, be positioned at the thin film transistor (TFT) 12 on the first glass substrate 11, CF substrate comprises from the bottom to top successively: public electrode 31, colored filter 32, touch-screen 33, the second glass substrate 34.Touch-screen 33 in Fig. 1 can self-capacitance formula touch-screen, and particularly, self-capacitance formula touch-screen detects is drive electrode or induction electrode and the electric capacity of ground end formation, and the capacitance variations causing during based on finger touches touch-screen is carried out position probing.

Liquid crystal indicator is when actual displayed, liquid crystal display drive circuit can be opened thin film transistor (TFT) 12 line by line by gate line, data line provides pixel voltage when gate line is opened thin film transistor (TFT), to the pixel electrode 35 of each sub-pixel, on public electrode 31, can load pixel voltage.With reference to figure 2, illustrated the equivalent circuit diagram of a sub-pixel unit in the liquid crystal indicator shown in Fig. 1.Pixel electrode 35 and public electrode 31 form an equivalent capacity Clc, in described equivalent capacity Clc, electric field can be through the liquid crystal molecule in liquid crystal layer 2, the size of electric field can determine the size of the anglec of rotation of liquid crystal molecule, and the liquid crystal molecule anglec of rotation can determine by the power of this sub-pixel light on specific direction.

And along with the raising of the lightening demand of touch-screen, prior art touches display technique also makes public electrode have the function that self-capacitance touches the detecting electrode detecting concurrently.As Fig. 3, illustrated a kind of schematic diagram of public electrode.Described public electrode comprises a plurality of square electrodes 36 of 4 row 4 row, and each square electrode 36 is all connected to and is driven chip 37 by connecting line.Described driving chip 37 timesharing drive described a plurality of square electrodes 36.Drive chip 37 showing that stage common electrode drive is to showing required current potential, at touch detection-phase, to public electrode, provide touch detection signal.

Yet, touching detection-phase, public electrode has also produced a plurality of stray capacitances, has affected and has touched the accuracy of detection detecting.With reference to figure 4, show the equivalent circuit diagram of the sub-pixel unit of the touch control display apparatus that comprises public electrode shown in Fig. 3.Public electrode as touch detection electrodes, easily produces the stray capacitance Cmg of public electrode to gate line, the stray capacitance Cms of public electrode to data line, and public electrode is to shielding the stray capacitance Cs etc. of external frame.The existence of above-mentioned stray capacitance is given to touch to detect and has been brought interference.

Utility model content

The problem that the utility model solves is to provide a kind of touch display unit, driving circuit, to reduce stray capacitance to touching the interference detecting, improves the precision that touch detects.

For addressing the above problem, the utility model provides a kind of touch display unit, for realizing touch sensible and demonstration, comprising: first substrate; Second substrate, is oppositely arranged with described first substrate, and described second substrate is provided with gate line, data line and thin film transistor (TFT) on the face of described first substrate; Liquid crystal layer, between described first substrate and second substrate; Public electrode, between described first substrate and second substrate, is used as touch sensible electrode in the touch sensible stage; Driving circuit, touches for providing to realize to described public electrode in the touch sensible stage first signal detecting; Described driving circuit is also for providing secondary signal in the touch sensible stage to described gate line, and described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or described driving circuit is also for providing the 3rd signal in the touch sensible stage to described data line, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor of public electrode and data line formation.

Optionally, described secondary signal and first signal are with the pulse signal of homophase frequently.

Optionally, described secondary signal and first signal are with frequently with the pulse signal of identical width.

Optionally, described the 3rd signal and first signal are with the pulse signal of homophase frequently.

Optionally, described the 3rd signal and first signal are with frequently with the pulse signal of identical width.Optionally, described the 3rd signal is to make the signal of described data line in floating dummy status.。

Optionally, described first signal, secondary signal or the 3rd signal are square-wave signal, sine wave signal or stairstep signal.

Optionally, described driving circuit also, for providing driving signal in the demonstration stage to gate line, provides display to data line, to public electrode, provides public voltage signal.

Optionally, described driving circuit comprises: common electrode drive unit, for generation of described public voltage signal and the first pulse signal; Drive element of the grid, is connected with many gate lines, for generation of described driving signal, also for generation of the second pulse signal with the same frequency of described the first pulse signal; Data line driver element, is connected with many data lines, for generation of display; Timing control unit, be connected with described common electrode drive unit, drive element of the grid and data line driver element, for providing successively driving signal at drive element of the grid described in demonstration stage control to many gate lines, control data line driver element and provide display to data line, control common electrode drive unit and provide public voltage signal to public electrode; Described timing control unit is also in the touch sensible stage, controlling common electrode drive unit provides the first pulse signal to detect to realize touching to public electrode, and controls drive element of the grid and provide the second pulse signal with described the first pulse signal homophase to described many gate lines.

Optionally, described data line driver element also for generation of with described the first pulse signal with the 3rd pulse signal frequently; Described timing control unit is also in the touch sensible stage, controls described data line driver element and provides the 3rd pulse signal with described the first pulse signal homophase to many data lines.

Optionally, described driving circuit also comprises: be arranged at the switch between data line driver element and many data lines, described data line driver element, for when described switch conduction, provides pixel voltage as display to data line; Described timing control unit is connected with described switch, for showing switch conduction described in stage control, so that described data line driver element provides pixel voltage to described data line; Also for disconnecting at switch described in touch sensible stage control, so that described data line is in floating dummy status.

Optionally, described driving circuit comprises: common electrode drive unit, for generation of described public voltage signal and the first pulse signal; Drive element of the grid, is connected with many gate lines, for generation of described driving signal; Data line driver element, is connected with many data lines, for generation of display, also for generation of with described the first pulse signal with the 3rd pulse signal frequently or be connected by switch with described many data lines; Timing control unit, be connected with described common electrode drive unit, drive element of the grid and data line driver element, for providing successively driving signal at drive element of the grid described in demonstration stage control to many gate lines, control data line driver element and provide display to data line, control common electrode drive unit and provide public voltage signal to public electrode; Described timing control unit is also in the touch sensible stage, controlling common electrode drive unit provides the first pulse signal to detect to realize touching to public electrode, and controls data line driver element and to described many data lines, provide with the 3rd pulse signal of described the first pulse signal homophase or control described switch and disconnect and make described data line in floating dummy status.

Optionally, described driving circuit is directly connected with described gate line.

Optionally, the mode that described driving circuit couples by electric capacity is connected with described gate line.

Accordingly, the utility model also provides a kind of driving circuit, and for driving touch display unit, described touch display unit comprises: first substrate; Second substrate, is oppositely arranged with described first substrate, and described second substrate is provided with gate line, data line and thin film transistor (TFT) on the face of described first substrate; Liquid crystal layer, between described first substrate and second substrate; Public electrode, between described first substrate and second substrate, is used as touch sensible electrode in the touch sensible stage; Described driving circuit comprises: the first driver module, touches for providing to realize to described public electrode in the touch sensible stage first signal detecting; The second driver module, for providing secondary signal in the touch sensible stage to described gate line, described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or the 3rd driver module is for providing the 3rd signal in the touch sensible stage to described data line, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor of public electrode and data line formation.

Optionally, described the 3rd signal and first signal are with frequently with the pulse signal of identical width.

Optionally, described the 3rd signal is to make the signal of described data line in floating dummy status.

Optionally, described the first driver module is also for providing public voltage signal in the demonstration stage to public electrode; Described the second driver module is also for providing driving signal in the demonstration stage to gate line, and described the 3rd driver module is also for providing display in the demonstration stage to data line.

Optionally, described the first driver module is directly connected with described gate line.

Optionally, the mode that described the first driver module couples by electric capacity is connected with described gate line.

Compared with prior art, the technical solution of the utility model has the following advantages:

Driving circuit in the utility model touch display unit is by providing first signal in the touch sensible stage to public electrode, to gate line, secondary signal is provided and/or the 3rd signal is provided, can reduce the charge/discharge electricity amount of capacitor parasitics between public electrode and gate line and/or data line, by reducing the charge/discharge electricity amount of described capacitor parasitics, capacitor parasitics can be reduced to touching the interference detecting, and then the precision that touches detection can be improved.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of a kind of embedded touch-screen liquid crystal indicator of prior art;

Fig. 2 is the equivalent circuit diagram of a sub-pixel unit in Fig. 1;

Fig. 3 is a kind of schematic diagram that has the public electrode of self-capacitance touch measuring ability concurrently of prior art;

Fig. 4 is that in prior art, public electrode makes the equivalent circuit diagram of a sub-pixel unit as touch-control electrode;

Fig. 5 is the schematic diagram of the utility model touch display unit one embodiment;

Fig. 6 is the schematic diagram of the driving signal of touch display unit shown in Fig. 5;

Fig. 7 is the schematic diagram of Fig. 5 driving circuit one embodiment;

Fig. 8 is the schematic diagram of Fig. 5 drive element of the grid one embodiment;

Fig. 9 is the schematic diagram of Fig. 5 common electrode drive unit one embodiment;

Figure 10 is the schematic diagram of Fig. 5 data line driver element one embodiment;

The schematic diagram of another embodiment of Figure 11 the utility model touch display unit.

Embodiment

For above-mentioned purpose of the present utility model, feature and advantage can more be become apparent, below in conjunction with accompanying drawing, specific embodiment of the utility model is described in detail.

In order to solve the problem of mentioning in background technology, the utility model provides a kind of touch display unit, with reference to figure 5, shows the schematic diagram of the utility model touch display unit one embodiment.Described touch display unit comprises:

First substrate (not shown), as the glass substrate of colored filter (Color Filter, CF) side.

Second substrate 111, as the glass substrate of thin film transistor (TFT) (Thin Film Transistor, TFT) side, described second substrate 111 is oppositely arranged with described first substrate.

Described second substrate 111 is also provided with many gate lines G on the face of first substrate ₁, G ₂g _m, many data line S ₁, S ₂s _nand thin film transistor (TFT) 104.The drain electrode of described thin film transistor (TFT) 106 is connected with pixel electrode (not shown), described many gate lines G ₁, G ₂g _mbe electrically connected to the grid of thin film transistor (TFT) 104, for the grid load driver signal to thin film transistor (TFT) 104, described many data line S ₁, S ₂s _nbe connected with the source electrode of thin film transistor (TFT) 104, for the source electrode to thin film transistor (TFT) 106, provide pixel voltage.

Liquid crystal layer (not shown), between described first substrate and second substrate 111.

Public electrode 105, between described first substrate and second substrate 111.Described public electrode 105 as touch sensible electrode, is used for load common electric voltage (VCOM) in the demonstration stage in the touch sensible stage.Particularly, described public electrode 105 can comprise a plurality of electrode units that matrix form is arranged, and realizes the detecting electrode that self-capacitance detects when described a plurality of electrode units are touch sensible.

Driving circuit 100, touches for providing to realize to described public electrode 105 in the touch sensible stage first signal detecting; Described driving circuit 100 also in the touch sensible stage to described gate lines G ₁, G ₂g _msecondary signal is provided, and described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or described driving circuit 100 is also for the 3rd signal was provided in the touch sensible stage, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor that public electrode and data line form.

It should be noted that, the charge/discharge electricity amount that reduces the capacitor that public electrode 105 and gate line (data line) form herein refers to: the capacitor when secondary signal (the 3rd signal) is not provided is compared, and charge/discharge electricity amount reduces.

The first signal that the present embodiment touch display unit provides to public electrode by driving circuit, the secondary signal providing (the 3rd signal) can reduce the charge/discharge electricity amount of capacitor parasitics between described public electrode and gate line (data line), thereby can reduce capacitor parasitics to touching the interference detecting, and then can improve the precision that touches detection.

Below in conjunction with the principle that can improve touch accuracy of detection to touch control display apparatus embodiment illustrated in fig. 5 with reference to the driving signal shown in figure 6, describe.

As shown in Figure 5, in the present embodiment, driving circuit 100 comprises:

Common electrode drive unit 103, is connected with public electrode 105, and for generation of described public voltage signal VCOM and the first pulse signal 201, described the first pulse signal 201 is described first signal.The first pulse signal 201 described herein for low level be the square-wave signal that 0V, high level are 2V.Described the first pulse signal 201 touches for being carried in as realizing on the public electrode of touch sensible electrode the detection signal detecting.

Drive element of the grid 101, with many gate lines G ₁, G ₂g _mbe connected, for generation of the second pulse signal 202.Described drive element of the grid 101 can with described gate lines G ₁, G ₂g _mdirectly connect.The mode that also can couple by electric capacity and described gate lines G ₁, G ₂g _mconnect.

Described the second pulse signal 202 is described secondary signal, and the second pulse signal 202 described herein for low level is-square-wave signal that 12V, high level are-10V.Described the second pulse signal 202 is the pulse signal with the same width of frequency (amplitude is 2V) with described the first pulse signal 201.Described the second pulse signal 202 high level are much smaller than the cut-in voltage of thin film transistor (TFT) 104, can so that thin film transistor (TFT) 104 in closed condition, thereby the signal loading on not to liquid crystal cell in the touch sensible stage exerts an influence, and then can make touch display unit can realize normal Presentation Function.

Data line driver element 102, with many data line S ₁, S ₂s _nbe connected, for generation of the 3rd pulse signal 203, described the 3rd pulse signal 203 is described the 3rd signal, the 3rd pulse signal 203 described herein for low level be the square-wave signal that 0V, high level are 2V, described the 3rd pulse signal 203 and described the first pulse signal 201 are for the pulse signal of same width (amplitude is 2V) frequently.

Timing control unit (not shown), drive Unit 102 to be connected with described common electrode drive unit 103, drive element of the grid 101 and data line, be used in the touch sensible stage, controlling common electrode drive unit 201 provides the first pulse signal to detect to realize touching to public electrode 105, and controls drive element of the grid 101 to described many gate lines G ₁, G ₂g _mthe second pulse signal 202 with described the first pulse signal 201 homophases is provided, also controls data line driver element 102 to described many data line S ₁, S ₂s _nthe 3rd pulse signal 203 with described the first pulse signal 201 homophases is provided.

The driving circuit 100 of the present embodiment touch display unit is in the touch sensible stage, by drive element of the grid 101 to many gate lines G ₁, G ₂g _mprovide and the first pulse signal 201 with frequently with the second pulse signal 202 of identical width, even public electrode 105 and gate lines G like this ₁, G ₂g _mbetween form capacitor, but two pole plate public electrodes 105 of described capacitor and gate lines G ₁, G ₂g _mupper owing to being loaded with frequently with the signal of identical width, that is to say, any time capacitor two battery lead plates on all load identical magnitude of voltage, thereby capacitor do not discharge and recharge, i.e. described public electrode 105 and gate lines G ₁, G ₂g _mthe charge/discharge electricity amount of the capacitor forming is zero.With not in gate lines G ₁, G ₂g _mcomparison while loading described the second pulse signal 202, charge/discharge electricity amount is decreased to zero.That is to say public electrode 105 and gate lines G ₁, G ₂g _mbetween capacitor cannot be to touch to detect produce disturbing in side circuit, and then can improve and touch the precision detecting.

The driving circuit 100 of the present embodiment touch display unit is also in the touch sensible stage, by data line driver element 102 to many data line S ₁, S ₂s _nprovide and the first pulse signal 201 with frequently with the 3rd pulse signal 203 of identical width, even public electrode 105 and data line S like this ₁, S ₂s _nbetween form capacitor, but two pole plate public electrodes 105 of described capacitor and data line S ₁, S ₂s _nupper owing to being loaded with frequently with the signal of identical width, any time capacitor two battery lead plates on all load identical magnitude of voltage, thereby capacitor do not discharge and recharge, i.e. described public electrode 105 and data line S ₁, S ₂s _nthe charge/discharge electricity amount of the capacitor forming is zero.With not at data line S ₁, S ₂s _ncomparison while loading described the 3rd pulse signal 203, charge/discharge electricity amount is decreased to zero.That is to say public electrode 105 and data line S ₁, S ₂s _nbetween capacitor cannot be to touch to detect produce disturbing in side circuit, and then can improve and touch the precision detecting.

Also it should be noted that, the second pulse signal 202 in the present embodiment, the 3rd pulse signal 203 is and described the first pulse signal 201 with frequently with the signal of identical width, the capacitor of public electrode and gate line (data line) formation is is no longer discharged and recharged.But the utility model is not restricted this, the second pulse signal 202, the 3rd pulse signal 203 is and described the first pulse signal 201 with the signal of homophase frequently, even any time capacitor two battery lead plates on the magnitude of voltage that loads different, because the signal of two battery lead plates is with homophase frequently, with respect to gate line not plus signal compare the electric potential difference having reduced between capacitor electrode pole plate, can reach and make public electrode 105 and gate lines G ₁, G ₂g _m(data line S ₁, S ₂s _n) object that reduces of the capacitor charging/discharging electric weight that forms.

Also it should be noted that, in the present embodiment, first signal, secondary signal and the 3rd signal are pulse signal, and whether the utility model is to being that pulse signal is not restricted, so long as correspondence is carried in public electrode 105, gate lines G ₁, G ₂g _mwith data line S ₁, S ₂s _non can to reduce the signal of capacitor electric weight all passable.

Also it should be noted that, in the present embodiment, what described first signal, secondary signal and the 3rd signal adopted is square-wave pulse signal, the utility model does not limit this yet, in other embodiments, described first signal, secondary signal and the 3rd signal can also be sine wave signal or stairstep signal.

Driving circuit 100 in the present embodiment touch display unit can reduce public electrode 105 and gate lines G ₁, G ₂g _mbetween the impact of stray capacitance, can also reduce public electrode 105 and data line S ₁, S ₂s _nbetween the impact of stray capacitance.But the utility model is not restricted this, in other embodiment touch display units, described drive element of the grid 101 can also be only set, play and reduce public electrode 105 and gate lines G ₁, G ₂g _mthe effect of stray capacitance to the interference touch detecting.Correspondingly, for the embodiment that described drive element of the grid 101 is only set, timing control unit only need be controlled drive element of the grid 101 to described many gate lines G ₁, G ₂g _mthe second pulse signal 202 with described the first pulse signal 201 homophases is provided.

Or, in other embodiment touch display units, described data line driver element 102 can also be only set, play and reduce public electrode 105 and data line S ₁, S ₂s _nthe effect of stray capacitance to the interference touch detecting.Correspondingly, for the embodiment that described data-driven unit 102 is only set, timing control unit only need be controlled data-driven unit 102 to described many data line S ₁, S ₂s _nthe 3rd pulse signal 203 with described the first pulse signal 201 homophases is provided.

Please continue to refer to Fig. 5 and Fig. 6, the driving circuit 100 of the present embodiment touch control display apparatus has the process that shows and drive touch to detect that drives concurrently.Driving circuit 100 will drive the circuit part showing and the circuit part that drives touch to detect to integrate.

Specifically, driving circuit 100 also in the demonstration stage to gate lines G ₁, G ₂g _mprovide driving signal, to data line S ₁, S ₂s _ndisplay is provided, to public electrode 105, provides public voltage signal.But the utility model is not restricted this, in other embodiments, described driving circuit can only possess the function that drives the circuit part that touches detection, as long as can play and reduce stray capacitance interference in the touch sensible stage.

Particularly, described driving circuit 100 has total time schedule controller (not shown), for timesharing, drives demonstration stage and touch sensible stage.For touch sensible stage driving circuit 100, please refer to foregoing description does not repeat them here.Introduce in detail the working method of demonstration stage driving circuit 100 below.

As shown in Figure 6, the drive element of the grid 101 of described driving circuit 100, also for generation of described driving signal.Driving circuit is driving grid line G successively herein particularly ₁, G ₂, G ₃the time sequential pulse signal of GM, described pulse signal is that high level is that 15V low level is 0 pulse signal.

Data line driver element 102, also for generation of display D;

Common electrode drive unit 103, also for public voltage signal VCOM.

Timing control unit, is connected with described common electrode drive unit 103, drive element of the grid 101 and data line driver element 102, for showing described in stage control that drive element of the grid 101 is to many gate lines G ₁, G ₂, G ₃g _mdriving signal is provided successively, controls data line driver element 102 to data line S ₁, S ₂s _ndisplay D is provided, controls common electrode drive unit 103 and provide public voltage signal VCOM to public electrode 105; Described timing control unit is also in the touch sensible stage, and controlling common electrode drive unit 103 provides the first pulse signal 201 to detect to realize touching to public electrode 105, and controls drive element of the grid 101 to described many gate lines G ₁, G ₂, G ₃g _mthe second pulse signal 202 with described the first pulse signal 201 homophases is provided, and described timing control unit also, in the touch sensible stage, is controlled described data line driver element 102 to many data line S ₁, S ₂s _nthe 3rd pulse signal 202 with described the first pulse signal 201 homophases is provided.

Below in conjunction with physical circuit, driving circuit 100 is further detailed.

The schematic diagram of one embodiment of driving circuit shown in Fig. 5 is shown with reference to figure 7.In the present embodiment, driving circuit 100 also comprises being arranged on screen body (in Fig. 5 region shown in dotted line frame for screen body) and shields grid circuit 106.It should be noted that, this sentences resolution is that the touch display unit of 1280 * 720RGB is example.On screen body, left and right respectively produces 640 gate lines, particularly, on described screen, grid circuit 106 is formed by connecting by 640 RS Cell electronic circuits (described RS Cell is as latch), in RS Cell electronic circuit, VGL end is to be carried on gate line for closing the voltage source of thin film transistor (TFT) TFT, CK end is clock input signal, SP end is data input pin, and OUT is output terminal.

The logic control signal that drive element of the grid 101 need provide to RS Cell electronic circuit comprises: CK1_L, CK2_L, SP_L, CK1_R, CK2_R, SP_R and VGLO are to realize gate lines G ₁, G ₂, G ₃g _mthe driving of (M is 1280).

With reference to figure 8, illustrated the schematic diagram of drive element of the grid 101 1 embodiment in Fig. 5.Described drive element of the grid 101 comprises:

Charge pump 1012, comprising: the first output terminal, for exporting the first voltage VGH(15V that drives thin film transistor (TFT) to open); The second output terminal, controls for exporting the second voltage VGL1(-12V that thin film transistor (TFT) cuts out).

Voltage adjuster 1013, be connected with the second output terminal of described charge pump 1012, for adjusting the second voltage of charge pump 1012 outputs, form tertiary voltage VGL2(-10V), described second voltage and the described the 3rd is pressed low level and the high level that corresponds respectively to described the second pulse signal 202.

A plurality of high drive unit 1015, input end is connected with voltage adjuster 1013 with the first output terminal, second output terminal of described charge pump 1012, output terminal is connected with the data input pin SP end of RS Cell electronic circuit, CK end is connected, for output logic control signal CK1_L, CK2_L, SP_L, CK1_R, CK2_R, SP_R.

Concrete, described high drive unit 1015 comprises: a PMOS pipe P1, and source electrode is connected with the first output terminal of described charge pump 1012 (being loaded with the first voltage VGH), and grid is connected with the first time schedule controller (not shown); The one NMOS pipe N1A, source electrode is connected (being loaded with second voltage VGL) with the second output terminal of described charge pump 1012, and grid is all connected with the second time schedule controller with described the 3rd time schedule controller; The 2nd NMOS pipe N1B, source electrode is connected with described voltage adjuster 1013 (loading tertiary voltage VGL2), and grid is connected with the second time schedule controller, and drain electrode is all connected with the drain electrode of a described NMOS pipe N1A, the drain electrode of a described PMOS pipe P1.

Power supply signal unit 1014, input end is connected with voltage adjuster with the second output terminal of described charge pump 1012, and output terminal is connected with the voltage source V GL input end of described a plurality of RS Cell electronic circuits.

Concrete, described power supply signal unit 1014 comprises: the 3rd NMOS pipe N2A and the 4th NMOS pipe N2B; The 3rd output terminal of charge pump 1012 described in the source electrode of described the 3rd NMOS pipe N2A, grid is connected with the second time schedule controller; The source electrode of described the 4th NMOS pipe N2B is connected with the output terminal of described voltage adjuster 1013, and grid is connected with described two time schedule controllers, and drain electrode is connected with the drain electrode of described the 3rd NMOS pipe.

Timing control unit 1011 comprises: the first time schedule controller (not shown), be connected with described high drive unit 1015, be used for driving described high drive unit 1015 alternately to export described the first voltage VGH and second voltage VGL1, to load described the first voltage VGH and second voltage VGL1 to described many gate line timesharing respectively, so that needed driving signal of demonstration stage to be provided to many gate line timesharing.

Timing control unit 1011 also comprises the second time schedule controller, be connected with described power supply signal unit 1014 with described high drive unit 1015, for driving described power supply signal unit 1014 alternately to export the voltage source V GL input end of described second voltage VGL1 and tertiary voltage VGL2 to RS Cell electronic circuit; Described the second time schedule controller is also alternately exported the data input pin SP of described second voltage VGL1 and tertiary voltage VGL2 to RS Cell electronic circuit for controlling described high drive unit 1015, so that the signal of the voltage source V GL input end of described RS Cell electronic circuit can export the output terminal OUT of RS Cell electronic circuit to, so that needed the second pulse signal 202 of touch sensible stage to be provided to many gate lines.

Described timing control unit 1011 also comprises: total time schedule controller (not shown), be connected with the second time schedule controller with described the first time schedule controller, for driving at the first time schedule controller described in demonstration stage control, for driving at the second time schedule controller described in touch sensible stage control.

With reference to figure 9, the schematic diagram of data line driver element one embodiment in Fig. 5 is shown.Particularly, described data line driver element comprises:

Timing control unit 1011 and a plurality of data line signal buffer 1023, described a plurality of data line signal buffers 1023 and many data line S ₁, S ₂s _ncorresponding one by one.

Described data line signal buffer 1023 comprises:

Positive polarity driving circuit 1021, output terminal is connected with described respective data lines, for generation of make liquid crystal molecule to the first pixel voltage of first direction deflection as described display, described positive polarity driving circuit is near being provided with the first switch T1A in output.

Negative polarity driving circuit 1022, output terminal is connected with described respective data lines, for generation of make liquid crystal molecule to the second pixel voltage of second direction deflection as display, described negative polarity driving circuit is provided with second switch T1D near output.

Described data line driver element also comprises: the 3rd switch T1B, one end is 2V with the voltage of voltage source V SP(VSP) be connected, the other end is connected with the output terminal of data line driver element; The 4th switch T1C, one section is connected with ground end, and the other end is connected with the output terminal of data line driver element.

Described timing control unit 1011 also comprises: the 3rd time schedule controller (not shown), by total time schedule controller, in the demonstration stage, driven, all be connected with described positive polarity driving circuit 1021, negative polarity driving circuit 1022, for driven the first switch T1A conducting, second switch T1D conducting, so that described positive polarity driving circuit, negative polarity driving circuit are exported respectively the first pixel voltage, the second pixel voltage.

Described timing control unit 1011 also comprises: the 4th time schedule controller, by total time schedule controller, in the touch sensible stage, driven, for driven the 3rd switch T1B conducting (not shown), the 4th switch T1C conducting, described the 3rd pulse signal 203 that the timesharing of take output high level is 0 as voltage source voltage, low level.

With reference to Figure 10, Fig. 9 is the schematic diagram of Fig. 1 common electrode drive unit one embodiment.Described common electrode drive unit comprises:

Touch detection circuit 1033, pass through respectively the first K switch 1A, K2A with a plurality of electrodes of public electrode 105 ... KNA is connected, be used at described the first K switch 1A, K2A ... during KNA conducting, described a plurality of electrodes are loaded to the first pulse signal, to realize touching, detect.

Common electrode drive impact damper 1032, passes through respectively second switch K1B, K2B with a plurality of electrodes of public electrode 105 ... KNB is connected, at described second switch K1B, K2B ... during KNB conducting, described a plurality of electrodes are loaded to public voltage signal.

Timing control unit 1011 and described the first K switch 1A, K2A ... KNA and described second switch K1B, K2B ... KNB is connected, for driving described the first K switch 1A, K2A in the touch sensible stage ... KNA conducting, thus make a plurality of electrodes of 1033 pairs of public electrodes 105 of touch detection circuit carry out self-capacitance detection; Also for drive described second switch K1B, K2B in the demonstration stage ... KNB conducting, thus make a plurality of electrodes of 1032 pairs of public electrodes 105 of common electrode drive impact damper that public voltage signal is provided.

It should be noted that, Fig. 8, Fig. 9 and Figure 10 are respectively a kind of specific implementation circuit of drive element of the grid 101, data line driver element 102 and common electrode drive unit 103, the utility model is not restricted this, in other embodiments, described drive element of the grid 101, data line driver element 102 and common electrode drive unit 103 can also adopt other circuit.

In addition, in other embodiments, the drive element of the grid of described driving circuit (or data line driver element) can also only be realized Presentation Function, touch sensible phase data line drive circuit provides the pulse signal corresponding with first signal to data line (or gate line drive circuit is to gate line), only reduce the stray capacitance of data line (or gate line) and public electrode to touching the interference detecting, also can realize and improve the object that touches accuracy of detection.

It should be noted that, in the above-described embodiments, the signal that the 3rd signal provides to data line for driving circuit, by being carried in the 3rd signal on data line and being carried in the charge/discharge electricity amount that first signal on public electrode reduces capacitor.But the utility model does not limit this, in other embodiments, described the 3rd signal can also be the signal not being carried on data line.

With reference to Figure 11, show the schematic diagram of another embodiment of the utility model touch display unit.The present embodiment and something in common embodiment illustrated in fig. 5 repeat no more, be with difference embodiment illustrated in fig. 5, between driving circuit and data line, by switch (not shown), couple, the signal that the 3rd signal 303 of the present embodiment disconnects for controlling described switch, can make data line in the touch sensible stage in floating dummy status.The meaning of floating dummy status described herein refers to, and the data line that the script demonstration stage is connected with driving circuit was disconnected in the touch sensible stage.

Data line does not reload any signal in touch sensible stage and driving circuit disconnection like this, therefore in the touch sensible stage, in the capacitor that public electrode and data line form, the battery lead plate that data line is corresponding is not led and is connected with any device, capacitor can not discharge and recharge, thereby reduced charge/discharge electricity amount, improved and touched the precision detecting.

Particularly, for the driving circuit that has Presentation Function and touch measuring ability concurrently, the something in common of driving circuit and last embodiment repeats no more, the difference of driving circuit and last embodiment is, driving circuit also comprises: be arranged at the switch between data line driver element and many data lines, described data line driver element, for when described switch conduction, provides pixel voltage as display to data line; Described timing control unit is connected with described switch, for showing switch conduction described in stage control, so that described data line driver element provides pixel voltage to described data line; Also for controlling described switch in the touch sensible stage by the 3rd signal 303, disconnect, so that described data line is in floating dummy status.Interference touch being detected to reduce the stray capacitance of data line and public electrode in the touch sensible stage.

It should be noted that, in the embodiment shown in fig. 11, drive element of the grid is also to described many gate lines G ₁, G ₂, G ₃g _mprovide and second pulse signal 302 of the same frequency of described the first pulse signal 301 with identical width, to reduce the interference of public electrode and gate line and data line stray capacitance simultaneously.In other embodiments, the drive element of the grid of described driving circuit can also only be realized Presentation Function, touch sensible stage driving circuit makes data line in floating dummy status, only reduce the stray capacitance of data line and public electrode to touching the interference detecting, also can realize and improve the object that touches accuracy of detection.

Accordingly, the utility model also provides a kind of driving circuit, and in application touch display unit, described touch display unit comprises: first substrate; Second substrate, is oppositely arranged with described first substrate, and described second substrate is provided with gate line, data line and thin film transistor (TFT) on the face of described first substrate; Liquid crystal layer, between described first substrate and second substrate; Public electrode, between described first substrate and second substrate, is used as touch sensible electrode in the touch sensible stage.

Described driving circuit comprises: the first driver module, touches for providing to realize to described public electrode in the touch sensible stage first signal detecting; The second driver module, for providing secondary signal in the touch sensible stage to described gate line, described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or the 3rd driver module is for providing the 3rd signal in the touch sensible stage to described data line, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor of public electrode and data line formation.

Particularly, described the first driver module comprises the part that common electrode drive unit and timing control unit drive common electrode drive unit; Described the second driver module comprises: the part that drive element of the grid and timing control unit drive drive element of the grid; Described the 3rd driver module comprises the part that data line driver element and timing control unit drive data line driver element.

Associated description about driving circuit is described in the related embodiment of touch display unit, does not repeat them here.

Although the utility model discloses as above, the utility model is not defined in this.Any those skilled in the art, within not departing from spirit and scope of the present utility model, all can make various changes or modifications, and therefore protection domain of the present utility model should be as the criterion with claim limited range.

Claims

1. a touch display unit, for realizing touch sensible and demonstration, is characterized in that, comprising:

First substrate;

Second substrate, is oppositely arranged with described first substrate, and described second substrate is provided with gate line, data line and thin film transistor (TFT) on the face of described first substrate;

Liquid crystal layer, between described first substrate and second substrate;

Public electrode, between described first substrate and second substrate, is used as touch sensible electrode in the touch sensible stage;

Driving circuit, touches for providing to realize to described public electrode in the touch sensible stage first signal detecting;

Described driving circuit is also for providing secondary signal in the touch sensible stage to described gate line, and described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or described driving circuit is also for the 3rd signal was provided in the touch sensible stage, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor of public electrode and data line formation.

2. touch display unit as claimed in claim 1, is characterized in that, described secondary signal and first signal are the pulse signal with frequency homophase.

3. touch display unit as claimed in claim 1, is characterized in that, described secondary signal is the pulse signal with identical width with frequency with first signal.

4. touch display unit as claimed in claim 1, is characterized in that, described driving circuit provides described the 3rd signal to described data line, and described the 3rd signal and first signal are the pulse signal with frequency homophase.

5. touch display unit as claimed in claim 1, is characterized in that, described driving circuit provides described the 3rd signal to described data line, and described the 3rd signal is the pulse signal with identical width with frequency with first signal.

6. touch display unit as claimed in claim 1, is characterized in that, between described driving circuit and data line, by switch, couples, and described the 3rd signal is the signal that described switch is disconnected, so that described data line is in floating dummy status.

7. touch display unit as claimed in claim 1, is characterized in that, described first signal, secondary signal or the 3rd signal are square-wave signal, sine wave signal or stairstep signal.

8. touch display unit as claimed in claim 1, is characterized in that, described driving circuit also, for providing driving signal in the demonstration stage to gate line, provides display to data line, to public electrode, provides public voltage signal.

9. touch display unit as claimed in claim 8, is characterized in that, described driving circuit comprises:

Common electrode drive unit, for generation of described public voltage signal and the first pulse signal;

Drive element of the grid, is connected with many gate lines, for generation of described driving signal, also for generation of the second pulse signal with the same frequency of described the first pulse signal;

Data line driver element, is connected with many data lines, for generation of display;

Timing control unit, be connected with described common electrode drive unit, drive element of the grid and data line driver element, for providing successively driving signal at drive element of the grid described in demonstration stage control to many gate lines, control data line driver element and provide display to data line, control common electrode drive unit and provide public voltage signal to public electrode; Described timing control unit is also in the touch sensible stage, controlling common electrode drive unit provides the first pulse signal to detect to realize touching to public electrode, and controls drive element of the grid and provide the second pulse signal with described the first pulse signal homophase to described many gate lines.

10. touch display unit as claimed in claim 9, is characterized in that, described data line driver element is also for generation of the 3rd pulse signal with the same frequency of described the first pulse signal;

Described timing control unit is also in the touch sensible stage, controls described data line driver element and provides the 3rd pulse signal with described the first pulse signal homophase to many data lines.

11. touch display units as claimed in claim 9, is characterized in that, described driving circuit also comprises:

Be arranged at the switch between data line driver element and many data lines, described data line driver element, for when described switch conduction, provides pixel voltage as display to data line;

Described timing control unit is connected with described switch, for showing switch conduction described in stage control, so that described data line driver element provides pixel voltage to described data line; Also for disconnecting by switch described in the 3rd signal controlling in the touch sensible stage, so that described data line is in floating dummy status.

12. touch display units as claimed in claim 8, is characterized in that, described driving circuit comprises:

Drive element of the grid, is connected with many gate lines, for generation of described driving signal;

Data line driver element, is connected with many data lines, for generation of display, also for generation of the 3rd pulse signal with the same frequency of described the first pulse signal; Or by switch, couple between data line driver element and many data lines, described data line driver element controls for providing the 3rd signal that described switch disconnects;

Timing control unit, be connected with described common electrode drive unit, drive element of the grid and data line driver element, for providing successively driving signal at drive element of the grid described in demonstration stage control to many gate lines, control data line driver element and provide display to data line, control common electrode drive unit and provide public voltage signal to public electrode; Described timing control unit is also in the touch sensible stage, controlling common electrode drive unit provides the first pulse signal to detect to realize touching to public electrode, and control data line driver element to described many data lines provide with the 3rd pulse signal of described the first pulse signal homophase or by switch described in the 3rd signal controlling disconnect so that described data line in floating dummy status.

13. touch display units as claimed in claim 1, is characterized in that, described driving circuit is directly connected with described gate line.

14. touch display units as claimed in claim 1, is characterized in that, the mode that described driving circuit couples by electric capacity is connected with described gate line.

15. 1 kinds of driving circuits, for driving touch display unit, described touch display unit comprises: first substrate; Second substrate, is oppositely arranged with described first substrate, and described second substrate is provided with gate line, data line and thin film transistor (TFT) on the face of described first substrate; Liquid crystal layer, between described first substrate and second substrate; Public electrode, between described first substrate and second substrate, is used as touch sensible electrode in the touch sensible stage; It is characterized in that, described driving circuit comprises:

The first driver module, touches for providing to realize to described public electrode in the touch sensible stage first signal detecting;

The second driver module, for providing secondary signal in the touch sensible stage to described gate line, described secondary signal can make described thin film transistor (TFT) in closed condition, can also reduce the charge/discharge electricity amount of the capacitor of public electrode and gate line formation simultaneously; And/or the 3rd driver module is for providing the 3rd signal in the touch sensible stage, described the 3rd signal can reduce the charge/discharge electricity amount of the capacitor of public electrode and data line formation.

16. driving circuits as claimed in claim 15, is characterized in that, described secondary signal and first signal are the pulse signal with frequency homophase.

17. driving circuits as claimed in claim 15, is characterized in that, described secondary signal is the pulse signal with identical width with frequency with first signal.

18. driving circuits as claimed in claim 15, is characterized in that, described the 3rd driver module provides described the 3rd signal to described data line, and described the 3rd signal and first signal are the pulse signal with frequency homophase.

19. driving circuits as claimed in claim 15, is characterized in that, described the 3rd driver module provides described the 3rd signal to described data line, and described the 3rd signal is the pulse signal with identical width with frequency with first signal.

20. driving circuits as claimed in claim 15, is characterized in that, between described the 3rd driver module and data line, by switch, couple, and described the 3rd signal is the signal that described switch is disconnected, so that described data line is in floating dummy status.

21. driving circuits as claimed in claim 15, is characterized in that, described first signal, secondary signal or the 3rd signal are square-wave signal, sine wave signal or stairstep signal.

22. driving circuits as claimed in claim 15, is characterized in that, described the first driver module is also for providing public voltage signal in the demonstration stage to public electrode; Described the second driver module is also for providing driving signal in the demonstration stage to gate line, and described the 3rd driver module is also for providing display in the demonstration stage to data line.

23. driving circuits as claimed in claim 22, is characterized in that, described driving circuit comprises:

24. driving circuits as claimed in claim 23, is characterized in that, described data line driver element is also for generation of the 3rd pulse signal with the same frequency of described the first pulse signal;

25. driving circuits as claimed in claim 23, it is characterized in that, described driving circuit also comprises: be arranged at the switch between data line driver element and many data lines, described data line driver element, for when described switch conduction, provides pixel voltage as display to data line;

26. driving circuits as claimed in claim 22, is characterized in that, described driving circuit comprises:

27. driving circuits as claimed in claim 15, is characterized in that, described the first driver module is directly connected with described gate line.

28. driving circuits as claimed in claim 15, is characterized in that, the mode that described the first driver module couples by electric capacity is connected with described gate line.