CN203250518U - Pixel circuit, organic light emitting display panel and display device - Google Patents

Abstract

The utility model provides a pixel circuit, an organic light emitting display panel and a display device. The pixel circuit is provided with a touch sensing module, a driving transistor, a driving control module and a light emitting module. A diode connection method for the driving transistor is employed by the pixel circuit, the pixel circuit discharges to form a threshold voltage which can compensate a threshold voltage of the driving transistor, so that a driving current of the driving transistor is unrelated to the threshold voltage of the driving transistor, driving currents of an OLED at different positions on the organic light emitting display panel are the same, and uniformity and reliability of the brightness of the organic light emitting display can be improved.

Description

Image element circuit, organic electroluminescence display panel and display device

Technical field

The utility model relates to the organic light emitting display field, relates in particular to a kind of image element circuit, organic electroluminescence display panel and display device.

Background technology

Touch-screen (touch screen panel) obtains increasing the concern in consumption electronic product market.Touch-screen has been widely used in the mobile electronic device as the interface of man-machine interaction at present, such as mobile phone, notebook computer, digital camera etc.Touch screen technology can be divided into two classes according to technology: externally positioned type (external) and internally-arranged type (in-cell).The externally positioned type touch-screen is as the term suggests do exactly a touching device again on display.The externally positioned type touch-screen has been widely used in the mobile application products such as mobile phone.Yet the externally positioned type touch-screen has improved the touch display unit cost, has increased the thickness of touch display unit.When especially will do touch display unit increasingly, two shortcomings of this of externally positioned type touch-screen just display all the more.

Current, consumer electronics product such as mobile phone, panel computer etc. all want cube less, and thickness is thinner, and weight is lighter.And the in-cell touch-screen can address these problems well owing to being incorporated in the display panel.

And with regard to display panel, because active matrix organic light-emitting diode (Active Matrix Organic Light Emitting Diode, AMOLED) display panel has without visual angle restriction, low manufacturing cost, high answer speed (being about more than hundred times of liquid crystal), power saving, autoluminescence, the direct drive that can be used for portable machine, operating temperature range is large and lightweight and can be with hardware device miniaturization and slimming etc. advantage to meet the characteristic requirements of multimedia era display.Therefore, active matrix organic light emitting diode display has great development potentiality, is expected to become follow-on novel planar display.

Based on internally-arranged type touch-screen and active matrix organic light-emitting diode display panel advantage separately, with the integrated setting of the two, become the mainstream development direction of electronic product.

So, how in same circuit, the detecting of integration realization touch-screen touch signal and the driving of image element circuit become at present technical matters anxious to be resolved.

The utility model content

The utility model provides a kind of image element circuit, organic electroluminescence display panel and display device, by drive transistor threshold voltage Vth is compensated, thereby so that the threshold voltage vt h of the drive current of driving transistors and driving transistors is irrelevant, thereby it is consistent to reach electric current, can improve homogeneity and the reliability of display panel brightness.

The utility model provides scheme as follows:

The utility model embodiment provides a kind of image element circuit, comprises driving transistors, drive control module, light emitting module; Wherein:

Described driving transistors is connected with described drive control module, described light emitting module respectively;

Described drive control module, respectively with the first level signal input end, the second electrical level signal input part, the first timing control signal input end, the second timing control signal input end, the 3rd timing control signal input end, the second timing control signal input end of upper level image element circuit, the second timing control signal input end of next stage image element circuit, described driving transistors, described light emitting module connects, be used under the control of the timing control signal of input, compensate the threshold voltage of described driving transistors and control described driving transistors that to drive described light emitting module luminous;

Described light emitting module, be connected with the 3rd timing control signal input end, second electrical level signal input part, described driving transistors, described drive control module respectively, be used under the driving of the control of the timing control signal of input and described driving transistors, carrying out luminous.

Preferably, described image element circuit also comprises the touch sensible module, described touch sensible module, be connected with the second timing control signal input end of the first level signal input end, upper level image element circuit, described driving transistors, described drive control module respectively, be used under the timing control signal control of input the touch signal of detecting touch-screen.

Preferably, described touch sensible module comprises:

Sensing device and the 7th transistor;

The first end of described sensing device is connected with described the first level input end, and the second end of described sensing device is connected with the described the 7th transistorized source electrode;

The described the 7th transistorized grid is connected with the second timing control signal input end of described upper level image element circuit, and the described the 7th transistorized drain electrode is connected with node A.

Preferably, described sensing device is photodiode, and described sensing device first end is the negative electrode of described photodiode, and the second end of described sensing device is the anode of described photodiode; Or

Described sensing device is for touching electric capacity, and described sensing device first end and the second end are respectively the two ends of electric capacity.

Preferably, described drive control module comprises:

The first transistor, transistor seconds, the 4th transistor, the 5th transistor, the 8th transistor and memory capacitance;

The source electrode of described the first transistor is connected with described second electrical level signal input part, and the grid of described the first transistor is connected with described the first timing control signal input end, and the drain electrode of described the first transistor is connected with node A;

The source electrode of described transistor seconds is connected with the drain electrode of the described the 8th transistorized drain electrode, described driving transistors, described light emitting module respectively, the grid of described transistor seconds is connected with the second timing control signal input end of described next stage image element circuit, and the drain electrode of described transistor seconds is connected with described node A;

The described the 4th transistorized source electrode is connected with described memory capacitance first end, the first level signal input end respectively, the described the 4th transistorized grid is connected with described the 3rd timing control signal input end, and the described the 4th transistorized drain electrode is connected with the source electrode of the described the 5th transistorized drain electrode, driving transistors respectively;

The described the 5th transistorized source electrode is connected with data line, and the described the 5th transistorized grid is connected with the second timing control signal input end;

The described the 8th transistorized source electrode is connected with described second electrical level signal input part, and the described the 8th transistorized grid is connected with the second timing control signal input end of described upper level image element circuit;

The second end of described memory capacitance is connected with described node A.

Preferably, described light emitting module comprises:

The 3rd transistor and Organic Light Emitting Diode;

The described the 3rd transistorized source electrode is connected with source electrode, the drain electrode of driving transistors, the 8th transistorized drain electrode of described transistor seconds respectively, the described the 3rd transistorized grid is connected the anodic bonding of the described the 3rd transistorized drain electrode and described Organic Light Emitting Diode with described the 3rd timing control signal input end;

The negative electrode of described Organic Light Emitting Diode is connected with described second electrical level signal input part.

Preferably, the grid of described driving transistors is connected with described node A.

Preferably, described driving transistors, the first transistor, transistor seconds, the 3rd transistor, the 4th transistor, the 5th transistor, the 7th transistor and the 8th transistor are the P transistor npn npn;

Described the first level signal input end is connected with high level;

Described second electrical level signal input part is connected with low level.

The utility model embodiment also provides a kind of organic electroluminescence display panel, and this organic electroluminescence display panel specifically can comprise the image element circuit that above-mentioned the utility model embodiment provides.

The utility model embodiment also provides a kind of display device, and this display device specifically can comprise the organic electroluminescence display panel that above-mentioned the utility model embodiment provides.

Can find out from the above, the image element circuit that the utility model provides, organic electroluminescence display panel and display device, by the touch sensible module is set, driving transistors, drive control module, light emitting module, this image element circuit utilizes driving transistors diode connection and discharge to form threshold voltage, the threshold voltage of compensation for drive transistor, so that the threshold voltage of the drive current of driving transistors and driving transistors is irrelevant, thereby make the OLED drive current at diverse location place in the organic electroluminescence display panel consistent, can improve homogeneity and the reliability of organic electroluminescence display panel brightness.

Description of drawings

The image element circuit structure schematic diagram one that Fig. 1 provides for the utility model embodiment;

The image element circuit structure schematic diagram two that Fig. 2 provides for the utility model embodiment;

The image element circuit structure schematic diagram three that Fig. 3 provides for the utility model embodiment;

The pixel circuit drive method schematic flow sheet one that Fig. 4 provides for the utility model embodiment;

The pixel circuit drive method schematic flow sheet two that Fig. 5 provides for the utility model embodiment;

Fig. 6 drives signal timing diagram for the image element circuit that the utility model embodiment provides.

Embodiment

For the purpose, technical scheme and the advantage that make the utility model embodiment is clearer, below in conjunction with the accompanying drawing of the utility model embodiment, the technical scheme of the utility model embodiment is clearly and completely described.Obviously, described embodiment is a part of embodiment of the present utility model, rather than whole embodiment.Based on described embodiment of the present utility model, the every other embodiment that those of ordinary skills obtain belongs to the scope that the utility model is protected.

Unless define in addition, technical term used herein or scientific terminology should be the ordinary meaning that the personage that has general technical ability under the utility model in the field understands." first " of using in the utility model patent application specification and claims, " second " and similar word do not represent any order, quantity or importance, and just are used for distinguishing different ingredients.Equally, " one " or similar words such as " one " do not represent restricted number yet, but there is at least one in expression." connection " or " linking to each other " etc. similarly word be not to be defined in connection physics or machinery, but can comprise electrical connection, no matter be directly or indirectly." on ", D score, " left side ", " right side " etc. only are used for the expression relative position relation, after the absolute position that is described object changed, then this relative position relation also correspondingly changed.

The utility model embodiment provides a kind of image element circuit, and as shown in Figure 1, this image element circuit specifically can comprise:

Driving transistors T6, drive control module 11, light emitting module 12; Wherein:

Driving transistors T6 can be connected with drive control module 11, light emitting module 12 respectively;

Drive control module 11, respectively with the first level signal input end, the second electrical level signal input part, the first timing control signal S1 input end, the second timing control signal S2 input end, the 3rd timing control signal input end S3, the second timing control signal S2_N-1 input end of upper level image element circuit, the second timing control signal S2_N+1 input end of next stage image element circuit, driving transistors T6, light emitting module 12 connects, be used under the control of the timing control signal of input, the threshold voltage of compensation for drive transistor T6 is also controlled driving transistors T6 to drive light emitting module 12 luminous;

Light emitting module 12 is connected with the 3rd timing control signal S3 input end, second electrical level signal input part, driving transistors T6, drive control module 11 respectively, is used under the driving of the control of the timing control signal of input and driving transistors T6 luminous.

The pixel cell that the utility model embodiment provides, so that the threshold voltage vt h of the drive current of driving transistors and driving transistors is irrelevant, thereby make the OLED drive current at diverse location place in the organic electroluminescence display panel consistent, can improve homogeneity and the reliability of organic electroluminescence display panel brightness.

In another specific embodiment of the utility model, as shown in Figure 2, the image element circuit that the utility model embodiment provides specifically can also comprise:

Touch sensible module 13, be connected with the second timing control signal S2_N-1 input end, driving transistors T6, the drive control module 11 of the first level signal input end, upper level image element circuit respectively, be used under the timing control signal control of input the touch signal of detecting touch-screen.

Because touch signal circuit for detecting that can integrated internally-arranged type touch-screen in the pixel cell that provides of the utility model embodiment, thereby realize pixel-driving circuit and the integrated setting of touch signal circuit for detecting, such circuit structure setting, can realize that internally-arranged type touch-screen and Organic Light Emitting Diode drive show integrated, be conducive to reduce thickness and the weight of display panel, and can reduce the cost of display panel.

Among the utility model embodiment, the first timing control signal S1, the second timing control signal S2, the 3rd timing control signal input end S3 specifically can be the timing control signal of image element circuit at the corresponding levels, wherein, the second timing control signal S2 is different timing control signal from the second timing control signal S2_N+1 of the second timing control signal S2_N-1 of upper level image element circuit and next stage image element circuit.

The first related level signal of the utility model embodiment is specifically as follows direct current high level signal VDD, also can be other regularly signals of input high level; And the second electrical level signal can be direct current low level signal VSS, also can be that other can the low level signal of timing output.

In an optional specific embodiment, as shown in Figure 3, Drive and Control Circuit 13 specifically can comprise:

The first transistor T1, transistor seconds T2, the 4th transistor T 4, the 5th transistor T 5, the 8th transistor T 8 and memory capacitance C1.

Wherein:

The source electrode of the first transistor T1 is connected with second electrical level signal (for example VSS) input end, and the grid of the first transistor T1 is connected with the first timing control signal S1 input end, and the drain electrode of the first transistor T1 is connected with described node A;

The source electrode of transistor seconds T2 is connected with drain electrode, the drain electrode of driving transistors T6, the light emitting module 12 of the 8th transistor T 8 respectively, the grid of transistor seconds T2 is connected with the second timing control signal S2_N+1 input end of next stage image element circuit, and the drain electrode of transistor seconds T2 is connected with node A;

The source electrode of the 4th transistor T 4 is connected with memory capacitance C1 first end, the first level signal input end respectively, the grid of the 4th transistor T 4 is connected with the 3rd timing control signal S3 input end, and the drain electrode of the 4th transistor T 4 is connected with the drain electrode of the 5th transistor T 5, the source electrode of driving transistors T6 respectively;

The source electrode of the 5th transistor T 5 is connected with data line (this data line also can be used as the touch signal read line), and the grid of the 5th transistor T 5 is connected with the second timing control signal S2 input end;

The source electrode of the 8th transistor T 8 is connected with the second electrical level signal input part, and the grid of the 8th transistor T 8 is connected with the second timing control signal S2_N-1 input end of upper level image element circuit;

The second end of memory capacitance C1 is connected with node A.

In an optional specific embodiment, as shown in Figure 3, light emitting module 12 specifically can comprise:

The 3rd transistor T 3 and Organic Light Emitting Diode OLED;

The source electrode of the 3rd transistor T 3 is connected with the source electrode of transistor seconds T2, the drain electrode of driving transistors T6, the drain electrode of the 8th transistor T 8 respectively, the grid of the 3rd transistor T 3 is connected the anodic bonding of the drain electrode of the 3rd transistor T 3 and Organic Light Emitting Diode OLED with the 3rd timing control signal S3 input end;

The negative electrode of Organic Light Emitting Diode OLED is connected with the second electrical level signal input part.

In an optional specific embodiment, as shown in Figure 3, the grid of driving transistors T6 is connected with node A.

In an optional specific embodiment, driving transistors T6, the first transistor T1, transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4, the 5th transistor T 5, the 7th transistor T 7 and the 8th transistor T 8 that above-mentioned the utility model embodiment is related, specifically all can be the P transistor npn npn, and the source in the above-mentioned transistor, the drain electrode interchangeable.

The utility model embodiment also provides a kind of pixel circuit drive method that drives the image element circuit that above-mentioned the utility model embodiment provides.As shown in Figure 4, the pixel circuit drive method that provides of the utility model embodiment specifically can comprise:

Step 41, at reseting stage, the first transistor T1, the 5th transistor T 5, the 8th transistor T 8 are in conducting state, transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4 are in cut-off state, and the current potential of drive control module 11 control node A is reset to the voltage of second electrical level signal input part input;

Step 42, in the maintenance stage that resets, the first transistor T1, transistor seconds T2, the 5th transistor T 5 are in conducting state, and the 3rd transistor T 3, the 4th transistor T 4, the 8th transistor T 8 are in cut-off state, and the current potential of drive control module 11 control node A remains unchanged;

Step 43, at compensated stage, transistor seconds T2, the 5th transistor T 5 are in conducting state, the first transistor T1, the 3rd transistor T 3, the 4th transistor T 4, the 8th transistor T 8 are in cut-off state, and the current potential of drive control module 11 control node A is data voltage Vdata and the driving transistors T6 threshold voltage vt h sum of data line input;

Step 44, in the buffer memory stage, transistor seconds T2 is in conducting state, and the first transistor T1, the 3rd transistor T 3, the 4th transistor T 4, the 5th transistor T 5, the 8th transistor T 8 are in cut-off state, and the current potential of drive control module 11 control node A remains unchanged;

Step 45, in glow phase, the 3rd transistor T 3, the 4th transistor T 4 are in conducting state, and the first transistor T1, transistor seconds T2, the 5th transistor T 5, the 8th transistor T 8 are in cut-off state, and drive control module 12 control driving transistors T6 drive light emitting module luminous 13.

The pixel cell driving method that the utility model embodiment provides, can be so that the threshold voltage vt h of the drive current of driving transistors and driving transistors be irrelevant, thereby make the OLED drive current at diverse location place in the organic electroluminescence display panel consistent, can improve homogeneity and the reliability of organic electroluminescence display panel brightness.

In the utility model one optional embodiment, as shown in Figure 5, the pixel circuit drive method that the utility model embodiment provides specifically also comprised the steps: before described reseting stage

Step 51, at initial phase, the first transistor T1, the 7th transistor T 7, the 8th transistor T 8 are in conducting state, transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4, the 5th transistor T 5 are in cut-off state, and the current potential of drive control module 11 control node A is the voltage of second electrical level signal input part input;

Step 52, touching reconnaissance phase, the 5th transistor T 5, the 7th transistor T 7, the 8th transistor T 8 are in conducting state, the first transistor T1, transistor seconds T2, the 3rd transistor T 3, the 5th transistor T 5 are in cut-off state, drive control module 11 exports the current potential of node A to data line so that chip based on this moment node A current potential judge whether touch-screen is touched.

Be that pixel circuit drive method that the utility model embodiment provides can also be realized the detecting to touch signal.

So as seen, the pixel circuit drive method that the utility model embodiment provides specifically can relate to two processes:

1, touch screen signal detecting process;

2, OLED threshold voltage compensation and pixel driver process.

And in one embodiment, in the specific implementation flow process of the image element driving method that the utility model embodiment provides, can carry out first touch screen signal detecting process, carry out OLED threshold voltage compensation and driving process.

In addition, also the execution sequence of above-mentioned two processes can be put upside down.

Below, the sequential chart shown in 6 by reference to the accompanying drawings, the specific implementation process of the pixel circuit drive method that the utility model embodiment is provided is described.

Among this embodiment, the first level signal is VDD, and the second electrical level signal is VSS, and sensing device is photodiode PD.

The specific implementation process of this embodiment can comprise:

At initial phase, the first timing control signal S1 is low level, the second timing control signal S2_N-1 of upper level image element circuit is low level, the second timing control signal S2 is high level, the second timing control signal S2_N+1 of next stage image element circuit is high level, and the 3rd timing control signal S3 is high level.In this stage, the first transistor T1, the 7th transistor T 7, the 8th transistor T 8 all are in conducting state so, and transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4, the 5th transistor T 5 all are in cut-off state.Because the first transistor T1 conducting, then node A point directly connects VSS, then the current potential V of node A _A=VSS.At this moment, the voltage of capacitor C 1 is V _C1=VDD-VSS.

Touching reconnaissance phase, the first timing control signal S1 is high level, the second timing control signal S2_N-1 of upper level image element circuit is low level, the second timing control signal S2 is low level, the second timing control signal S2_N+1 of next stage image element circuit is high level, and the 3rd timing control signal S3 is high level.In this stage, the 5th transistor T 5, the 7th transistor T 7, the 8th transistor T 8 all are in conducting state so, and the first transistor T1, transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4 all are in cut-off state.So this moment, linked to each other with photodiode PD through the 7th transistor T 7 in node A o'clock.Because photodiode PD is no touch (under the illumination) different with the electric leakage when touch (under the shade) is arranged (electric leakage the when electric leakage of photodiode is than unglazed photograph under the illumination is large).Photodiode PD is in no touch with have electric leakage when touching to change will to cause that the voltage that node A is ordered changes so.After the variation of node A point voltage is amplified by the first transistor T1, (read line specifically can be data line data line, namely among the utility model embodiment through read line, read line and data line can share) deliver to the IC chip and detect parsing, confirm whether this position has touch.

At reseting stage, the first timing control signal S1 is low level, the second timing control signal S2_N-1 of upper level image element circuit is low level, the second timing control signal S2 is low level, the second timing control signal S2_N+1 of next stage image element circuit is high level, and the 3rd timing control signal S3 is high level.In this stage, the first transistor T1, the 5th transistor T 5, the 7th transistor T 7, the 8th transistor T 8 all are in conducting state so, and transistor seconds T2, the 3rd transistor T 3, the 4th transistor T 4 all are in cut-off state.So this moment, the current potential that node A is ordered is reset to VSS, eliminates the impact that touches on last stage.

In the maintenance stage that resets, the first timing control signal S1 is low level, the second timing control signal S2_N-1 low level of upper level image element circuit, the second timing control signal S2 is low level, the second timing control signal S2_N+1 of next stage image element circuit is high level, and the 3rd timing control signal S3 is high level.So in this stage, the first transistor T1, transistor seconds T2, the 5th transistor T 5 are in conducting state, the 3rd transistor T 3, the 4th transistor T 4, the 7th transistor T 7, the 8th transistor T 8 all are in cut-off state, the current potential that node A is ordered is kept and is reset to VSS, continues to eliminate the impact that touches on last stage.

At compensated stage, the first timing control signal S1 is high level, the second timing control signal S2_N-1 high level of upper level image element circuit, the second timing control signal S2 is low level, the second timing control signal S2_N+1 of next stage image element circuit is low level, and the 3rd timing control signal S3 is high level.In this stage, transistor seconds T2, the 5th transistor T 5 are in conducting state so, and the first transistor T1, the 3rd transistor T 3, the 4th transistor T 4, the 7th transistor T 7, the 8th transistor T 8 are in cut-off state.Because the T5 conducting, then data voltage (Vdata) is written into.Because transistor seconds T2 is in conducting state, so this moment, the grid leak short circuit of driving transistors T6, driving transistors T6 are essentially a diode and enter state of saturation.The gate source voltage Vgs=V of driving transistors T6 _ATherefore-Vdata=Vth is V _A=Vdata+Vth, the voltage at capacitor C 1 two ends is VC1=VDD-V _A=VDD-Vdata-Vth.

In the buffer memory stage, the first timing control signal S1 is high level, the second timing control signal S2_N-1 high level of upper level image element circuit, the second timing control signal S2 is high level, the second timing control signal S2_N+1 of next stage image element circuit is low level, and the 3rd timing control signal S3 is high level.In this stage, transistor seconds T2 is in conducting state so, and the first transistor T1, the 3rd transistor T 3, the 4th transistor T 4, the 5th transistor T 5, the 7th transistor T 7, the 8th transistor T 8 are in cut-off state, buffer stage.S1 is high level, and S2_N-1 is high level, and S2 is high level, and S2_N+1 is low level.Because the source electrode unsettled (floating) of driving transistors T6 does not have current path, according to charge conservation, does not have increase and the minimizing of electric charge at node A, therefore the voltage of node A remains unchanged V _A=Vdata+Vth, the voltage at capacitor C 1 two ends remains VC1=VDD-V _A=VDD-Vdata-Vth.

In glow phase, the first timing control signal S1 is high level, the second timing control signal S2_N-1 high level of upper level image element circuit, the second timing control signal S2 is high level, the second timing control signal S2_N+1 of next stage image element circuit is high level, and the 3rd timing control signal S3 is low level.So in this stage, the 3rd transistor T 3, the 4th transistor T 4 are in conducting state, the first transistor T1, transistor seconds T2, the 5th transistor T 5, the 7th transistor T 7, the 8th transistor T 8 are in cut-off state, drive control module 12 utilizes the voltage at capacitor C 1 two ends to make driving transistors T6 conducting, and OLED begins luminous.Because it is node A that the grid of driving transistors T6 is connected directly to the second end of capacitor C 1, the gate source voltage Vgs=V of driving transistors T6 _A-Vth_oled=Vdata+Vth-Vth_oled, wherein, Vth_oled is the pressure drop on the OELD, then flows through the electric current of OLED this moment to be:

I=K（Vgs-Vth） ²=K（Vdata+Vth-Vth_oled-Vth） ²=K(Vdata-Vth_oled) ²

Wherein, K is with technique and drives the relevant constant of design

So as seen, because the image element circuit structure that the utility model embodiment provides is under clock signal control, the drive current of OLED and the threshold voltage of driving transistors are irrelevant, therefore can make the OLED drive current at diverse location place in the organic electroluminescence display panel consistent, can improve homogeneity and the reliability of organic electroluminescence display panel brightness.

Based on the image element circuit that the utility model embodiment provides, the utility model embodiment also provides a kind of organic electroluminescence display panel, and this organic electroluminescence display panel specifically can comprise the pixel electrode that above-mentioned the utility model embodiment provides.

The utility model embodiment also provides a kind of display device, and this display device specifically can comprise the organic electroluminescence display panel that above-mentioned the utility model embodiment provides.

This display device is specifically as follows the display device such as liquid crystal panel, LCD TV, liquid crystal display, oled panel, OLED display, plasma display or Electronic Paper.

Image element circuit described in the utility model, organic electroluminescence display panel and display device are particularly suitable for LTPS(low temperature polycrystalline silicon technology) GOA circuit requirements under the processing procedure, also applicable to the GOA circuit under the amorphous silicon technology.

Can find out from the above, the image element circuit that the utility model embodiment provides, organic electroluminescence display panel and display device, by touch sensible module, driving transistors, drive control module, light emitting module are set, wherein the touch sensible module is used for the touch signal that the detecting touch-screen produces, drive control module is used for the timing control signal according to input, and it is luminous that the control driving transistors drives light emitting module.Thereby realize that internally-arranged type touch-screen and Organic Light Emitting Diode drive show integrated, are conducive to reduce thickness and the weight of display panel, and can reduce the cost of display panel.And, this image element circuit utilizes driving transistors diode connection and discharge to form threshold voltage vt h, the threshold voltage vt h of compensation for drive transistor, so that the threshold voltage vt h of the drive current of driving transistors and driving transistors is irrelevant, thereby make the OLED drive current at diverse location place in the organic electroluminescence display panel consistent, can improve homogeneity and the reliability of organic electroluminescence display panel brightness.Simultaneously, the technical scheme that the utility model embodiment provides specifically has control signal few, and sequential is simple, the advantage that circuit is easy to realize.

Be pointed out that, although in above-described embodiment, be illustrated as an example of single employing P type thin film transistor (TFT) example, yet foregoing circuit can also adopt single N-type thin film transistor (TFT) or CMOS pipe circuit easily instead; In addition, touch controllable function partly can also be removed, change this driving touch-control circuit into pure pixel light emission drive circuit.And, although be illustrated as an example of active matrix organic light-emitting diode example in above-described embodiment, yet the utility model is not limited to use the display device of active matrix organic light-emitting diode, also can be applied to use the display device of other various light emitting diodes.

The above only is embodiment of the present utility model; should be pointed out that for those skilled in the art, under the prerequisite that does not break away from the utility model principle; can also make some improvements and modifications, these improvements and modifications also should be considered as protection domain of the present utility model.

Claims (10)

1. an image element circuit is characterized in that, comprises driving transistors, drive control module, light emitting module; Wherein:

Described driving transistors is connected with described drive control module, described light emitting module respectively;

Described drive control module, respectively with the first level signal input end, the second electrical level signal input part, the first timing control signal input end, the second timing control signal input end, the 3rd timing control signal input end, the second timing control signal input end of upper level image element circuit, the second timing control signal input end of next stage image element circuit, described driving transistors, described light emitting module connects, be used under the control of the timing control signal of input, compensate the threshold voltage of described driving transistors and control described driving transistors that to drive described light emitting module luminous;

Described light emitting module, be connected with the 3rd timing control signal input end, second electrical level signal input part, described driving transistors, described drive control module respectively, be used under the driving of the control of the timing control signal of input and described driving transistors, carrying out luminous.

2. image element circuit as claimed in claim 1, it is characterized in that, also comprise the touch sensible module, described touch sensible module, be connected with the second timing control signal input end of the first level signal input end, upper level image element circuit, described driving transistors, described drive control module respectively, be used under the timing control signal control of input the touch signal of detecting touch-screen.

3. image element circuit as claimed in claim 2 is characterized in that, described touch sensible module comprises:

Sensing device and the 7th transistor;

The first end of described sensing device is connected with described the first level input end, and the second end of described sensing device is connected with the described the 7th transistorized source electrode;

The described the 7th transistorized grid is connected with the second timing control signal input end of described upper level image element circuit, and the described the 7th transistorized drain electrode is connected with node A.

4. image element circuit as claimed in claim 3 is characterized in that, described sensing device is photodiode, and described sensing device first end is the negative electrode of described photodiode, and the second end of described sensing device is the anode of described photodiode; Or

Described sensing device is for touching electric capacity, and described sensing device first end and the second end are respectively the two ends of electric capacity.

5. image element circuit as claimed in claim 3 is characterized in that, described drive control module comprises:

The first transistor, transistor seconds, the 4th transistor, the 5th transistor, the 8th transistor and memory capacitance;

The source electrode of described the first transistor is connected with described second electrical level signal input part, and the grid of described the first transistor is connected with described the first timing control signal input end, and the drain electrode of described the first transistor is connected with node A;

The source electrode of described transistor seconds is connected with the drain electrode of the described the 8th transistorized drain electrode, described driving transistors, described light emitting module respectively, the grid of described transistor seconds is connected with the second timing control signal input end of described next stage image element circuit, and the drain electrode of described transistor seconds is connected with described node A;

The described the 4th transistorized source electrode is connected with described memory capacitance first end, the first level signal input end respectively, the described the 4th transistorized grid is connected with described the 3rd timing control signal input end, and the described the 4th transistorized drain electrode is connected with the source electrode of the described the 5th transistorized drain electrode, driving transistors respectively;

The described the 5th transistorized source electrode is connected with data line, and the described the 5th transistorized grid is connected with the second timing control signal input end;

The described the 8th transistorized source electrode is connected with described second electrical level signal input part, and the described the 8th transistorized grid is connected with the second timing control signal input end of described upper level image element circuit;

The second end of described memory capacitance is connected with described node A.

6. image element circuit as claimed in claim 5 is characterized in that, described light emitting module comprises:

The 3rd transistor and Organic Light Emitting Diode;

The described the 3rd transistorized source electrode is connected with source electrode, the drain electrode of driving transistors, the 8th transistorized drain electrode of described transistor seconds respectively, the described the 3rd transistorized grid is connected the anodic bonding of the described the 3rd transistorized drain electrode and described Organic Light Emitting Diode with described the 3rd timing control signal input end;

The negative electrode of described Organic Light Emitting Diode is connected with described second electrical level signal input part.

7. image element circuit as claimed in claim 6 is characterized in that, the grid of described driving transistors is connected with described node A.

8. image element circuit as claimed in claim 7 is characterized in that, described driving transistors, the first transistor, transistor seconds, the 3rd transistor, the 4th transistor, the 5th transistor, the 7th transistor and the 8th transistor are the P transistor npn npn;

Described the first level signal input end is connected with high level;

Described second electrical level signal input part is connected with low level.

9. an organic electroluminescence display panel is characterized in that, comprises each image element circuit of described claim 1-8.

10. a display device is characterized in that, comprises organic electroluminescence display panel as claimed in claim 9.

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