CN203931451U - Image element circuit and display device - Google Patents

Abstract

The utility model provides a kind of image element circuit and display device.Described image element circuit, comprises multirow pixel cell, and every a line pixel cell comprises a plurality of sub-pixel unit; Each sub-pixel unit comprises sub-pixel driving circuit and light-emitting component, and every a line pixel cell also comprises row sharing unit; A plurality of sub-pixel unit are all connected with secondary signal line with first signal line; Each sub-pixel unit that this row sharing unit comprises with this row pixel cell is connected with secondary signal line by first signal line, to have valve value compensation function.Fundamental purpose of the present utility model is to provide a kind of image element circuit and display device, and the utility model increases the aperture opening ratio of pixel, when obtaining evenly demonstration, reduces the current density of organic luminous layer.

Description

Image element circuit and display device

Technical field

The utility model relates to display technique field, relates in particular to image element circuit and display device.

Background technology

Basic AMOLED (Active Matrix/Organic Light Emitting Diode, active matrix organic light-emitting diode) pixel-driving circuit is 2T1C pixel-driving circuit, simple in structure.But based on LTPS (Low Temperature Poly-silicon, low temperature polycrystalline silicon technology) AMOLED pixel-driving circuit, because LTPS exists the problems such as threshold voltage homogeneity is poor, so need to increase the circuit of drive TFT (Thin Film Transistor, Thin Film Transistor (TFT)) threshold voltage compensation in the Pixel Design of AMOLED.The common design with the AMOLED pixel-driving circuit of threshold voltage compensation needs 6T1C pixel-driving circuit or 5T2C pixel-driving circuit, or need more TFT and/electric capacity.The increase of TFT and/or electric capacity quantity, will take larger arrangement space, is unfavorable for dwindling of AMOLED Pixel Dimensions, has limited the development of the AMOLED pixel-driving circuit of high PPI (Pixel Per Inch, the number of pixels that per inch has).

Utility model content

Fundamental purpose of the present utility model is to provide a kind of image element circuit and display device, increases the aperture opening ratio of pixel, thereby when obtaining evenly demonstration, reduces the current density of organic luminous layer.

In order to achieve the above object, the utility model provides a kind of image element circuit, comprises multirow pixel cell, and every a line pixel cell comprises a plurality of sub-pixel unit; Described in each, sub-pixel unit comprises sub-pixel driving circuit and light-emitting component, and this sub-pixel driving circuit comprises the driving transistors being connected with described light-emitting component and the drive control module being connected with this driving transistors with a data line respectively; Every a line pixel cell also comprises row sharing unit;

Described a plurality of sub-pixel unit is all connected with secondary signal line with first signal line;

Each sub-pixel unit that described row sharing unit comprises with this row pixel cell is connected with described secondary signal line by described first signal line.

During enforcement, described sub-pixel unit is arranged in effective display area, and described row sharing unit is arranged at outside effective display area.

During enforcement, described driving transistors, first utmost point is connected with the first end of described light-emitting component, and second utmost point is connected with described first signal line; The second end of described light-emitting component is connected with described secondary signal line;

Described row sharing unit comprises:

The light emitting control module of the initial module of access initial control signal and access LED control signal;

Be used for accessing initial control signal, and the sweep signal on described initial control signal and sweep trace is set to the initial module of original levels simultaneously effectively time by the grid potential of the described driving transistors of described drive control module, be connected with described first signal line;

And, for accessing LED control signal, and when described LED control signal is effective, control the light emitting control module that described first signal line accesses the first level described secondary signal line access second electrical level;

Described drive control module comprises: for when described sweep signal is effective, the data voltage of controlling on described data line writes described driving transistors, when described LED control signal is effective, control described driving transistors and drive described light-emitting component luminous and compensate the driving control unit of the threshold value of this driving transistors, be connected with described sweep trace with the grid of this driving transistors, second utmost point of first utmost point of this driving transistors, this driving transistors respectively.

During enforcement, described driving control unit comprises that data write transistor, drive control transistor and memory capacitance, wherein,

Described data write transistor, and grid is connected with described sweep trace, and first utmost point is connected with described data line, and second utmost point is connected with first utmost point of described driving transistors;

Described drive control transistor, grid is connected with described sweep trace, and first utmost point is connected with the grid of described driving transistors, and second utmost point is connected with second utmost point of described driving transistors;

Described memory capacitance, first end is connected with first utmost point of described driving transistors, and the second end is connected with the grid of described driving transistors.

During enforcement, described initial module comprises:

Initialization transistor, grid accesses described initial control signal, and first utmost point is connected with described secondary signal line, the second utmost point access original levels.

During enforcement, described light emitting control module comprises:

The first light emitting control transistor, grid accesses described LED control signal, and first utmost point accesses the first level, and second utmost point is connected with described first signal line;

The second light emitting control transistor, grid accesses described LED control signal, and first utmost point is connected with described secondary signal line, and second utmost point accesses described second electrical level.

The utility model also provides a kind of display device, it is characterized in that, comprises above-mentioned image element circuit.

Compared with prior art, image element circuit described in the utility model adopts row sharing unit, so that can make the TFT decreased number in effective display area in the threshold value of compensation for drive transistor, the aperture opening ratio of pixel is increased, thereby when evenly showing, reduce the current density of organic luminous layer, extended the serviceable life of AMOLED panel.

Accompanying drawing explanation

Fig. 1 is the structural drawing of the image element circuit described in the utility model embodiment;

Fig. 2 is the sub-pixel unit that comprises of the image element circuit described in the utility model embodiment and the structured flowchart of row sharing unit;

Fig. 3 is the sub-pixel unit that comprises of the image element circuit described in the utility model embodiment and the circuit diagram of row sharing unit;

Fig. 4 comprises sub-pixel unit as shown in Figure 3 and the working timing figure of row sharing unit;

Fig. 5 is the circuit diagram of the image element circuit described in the utility model embodiment.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, the technical scheme in the utility model embodiment is clearly and completely described, obviously, described embodiment is only the utility model part embodiment, rather than whole embodiment.Embodiment based in the utility model, those of ordinary skills are not making the every other embodiment obtaining under creative work prerequisite, all belong to the scope of the utility model protection.

The transistor adopting in all embodiment of the utility model can be all thin film transistor (TFT) or field effect transistor or the identical device of other characteristics.In the utility model embodiment, for distinguishing transistor the two poles of the earth except grid, wherein first can be extremely source electrode or drain electrode, and second can be extremely drain electrode or source electrode.In addition, according to transistorized characteristic, distinguish and transistor can be divided into N-shaped transistor or p-type transistor.In the driving circuit providing at the utility model embodiment; all crystals Guan Jun be take the explanation that N-shaped transistor carries out as example; what can expect is that those skilled in the art can expect easily not making under creative work prerequisite when adopting p-type transistor to realize, therefore also in embodiment protection domain of the present utility model.

Image element circuit described in the utility model embodiment, comprises multirow pixel cell, and every a line pixel cell comprises a plurality of sub-pixel unit; Described in each, sub-pixel unit comprises sub-pixel driving circuit and light-emitting component, and this sub-pixel driving circuit comprises the driving transistors being connected with described light-emitting component and the drive control module being connected with this driving transistors with a data line respectively; Every a line pixel cell also comprises row sharing unit;

Described a plurality of sub-pixel unit is all connected with secondary signal line with first signal line;

Each sub-pixel unit that this row sharing unit comprises with this row pixel cell is connected with described secondary signal line by described first signal line, to have valve value compensation function.

In the image element circuit described in this embodiment of the utility model, in sub-pixel unit, except comprising sub-pixel driving circuit, also comprise light-emitting component, sub-pixel driving circuit forms sub-pixel unit together with light-emitting component, and this light-emitting component can be for example OLED (Organic Light Emitting Diode).

Image element circuit described in this embodiment of the utility model adopts row sharing unit, so that can make the TFT decreased number in effective display area in the threshold value of compensation for drive transistor, the aperture opening ratio of pixel is increased, thereby when evenly showing, reduce the current density of organic luminous layer, extended the serviceable life of AMOLED panel.

Preferably, described sub-pixel unit is arranged in effective display area, and described row sharing unit is arranged at outside effective display area, and the circuit with general character in every a line pixel cell is arranged at outside effective display area, further to reduce the TFT number in effective display area, increase aperture opening ratio.

Concrete, the image element circuit described in the utility model embodiment, comprises the capable pixel cell of m, and every a line pixel cell comprises n sub-pixel unit; N the sub-pixel unit that the capable pixel cell of j comprises is all connected (in Fig. 1, not showing) with j sweep trace; The k sub-pixel unit that every a line pixel cell comprises is all connected with k data line; M and n are greater than 1 integer, and j is the positive integer that is less than or equal to m, and k is the positive integer that is less than or equal to n;

As shown in Figure 1, Vdata_1 is the data voltage of the first data line output, and Vdata_k-1 is the data voltage of k-1 data line output, and Vdata_k is the data voltage of k data line output, the data voltage of Vdata_k+1 data line output, Vdata_n is the data voltage of n data line output;

Described in each, sub-pixel unit comprises sub-pixel driving circuit and light-emitting component, and this sub-pixel driving circuit comprises the driving transistors being connected with described light-emitting component and the drive control module being connected with this driving transistors with a data line respectively;

Every a line pixel cell also comprises row sharing unit; M row sharing unit forms row common circuit;

A plurality of sub-pixel unit that every a line image element circuit comprises are all connected with secondary signal line with first signal line;

Each sub-pixel unit that this row sharing unit comprises with this row pixel cell is connected with described secondary signal line by described first signal line, to have valve value compensation function;

Described sub-pixel unit is arranged in effective display area, and described row sharing unit is arranged at outside effective display area;

In Fig. 1, V1_1 is the first signal line of the first row image element circuit, V2_1 is the secondary signal line of the first row image element circuit, V1_j-1 is the first signal line of the capable image element circuit of j-1, V2_j-1 is the secondary signal line of the capable image element circuit of j-1, V1_j is the first signal line of the capable image element circuit of j, V2_j is the secondary signal line of the capable image element circuit of j, V1_j+1 is the first signal line of the capable image element circuit of j+1, V2_j+1 is the secondary signal line of the capable image element circuit of j+1, V1_m is the first signal line of the capable image element circuit of m, V2_m is the secondary signal line of the capable image element circuit of m.

Preferably, described driving transistors, first utmost point is connected with the first end of described light-emitting component, and second utmost point is connected with described first signal line; The second end of described light-emitting component is connected with described secondary signal line;

Described row sharing unit comprises:

The light emitting control module of the initial module of access initial control signal and access LED control signal;

Be used for accessing initial control signal, and the sweep signal on described initial control signal and sweep trace is set to the initial module of original levels simultaneously effectively time by the grid potential of the described driving transistors of described drive control module, be connected with described first signal line;

And, for accessing LED control signal, and when described LED control signal is effective, control the light emitting control module that described first signal line accesses the first level described secondary signal line access second electrical level;

Described drive control module comprises: for when described sweep signal is effective, the data voltage of controlling on described data line writes described driving transistors, when described LED control signal is effective, control described driving transistors and drive described light-emitting component luminous and compensate the driving control unit of the threshold value of this driving transistors, be connected with described sweep trace with the grid of this driving transistors, second utmost point of first utmost point of this driving transistors, this driving transistors respectively.

Preferably, described driving control unit comprises that data write transistor, drive control transistor and memory capacitance, wherein,

Described data write transistor, and grid is connected with described sweep trace, and first utmost point is connected with described data line, and second utmost point is connected with first utmost point of described driving transistors;

Described drive control transistor, grid is connected with described sweep trace, and first utmost point is connected with the grid of described driving transistors, and second utmost point is connected with second utmost point of described driving transistors;

Described memory capacitance, first end is connected with first utmost point of described driving transistors, and the second end is connected with the grid of described driving transistors.

Preferably, described initial module comprises:

Initialization transistor, grid accesses described initial control signal, and first utmost point is connected with described secondary signal line, the second utmost point access original levels.

Preferably, described light emitting control module comprises:

The first light emitting control transistor, grid accesses described LED control signal, and first utmost point accesses the first level, and second utmost point is connected with described first signal line;

The second light emitting control transistor, grid accesses described LED control signal, and first utmost point is connected with described secondary signal line, and second utmost point accesses described second electrical level.

Concrete, with the example that is connected to of a sub-pixel unit and row sharing unit, be described as follows:

As shown in Figure 2, described sub-pixel unit comprises sub-pixel driving circuit and Organic Light Emitting Diode OLED, this sub-pixel driving circuit comprise the driving transistors DTFT that is connected with OLED with respectively with the grid of a data line Data, this driving transistors DTFT, the drive control module 21 that second utmost point of first utmost point of this driving transistors DTFT and this driving transistors DTFT is connected;

Described driving transistors DTFT, the anodic bonding of first utmost point and OLED, second utmost point is connected with first signal line V1;

The negative electrode of OLED is connected with described secondary signal line V2;

Described drive control module 21 also accesses the sweep signal Vscan on one scan line;

Described row sharing unit comprises the initial module 22 of access initial control signal CN and the light emitting control module 23 of access LED control signal EM;

Described initial module 22, be connected with described first signal line V1, the grid potential by the described driving transistors DTFT of described drive control module 21 when effective for the sweep signal Vscan while on described initial control signal CN and described sweep trace is set to original levels VINI;

Described light emitting control module 23, for control described first signal line V1 access high level VDD described secondary signal line V2 access low level VSS when LED control signal CN is effective, the first level is high level VDD, second electrical level is low level VSS;

Described drive control module 21, for when described sweep signal Vscan is effective, the data voltage Vdata controlling on described data line writes described driving transistors DTFT, controls described driving transistors DTFT driving OLED luminous and compensate the threshold value of this driving transistors DTFT when described LED control signal EM is effective.

Concrete, as shown in Figure 3, described drive control module can comprise that data write transistor T I, drive control transistor TC and memory capacitance Cs, wherein,

Described data write transistor T I, and grid accesses described sweep signal Vscan, and first utmost point accesses the data voltage Vdata on described data line, and second utmost point is connected with first utmost point of described driving transistors DTFT;

Described drive control transistor DTFT, grid accesses described sweep signal Vscan, and first utmost point is connected with the grid of described driving transistors DTFT, and second utmost point is connected with second utmost point of described driving transistors DTFT;

Described memory capacitance Cs, first end is connected with first utmost point of described driving transistors DTFT, and the second end is connected with the grid of described driving transistors DTFT;

Described initial module comprises:

Initialization transistor TINI, grid accesses described initial control signal CN, and first utmost point is connected with described secondary signal line V2, the second utmost point access original levels VINI;

Described light emitting control module comprises:

The first light emitting control transistor T EC1, grid accesses described LED control signal EM, the first utmost point access high level VDD, second utmost point is connected with described first signal line V1;

The second light emitting control transistor T EC2, grid accesses described LED control signal EM, and first utmost point is connected with described secondary signal line V2, the second utmost point access low level VSS;

DTFT, TI, TC, TINI, TEC1 and TEC2 are N-shaped TFT.

In embodiment as shown in Figure 3, the sub-pixel unit that comprises DTFT, TI, TC, Cs and OLED is arranged in effective display area, comprise outside the setting of row sharing unit and effective display area of TEC1, TEC2 and TINI, and a plurality of sub-pixel unit with a line pixel cell are all connected with described row sharing unit, to have valve value compensation function.

In the specific implementation, be not limited in above embodiment, only need to adopt row sharing unit can reach the object that reduces the TFT in effective display area, can be so that Pixel Dimensions dwindles.

The time sequential routine of embodiment as shown in Figure 3, (Vdata was data voltage as shown in Figure 4, what represent is the information of image, the voltage of output is image-related with soon demonstration, image is uncertain, data are also just uncertain, therefore the output level of Vdata is filled and is represented with trellis), be divided into three phases:

Stage A (initial phase): Vscan and CN are high level, EM is low level, TI, TC and TINI conducting, TEC1 and TEC2 cut-off, Vdata writes by TI, and the voltage on V1 is VINI, voltage on V2 is floating empty voltage, the drain electrode of DTFT (second utmost point) is connected with the grid of DTFT, and the grid potential of DTFT is initialization level VINI, and the source electrode of DTFT (first utmost point) current potential is Vdata;

Stage B (compensated stage): Vscan is high level, CN and EM are low level, TI and TC conducting, TINI, TEC1 and TEC2 cut-off, the drain electrode of DTFT (second utmost point) is connected with the grid of DTFT, the source electrode of DTFT (first utmost point) access Vdata, DTFT forms diode and connects, the grid potential of DTFT is discharged to Vdata+Vth (threshold value that Vth is DTFT) from initialization level VINI, the current potential that is the second end of Cs is Vdata+Vth, and now the voltage on V1 is Vdata+Vth, the voltage on V2 is floating empty voltage;

Stage C (glow phase), Vscan and CN are low level, EM is high level, be TI, TC and TINI cut-off, TEC1 and TEC2 conducting, voltage on V1 becomes high level VDD, V2 becomes low level VSS from upper voltage from floating empty voltage, the grid potential of DTFT is by remaining Vdata+Vth at memory capacitance Cs (because the second end of Cs is now floating empty, so the discharge path of Cs is turned off, therefore the current potential of the second end of Cs is that the grid potential of DTFT is kept by Cs), now the source electrode of DTFT (first utmost point) current potential is VSS, therefore flows through the source-drain current I of DTFT _dS=K * (V _data+ Vth-VSS-Vth) ²=K * (V _data-VSS) ², K is the constant relevant with design to technique, the last electric current of driving OLED and the threshold voltage of DTFT are irrelevant, only relevant with Vdata.

Fig. 5 is the circuit diagram of having applied the image element circuit of the sub-pixel unit shown in Fig. 3 and row sharing unit, as shown in Figure 5, every a line pixel cell shares the row sharing unit in left side, m row sharing unit forms row common circuit, the initial control signal of the row sharing unit of the first row image element circuit is CN_1, sweep signal Vscan_1, LED control signal EM_1, the initial control signal of the row sharing unit of the capable image element circuit of j is CN_j, sweep signal Vscan_j, LED control signal EM_j, the initial control signal of the row sharing unit of the capable image element circuit of j+1 is CN_j+1, sweep signal Vscan_j+1, LED control signal EM_j+1, the initial control signal of the row sharing unit of the capable image element circuit of m is CN_m, sweep signal Vscan_m, LED control signal EM_m, wherein j is the positive integer that is less than or equal to m.

Display device described in the utility model embodiment comprises above-mentioned image element circuit.Described display device can comprise liquid crystal indicator, for example liquid crystal panel, LCD TV, mobile phone, liquid crystal display.Except liquid crystal indicator, described display device can also comprise the display device of organic light emitting display or other types, such as electronic reader etc.

More than illustrate the utility model just illustrative; and it is nonrestrictive; those of ordinary skills understand; in the situation that do not depart from the spirit and scope that claims limit; can make many modifications, variation or equivalence, but all will fall in protection domain of the present utility model.

Claims (7)

1. an image element circuit, comprises multirow pixel cell, and every a line pixel cell comprises a plurality of sub-pixel unit; Described in each, sub-pixel unit comprises sub-pixel driving circuit and light-emitting component, and this sub-pixel driving circuit comprises the driving transistors being connected with described light-emitting component and the drive control module being connected with this driving transistors with a data line respectively; It is characterized in that, every a line pixel cell also comprises row sharing unit;

Described a plurality of sub-pixel unit is all connected with secondary signal line with first signal line;

Each sub-pixel unit that described row sharing unit comprises with this row pixel cell is connected with described secondary signal line by described first signal line.

2. image element circuit as claimed in claim 1, is characterized in that,

Described sub-pixel unit is arranged in effective display area, and described row sharing unit is arranged at outside effective display area.

3. image element circuit as claimed in claim 1, is characterized in that,

Described driving transistors, first utmost point is connected with the first end of described light-emitting component, and second utmost point is connected with described first signal line; The second end of described light-emitting component is connected with described secondary signal line;

Described row sharing unit comprises:

The light emitting control module of the initial module of access initial control signal and access LED control signal;

Be used for accessing initial control signal, and the sweep signal on described initial control signal and sweep trace is set to the initial module of original levels simultaneously effectively time by the grid potential of the described driving transistors of described drive control module, be connected with described first signal line;

And, for accessing LED control signal, and when described LED control signal is effective, control the light emitting control module that described first signal line accesses the first level described secondary signal line access second electrical level;

Described drive control module comprises: for when described sweep signal is effective, the data voltage of controlling on described data line writes described driving transistors, when described LED control signal is effective, control described driving transistors and drive described light-emitting component luminous and compensate the driving control unit of the threshold value of this driving transistors, be connected with described sweep trace with the grid of this driving transistors, second utmost point of first utmost point of this driving transistors, this driving transistors respectively.

4. image element circuit as claimed in claim 3, is characterized in that, described driving control unit comprises that data write transistor, drive control transistor and memory capacitance, wherein,

Described data write transistor, and grid is connected with described sweep trace, and first utmost point is connected with described data line, and second utmost point is connected with first utmost point of described driving transistors;

Described drive control transistor, grid is connected with described sweep trace, and first utmost point is connected with the grid of described driving transistors, and second utmost point is connected with second utmost point of described driving transistors;

Described memory capacitance, first end is connected with first utmost point of described driving transistors, and the second end is connected with the grid of described driving transistors.

5. image element circuit as claimed in claim 4, is characterized in that, described initial module comprises:

Initialization transistor, grid accesses described initial control signal, and first utmost point is connected with described secondary signal line, the second utmost point access original levels.

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

The first light emitting control transistor, grid accesses described LED control signal, and first utmost point accesses the first level, and second utmost point is connected with described first signal line;

The second light emitting control transistor, grid accesses described LED control signal, and first utmost point is connected with described secondary signal line, and second utmost point accesses described second electrical level.

7. a display device, is characterized in that, comprises the image element circuit as described in arbitrary claim in claim 1 to 6.