KR102199942B1 - Pmoled display device and pmoled display method for reducing flicker having brightness linearity - Google Patents

Abstract

Disclosed are a PMOLED display device and a PMOLED display method for reducing flicker while maintaining luminance linearity. In the PMOLED display device and method of the present invention, a unit frame consists of a plurality of sub-frames, and a corresponding pixel is driven in as many sub-frames as possible. In this case, when data value of the driving data corresponds to high luminance, the corresponding pixel is driven by a ′PWM driving method′. And, when the data value of the driving data corresponds to a low luminance, the corresponding pixel is driven a plurality of times with a driving current smaller than a unit current. Accordingly, according to the PMOLED display device and method of the present invention, a flicker phenomenon is greatly alleviated even when the data value of driving data corresponds to low luminance while maintaining the linearity of the luminance.

Description

PMOLED display device and PMOLED display method that reduces flicker while maintaining luminance linearity {PMOLED DISPLAY DEVICE AND PMOLED DISPLAY METHOD FOR REDUCING FLICKER HAVING BRIGHTNESS LINEARITY}

The present invention relates to a PMOLED display device and a PMOLED display method, and more particularly, to a PMOLED display device and a PMOLED display method for reducing flicker while maintaining luminance linearity.

In general, a display panel of a PMOLED display device includes a plurality of pixels arranged on a matrix structure consisting of gate lines and data lines. In addition, the plurality of pixels display one image in one unit frame by generating light according to their respective driving data.

In this case, each of the plurality of pixels includes a light emitting diode, and when a corresponding gate line is selected, light according to the total amount of current supplied from its own data line is generated. Further, the gate lines are sequentially selected during one frame.

As a driving method of such a PMOLED display device, there are so-called'PWM driving method' and'PAM driving method'. The'PWM driving method' is a method of controlling a pixel driving time, that is, the number of unit connection times, according to a data value of driving data while a constant amount of current flows through a light emitting diode of a pixel. In addition, the'PAM driving method' is a method in which the driving time of the light emitting diode is constant and the magnitude of the driving current according to the data value is adjusted.

In general, the'PWM driving method' is widely used because of the advantage that the linearity of luminance according to the data value of the driving data is greater than that of the'PAM driving method'.

Meanwhile, in recent PMOLED display devices, efforts to mitigate the flicker phenomenon are continuing.

As an example, one unit frame is divided into a plurality of subframes, and a plurality of gate lines are sequentially selected for each subframe. In this case, each pixel is driven according to its own driving data value, but is driven by being distributed to each of a plurality of subframes, so that a flicker phenomenon is somewhat reduced.

However, in the case of a pixel having a small data value of the driving data, it is driven only in one subframe. In this case, there is a problem that flicker still remains.

An object of the present invention is to solve the problems of the prior art, and to provide a PMOLED display device and a PMOLED display method for reducing flicker while maintaining luminance linearity.

One aspect of the present invention for achieving the above object is a PMOLED display device that displays one image in a unit frame, wherein the unit frame includes first to pth (where p is a natural number) subframes. It is about. The PMOLED display device of the present invention is a display panel including a plurality of pixels disposed on a matrix structure consisting of a plurality of gate lines and a plurality of data lines, each of the plurality of pixels corresponding to the corresponding gate line. The display panel to emit light by being specified by a data line; A gate line driving block driving to sequentially select the plurality of gate lines in each of the first to p-th sub-frames; A data line driving block including a plurality of data driving units driving the plurality of data lines, wherein each of the plurality of data driving units is a corresponding pixel according to a frame information signal and driving data of the corresponding pixel. The data line driving block, which is driven to emit light, and the frame information signal indicates a current subframe; And a control block driven to provide the driving data of the pixel corresponding to the frame information signal to each of a plurality of data driving units of the data line driving block. When each of the plurality of data driving units of the data line driving block has a driving luminance equal to a reference luminance, the specified pixel in each of the first to p-th subframes is used as a unit current for one unit connection time. , Wherein the driving luminance is a luminance corresponding to a data value of the received driving data, and the reference luminance is a luminance corresponding to a data value of the reference data, and when the driving luminance is greater than the reference luminance, the first The specified pixel is driven by the unit current in each of the p-th sub-frames, but at least in the i-th (where i is a natural number between 1 and p) the specified pixel is selected during two or more unit connection times. When the driving luminance is less than the reference luminance, the specified pixel is driven with a driving current smaller than the unit current in at least the jth subframe (where j is a natural number between 1 and p).

Another aspect of the present invention for achieving the above other object is a PMOLED display method for driving a plurality of pixels displaying one image in a unit frame, wherein the unit frame includes first to The PMOLED display method is composed of a p-th sub-frame (where p is a natural number), and a plurality of unit connection times are arranged in each of the first to p-th sub-frames. The PMOLED display method of the present invention includes a driving data receiving step of receiving driving data of the specified pixel; A driving method determination step of determining a driving method based on an evaluation of the driving luminance for a reference luminance, wherein the reference luminance is a luminance corresponding to a data value of reference data, and the driving luminance is a data value of the received driving data Determining the driving method, which is the luminance corresponding to; And a pixel driving step of driving the specified pixel according to a driving method determined in the driving method determining step. In the determining of the driving method, when the driving luminance is the same as the reference luminance, a reference luminance driving method of driving the specified pixel during one unit connection time with a driving current of a unit current in each of the first to p-th subframes And, if the driving luminance is greater than the reference luminance, the driving current is driven by the driving current of the unit current in each of the first to p-th sub-frames, but at least i-th (where i is a natural number between 1 and p) sub In a frame, it is determined by a high luminance driving method that drives the specified pixel during two or more unit connection times, and if the driving luminance is less than the reference luminance, at least j (where j is a natural number between 1 and p) In the sub-frame, the specified pixel is determined as a low luminance driving method in which the specified pixel is driven with a driving current smaller than the unit current.

In the PMOLED display apparatus and method of the present invention as described above, a unit frame is composed of a plurality of subframes, and a corresponding pixel is driven in as many subframes as possible. In this case, when the data value of the driving data corresponds to high luminance, the corresponding pixel is driven in the'PWM driving method'. In addition, when the data value of the driving data corresponds to low luminance, the pixel is driven multiple times with a driving current less than a unit current. Accordingly, according to the PMOLED display apparatus and method of the present invention, even when the data value of the driving data corresponds to low luminance while maintaining linearity of luminance, the flicker phenomenon is greatly alleviated.

A brief description of each drawing used in the present invention is provided.
1 is a diagram showing a PMOLED display device according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating that a plurality of gate lines of FIG. 1 are sequentially selected in each of subframes.
3 is a diagram illustrating in detail a data driving unit of the data line driving block of FIG. 1.
4 is a flow chart showing the PMOLED display method of the present invention as a display method using the PMOLED display device of the present invention.
FIG. 5 is a diagram for describing driving of a pixel according to the high luminance driving method of FIG. 4.
6 is a diagram for describing driving of a pixel according to the low luminance driving method of FIG. 4.
FIG. 7 is a diagram for explaining that emission luminance can be further subdivided in driving a pixel according to the low luminance driving method of FIG.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the implementation of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

And, in understanding each drawing, it should be noted that the same members are intended to be shown with the same reference numerals as much as possible. In addition, in the following description, many specific details, such as specific processing flows, are set forth to provide a more general understanding of the present invention. However, it is obvious to one of ordinary skill in the art that the present invention can be practiced without these specific details. Further, detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

Meanwhile, in the present specification, reference numerals are added to <> together with the same reference numerals for elements performing the same configuration and operation. In this case, these components are collectively referred to by reference numerals. And, if it is necessary to distinguish them individually,'< >'is added after the reference sign.

And, in describing the contents of the present invention throughout the specification, the meanings of the terms'electrically connected','connected', and'connected' between individual components are not only direct connection but also constant properties. It includes everything that is connected through an intermediate medium while maintaining it at a certain level. Terms such as'transmitted' and'derived' of individual signals also include both direct meaning as well as indirect meaning through intermediate media while maintaining the properties of the signal to a certain extent. In addition, terms such as'applied,'applied', and'input' to a voltage or signal are also used in the same meaning throughout the specification.

Also, a plurality of expressions for each component may be omitted. For example, even if a configuration consisting of a plurality of switches or a plurality of signal lines may be expressed as'switches' and'signal lines', it may be expressed in a singular number such as'switches' and'signal lines'. This is because the switches may operate complementary to each other, and in some cases, operate independently. In the case of multiple signal lines having the same properties, for example, data signals, the number of switches is It is also because there is no need to separate them into plural. In this respect, this description is valid. Therefore, similar expressions should also be interpreted in the same meaning throughout the specification.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a diagram showing a PMOLED display device according to an embodiment of the present invention. The PMOLED display device of FIG. 1 displays one image in one unit frame (UFR, see FIG. 2). In this case, the unit frame UFR is composed of first to p-th (here, p is a natural number of 2 or more) sub-frames (SUF<1:p>, see FIG. 2).

Referring to FIG. 1, a PMOLED display device of the present invention includes a display panel 100, a gate line driving block 200, a data line driving block 300, and a control block 400.

The display panel 100 includes a plurality of pixels PIX disposed on a matrix structure consisting of a plurality of gate lines GL<1:n> and a plurality of data lines DL<1:m>. do. Here, n and m are each a natural number of 2 or more.

In this case, each of the plurality of pixels PIX is specified by a corresponding gate line GL and a corresponding data line DL.

The gate line driving block 200 is driven to select the plurality of gate lines GL by activation of a corresponding gating signal (/XGT<1:n>) to “L”.

That is, the plurality of gate lines GL are sequentially selected from each of the first to p-th sub-frames SFR<1:p>, as shown in FIG. 2, and are used as the driving voltage VLED. Is controlled. Here, the driving voltage VLED is a voltage having a higher level than the ground voltage VSS.

Further, each of the pixels PIX emits light with luminance according to its own driving data DDAT when the corresponding gate line GL is selected.

The data line driving block 300 includes a plurality of data driving units 300a<1:m> that drive the plurality of data lines DL<1:m>.

Each of the plurality of data driving units 300a<1:m> is a corresponding pixel according to a frame information signal IFFR and driving data DDAT<1:m> of the pixel PIX corresponding to each. It is driven to emit light (PIX).

Here, the frame information signal IFFR indicates which sub-frame SRF is in progress among the first to p-th sub-frames SRF<1:p>.

In this way, each of the plurality of data driving units 300a<1:m> is operated by reflecting the frame information signal IFFR, so that each of the first to pth subframes SRF<1:p> The number of unit connection times (UTT, see FIGS. 5 to 7) that may be different and/or the amount of current driving the pixels may be reflected in the image display method.

3 is a diagram illustrating in detail the data driving unit 300a of the data line driving block 300 of FIG. 1. In FIG. 3, the data driving unit 300a<q> is representatively shown. Where q is a natural number between 1 and m.

Referring to FIG. 3, the data driving unit 300a<q> of the data line driving block 300 includes a switch 310, a variable current device 330, and a control signal generator 350.

The switch 310 is formed between the corresponding data line DL<q> and a first voltage (in this embodiment, it is a ground voltage VSS), and is turned on according to activation of the switching control signal XCONS. (turn-on). At this time, the activation time of the switching control signal XCONS is indicated by the number of unit connection times (UTT, see FIGS. 5 to 7) in each of the sub-frames SFR.

The variable current meter 330 is formed in series with the switch 310 between the corresponding data line DL<q> and the ground voltage VSS, and the amount of current is adjusted according to a current control signal XCONC. do. Preferably, the amount of current controlled by the variable current device 330 is discrete.

In this case, the amount of current according to the current control signal XCONC is indicated by the magnitude of the driving current of the corresponding pixel PIX (see FIGS. 5 to 7 ).

The control signal generation unit 350 compares the driving data DDAT<q> of the corresponding pixel PIX with reference data RFDAT to provide the switching control signal XCONS and the current control signal XCONC. Occurs. In addition, the switching control signal XCONS and the current control signal XCONC are also dependent on the frame information signal IFFR.

Meanwhile, the data driving unit 300a<q> of the data line driving block 300 is driven to emit light of a corresponding pixel PIX with a luminance according to the driving data DDAT<q>. It will be described in detail with respect to the PMOLED display method using the PMOLED display device of the present invention.

Referring back to FIG. 1, the control block 400 includes the pixel PIX corresponding to the frame information signal IFFR in each of a plurality of data driving units 300a of the data line driving block 300. It is driven to provide the driving data DDAT.

Specifically, the control block 400 includes a data supply unit 410 and a frame information supply unit 430.

The data supply unit 410 supplies the driving data DDAT of the pixel PIX corresponding to each of the plurality of data driving units 300a of the data line driving block 300.

In addition, the frame information providing unit 430 provides the frame information signal IFFR by counting the clock signal CLK.

In FIG. 1, the timing controller 500 generates a timing control signal XTCON to control operation timings of the gate line driving block 200, the data line driving block 300, and the control block 400. .

Subsequently, a PMOLED display method using the PMOLED display device of the present invention is described.

4 is a flow chart showing the PMOLED display method of the present invention as a display method using the PMOLED display device of the present invention.

According to the PMOLED display method of the present invention, a plurality of pixels PIX for displaying one image in the unit frame UFR are driven. In this case, the unit frame UFR is composed of first to p-th sub-frames SFR<1:p> in which the plurality of pixels PIX are specified in each, and each of the first to p-th sub-frames A plurality of unit connection times (UTTs) are arranged (see FIGS. 5 to 7 ).

In this embodiment, p is assumed to be '4'. In addition, it is assumed that the data value of the reference data RFDAT is also '4'.

Referring to FIG. 4, the PMOLED display method of the present invention includes a driving data receiving step (S100), a driving method determining step (S200), and a pixel driving step (S300).

In the driving data receiving step S100, driving data DDAT of the pixel PIX specified by the gate line GL and the data line DL is received.

In the driving method determination step S200, the driving luminance PDBR for the reference luminance PRBR is evaluated, and the driving method is determined based on the evaluated result. Here, the reference luminance PRBR is a luminance corresponding to a data value of the reference data RFDAT, and the driving luminance PDBR is a luminance corresponding to a data value of the received driving data DDAT.

In addition, in the present specification, it is assumed that the driving luminance PDBR increases as the data value of the driving data DDAT increases.

The driving method determination step (S200) specifically includes a luminance evaluation process (S210), a reference luminance drive determination process (S231), a high luminance drive determination process (S233), and a low luminance drive determination process (S235).

In the luminance evaluation process S210, the driving luminance PDBR with respect to the reference luminance PRBR is evaluated. That is, in the luminance evaluation process S210, the driving data DDAT of the specified pixel PIX and the data values of the reference data RFDAT are compared.

In addition, according to the evaluation result in the luminance evaluation process (S210), one of a reference luminance driving determination process (S231), a high luminance driving determination process (S233), and a low luminance driving determination process (S235) is performed.

The reference luminance driving determination process S231 is performed when the driving luminance PDBR is the same as the reference luminance PRDR, that is, when the data value of the driving data DDAT is '4'. In this case, the driving method of the corresponding pixel PIX is determined as the reference luminance driving method MDRBR.

The high luminance driving determination process S233 is performed when the driving luminance PDBR is greater than the reference luminance PRDR and the data value of the driving data DDAT is greater than '4'. In this case, the driving method of the corresponding pixel PIX is determined as the high luminance driving method (MDHBR).

The low luminance driving determination process (S235) is performed when the driving luminance PDBR is less than the reference luminance PRDR and a data value of the driving data DDAT is less than '4'. In this case, the driving method of the corresponding pixel PIX is determined as a low luminance driving method (MDLBR).

For reference, when the PMOLED display method of the present invention is applied to the PMOLED display device of the present invention, the driving method determining step (S200) includes each of the plurality of data driving units 300a of the data line driving block 300 It can be understood that it is performed in the control signal generator 350 (refer to FIG. 3 ).

With continued reference to FIG. 4, in the pixel driving step S300, the specified pixel PIX is driven according to the driving method determined in the driving method determining step S200.

Next, with reference to FIGS. 5 to 6, the driving of the specified pixel PIX performed in the pixel driving step S300 will be described in detail according to the driving method determined in the driving method determining step S200. .

5 is a view for explaining driving of the pixel PIX according to the high luminance driving method (MDHBR) of FIG. 4, and FIG. 6 is a diagram illustrating driving of the pixel PIX according to the low luminance driving method (MDLBR) of FIG. 4 It is a drawing to do. And, FIG. 7 is a view for explaining that the light emission luminance can be further subdivided in the low luminance driving process of FIG. 4.

At this time, in FIGS. 5 to 7, driving of the pixel PIX according to the reference luminance driving method MDRBR of FIG. 4 is also illustrated, and the pixel PIX connected to the first gate line GL<1> is driven. It should be done.

In addition, in each of FIGS. 5 to 7, when driving in one unit connection time (UTT) with the size of a unit current (UTI) in one unit frame (YFR), the luminance of the corresponding pixel (PIX) is driven. It corresponds to the data value '1' of the data DDAT.

First, when the driving method of the corresponding pixel PIX is determined as the reference luminance driving method (MDRBR) (Case 11 of FIG. 5, CASE21 of FIG. 6, and CASE31 of FIG. 7), the first to fourth subframes ( In each of SFR<1> to SRF<4>), the corresponding pixel PIX has a unit current UTI and is driven during one unit connection time UTT.

In addition, when the driving method of the corresponding pixel PIX is determined as the high luminance driving method MDRBR, the corresponding pixel PIX is driven in a so-called'PWM driving method'. That is, as shown in FIG. 5, in each of the first to fourth sub-frames SFR<1> to SRF<4>, the corresponding pixel PIX is driven by the unit current UTI. At this time, the corresponding pixel PIX is driven during two or more unit connection times (UTT) at least in the i-th subframe (where i is a natural number between 1 and 4).

For example, when the data value of the driving data DDAT of the corresponding pixel PIX is '8' (Case12 in FIG. 5), the pixel PIX is the first to fourth subframes SFR< 1> to SRF<4>) are driven during two unit connection times (UTT) with the magnitude of the unit current (UTI)).

In addition, when the data value of the driving data DDAT of the corresponding pixel PIX is '6', the pixel PIX is the first and third sub-frames SFR<1> and SRF<3>. In each, the unit current (UTI) is driven during two unit connection times (UTT), and in each of the second and fourth sub-frames (SFR<2> and SRF<4>), the unit current ( UTI) is driven during one unit connection time (UTT).

In addition, when the driving method of the corresponding pixel PIX is determined as the low luminance driving method MDLBR, the corresponding pixel PIX is driven in a so-called'PAM driving method'. That is, as shown in FIG. 6, the corresponding pixel PIX in each of the first to fourth sub-frames SFR<1> to SRF<4> is during one unit connection time (UTT). It is driven. In this case, the corresponding pixel PIX is driven by a current smaller than the unit current UTI in at least the jth subframe (where j is a natural number between 1 and 4).

For example, when the data value of the driving data DDAT of the corresponding pixel PIX is '3' (Case22 in FIG. 6), the pixel PIX is the first to fourth subframes SFR< In each of 1> to SRF<4>), it is driven at 3/4 of the unit current UTI during one unit connection time UTT.

And, when the data value of the driving data DDAT of the corresponding pixel PIX is '2' (Case23 in FIG. 6), the pixel PIX is the first to fourth subframes SFR<1>. In each of SRF<4>), during one unit connection time (UTT), it is driven at 2/4 of the unit current (UTI).

In addition, when the data value of the driving data DDAT of the corresponding pixel PIX is '1' (Case24 in FIG. 6), the pixel PIX is the first to fourth sub-frames SFR<1>. In each of SRF<4>), it is driven at 1/4 of the unit current UTI during one unit connection time UTT.

Meanwhile, when the driving method of the corresponding pixel PIX is determined as the low luminance driving method MDLBR, the resolution of the emission luminance of the corresponding pixel PIX may be increased.

For example, when the data value of the driving data DDAT of the corresponding pixel PIX is '3.5' (Case32 in FIG. 7), the pixel PIX is the first and third subframes SFR< In each of 1> and SRF<3>), it is driven during one unit connection time (UTT) at the size of the unit current (UTI), and the second and fourth sub-frames (SFR<2> and SRF<4>) ) In each, it is driven during one unit connection time (UTT) with a size of 3/4 of the unit current (UTI).

In addition, when the data value of the driving data DDAT of the corresponding pixel PIX is '1.5' (Case33 in FIG. 7), the pixel PIX is the first and third subframes SFR<1>. And SRF<3>), each of which is driven during one unit connection time (UTT) with a magnitude of 2/4 of the unit current (UTI), and the second and fourth sub-frames (SFR<2> and SRF< 4>) In each case, it is driven during one unit connection time (UTT) with a magnitude of 1/4 of the unit current (UTI).

In summary, in the PMOLED display apparatus and method of the present invention as described above, the unit frame UFR is composed of a plurality of subframes SFR, and the corresponding pixel PIX is driven in as many subframes as possible.

In this case, when the driving luminance PDBR is greater than the reference luminance PRBR, the pixel PIX is driven in a so-called'PWM driving method'. In addition, when the driving luminance PDBR is less than the reference luminance PRBR, the corresponding pixel PIX is driven in a so-called'PAM driving method'. That is, when the data value of the driving data DDAT corresponds to low luminance, the pixel is driven multiple times with a driving current less than the unit current.

Accordingly, according to the PMOLED display apparatus and method of the present invention, the flicker phenomenon is greatly alleviated even when the data value of the driving data DDAT corresponds to low luminance while maintaining linearity of luminance.

As described above, although the embodiments have been described by the limited embodiments and drawings, various modifications and variations are possible from the above description by those of ordinary skill in the art.

For example, in the present specification, an embodiment in which the driving luminance PDBR is also increased as the data value of the driving data DDAT increases is shown and described. However, it is apparent to those skilled in the art that the technical idea of the present invention can be implemented in an embodiment in which the driving luminance PDBR is decreased as the data value of the driving data DDAT increases.

Therefore, the true technical protection scope of the present invention should be determined by the technical idea of the attached registration claims.

Claims (6)

A PMOLED display device for displaying one image in a unit frame, wherein the unit frame comprises first to pth (wherein p is a natural number) subframes,
A display panel including a plurality of pixels disposed on a matrix structure consisting of a plurality of gate lines and a plurality of data lines, wherein each of the plurality of pixels is specified by a corresponding data line and a corresponding gate line. The display panel emitting light;
A gate line driving block driving to sequentially select the plurality of gate lines in each of the first to p-th subframes;
A data line driving block including a plurality of data driving units driving the plurality of data lines, wherein each of the plurality of data driving units is a corresponding pixel according to a frame information signal and driving data of the corresponding pixel. The data line driving block, which is driven to emit light, and the frame information signal indicates a current subframe; And
A control block driven to provide the driving data of the pixel corresponding to the frame information signal to each of a plurality of data driving units of the data line driving block,
Each of the plurality of data driving units of the data line driving block
When the driving luminance is the same as the reference luminance, the specified pixel in each of the first to p-th subframes is driven by a unit current for one unit connection time, and the driving luminance is the data of the received driving data. Is the luminance corresponding to the value, the reference luminance is the luminance corresponding to the data value of the reference data,
When the driving luminance is greater than the reference luminance, the specified pixel is driven by the unit current in each of the first to p-th sub-frames, but at least in the i-th subframe (where i is a natural number between 1 and p) Driving the specified pixel during two or more of the unit connection times,
When the driving luminance is less than the reference luminance, at least j-th (where j is a natural number between 1 and p) sub-frame drives the specified pixel with a driving current smaller than the unit current Device.
The method of claim 1, wherein each of the plurality of data driving units of the data line driving block
A switch formed between the corresponding data line and the first voltage and turned on in response to a switching control signal;
A variable current device formed in series with the switch between the corresponding data line and the first voltage, the amount of current adjusted by a current control signal; And
A control signal generator for generating the switching control signal and the current control signal by comparing the driving data of the corresponding pixel with the reference data, wherein the switching control signal and the current control signal are dependent on the frame information signal. A PMOLED display device comprising the control signal generator.
The method of claim 1, wherein the control block is
A data supply unit supplying the driving data of the pixel corresponding to each of the plurality of data driving units of the data line driving block; And
And a frame information providing unit that counts a clock signal and provides the frame information signal.
A PMOLED display method for driving a plurality of pixels displaying one image in a unit frame, wherein the unit frame is composed of first to p-th (where p is a natural number) sub-frames in which the plurality of pixels are specified in each, In the PMOLED display method in which a plurality of unit connection times are arranged in each of the first to p-th sub-frames,
A driving data receiving step of receiving driving data of the specified pixel;
A driving method determination step of determining a driving method based on an evaluation of the driving luminance for a reference luminance, wherein the reference luminance is a luminance corresponding to a data value of reference data, and the driving luminance is a data value of the received driving data Determining the driving method, which is a luminance corresponding to; And
A pixel driving step of driving the specified pixel according to the driving method determined in the driving method determining step,
The driving method determination step
If the driving luminance is the same as the reference luminance, a driving current of a unit current in each of the first to p-th subframes is determined as a reference luminance driving method for driving the specified pixel during one unit connection time,
If the driving luminance is greater than the reference luminance, it is driven by the driving current of the unit current in each of the first to p-th sub-frames, but at least two in the i-th subframe (where i is a natural number between 1 and p) It is determined by a high luminance driving method for driving the specified pixel during the unit connection time,
If the driving luminance is less than the reference luminance, at least j-th (where j is a natural number between 1 and p) is determined as a low luminance driving method in which the specified pixel is driven with a driving current smaller than the unit current. PMOLED display method, characterized in that.
The method of claim 4, wherein the driving current of the specified pixel according to the low luminance driving method is
PMOLED display method, characterized in that the same amount in each of the first to p-th sub-frame.
The method of claim 4, wherein the driving current of the specified pixel according to the low luminance driving method is
The PMOLED display method, characterized in that different in at least one sub-frame of the first to p-th sub-frame.

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