KR102479870B1 - Display apparatus and method of driving the same - Google Patents

Abstract

A display device includes a display unit including a plurality of data lines and a plurality of pixels connected to a plurality of gate lines crossing the plurality of data lines, and having a first gate-on pulse when image data is a normal grayscale image. A gate signal is generated, and when the image data is a low grayscale image, a low grayscale gate signal having a second gate-on period smaller than the first gate-on period is generated, and one output channel is connected to at least two gate lines. A connected gate driver, and in the low grayscale image, applies a signal of the second gate-on period of the low grayscale gate signal to the odd-numbered gate line during a first subframe, and applies the signal of the second gate-on period to the even-numbered gate line during a second subframe. and a switching unit for applying a signal of a second gate-on period of the low grayscale gate signal. Accordingly, in the low grayscale frame image displayed in the OPR mode, only odd-numbered horizontal lines are driven in the first subframe to display odd-numbered line images, and only even-numbered horizontal lines are driven in the second subframe to display even-numbered line images. Accordingly, it is possible to improve a flicker phenomenon caused by light emitting pixels and non-emitting pixels according to the OPR mode.

Description

Display device and its driving method {DISPLAY APPARATUS AND METHOD OF DRIVING THE SAME}

The present invention relates to a display device, and more particularly, to a display device capable of improving display quality and a method for driving the display device.

Recently, various flat panel display devices capable of reducing the weight and volume, which are disadvantages of cathode ray tubes, are being developed. Flat panel displays include liquid crystal display (LCD), field emission display (FED), plasma display panel (PDP), and organic light emitting display (OLED). . In particular, since the organic light emitting display device has various advantages such as a wide viewing angle, fast response speed, thin thickness, and low power consumption, it has been spotlighted as a promising next-generation display device.

The organic light emitting diode display may include a controller that controls overall driving timing, a gate driver that provides gate signals to pixels, a data driver that provides data signals to pixels, and a light emitting driver that supplies light emitting signals to pixels.

One object of the present invention is to provide a display device with improved display quality.

Another object of the present invention is to provide a method for driving the display device.

In order to achieve the above object, a display device according to example embodiments includes a display unit including a plurality of pixels connected to a plurality of data lines and a plurality of gate lines crossing the plurality of data lines; When the image data is a normal grayscale image, a normal gate signal having a first gate-on pulse is generated, and when the image data is a low-grayscale image, a low-grayscale gate signal having a second gate-on interval smaller than the first gate-on interval and one output channel is a gate driver connected to at least two gate lines, and a second gate-on period of the low grayscale gate signal to the odd-numbered gate line during the first subframe in the low grayscale image. and a switching unit for applying a signal of a second gate-on period of the low grayscale gate signal to the even-numbered gate line during a second subframe.

In an embodiment, the switching unit applies an initial signal of the first gate-on period to odd-numbered gate lines and a later signal of the first gate-on period to even-numbered gate lines during a frame in the normal grayscale image. can

In one embodiment, the display device calculates an on-pixel rate corresponding to the image data of the current frame when the image data is the low-grayscale image, and generates correction data obtained by correcting the image data based on the on-pixel rate. The control unit may further include a control unit for driving the plurality of data lines using the correction data.

In one embodiment, the switching unit includes first odd-numbered switches connected to the odd-numbered gate lines and first even-numbered switches connected to even-numbered gate lines, and a first switching control signal is applied to the first odd-numbered switches. and a second switching control signal may be applied to the first even-numbered switches.

In an embodiment, in the normal grayscale image, the first switching control signal may have a switch-on period and a switch-off period corresponding to one horizontal period, and may be delayed from the second switching control signal by one horizontal period.

In one embodiment, in the low grayscale image, the first switching control signal may have a switch-on period and a switch-off period corresponding to a first subframe, and may be delayed with the second switching control signal in a subframe.

In one embodiment, the display unit further includes a plurality of light emitting lines that intersect the plurality of data lines and are connected to the plurality of pixels, and when the image data is a normal grayscale image, a first light emission on period is set to normal. generating a light emitting signal, and generating a low gradation light emitting signal having a second light emitting on period smaller than the first light emitting on period when the image data is a low gradation image, and one output channel connected to a plurality of light emitting lines; A light emitting driver may be further included.

In one embodiment, the switching unit applies an initial signal of the first light-on period to odd-numbered light-emitting lines during a frame in the normal grayscale image and applies a later signal of the first light-on period to even-numbered light-emitting lines; , In the low grayscale image, the signal of the second light-on period of the low-grayscale light-emitting signal is applied to the odd-numbered light-emitting lines during the first subframe, and the low-grayscale light emission is applied to the even-numbered light-emitting lines during the second subframe. A signal of the second light-on period of the signal may be applied.

In one embodiment, the switching unit includes second odd-numbered switches connected to the odd-numbered light-emitting lines and second even-numbered switches connected to the even-numbered light-emitting lines, and a third switching control signal is provided to the second odd-numbered switches. and a fourth switching control signal may be applied to the second even-numbered switches.

In an embodiment, in the normal grayscale image, the third switching control signal may have a switch-on period and a switch-off period corresponding to one horizontal period, and may be delayed from the fourth switching control signal by one horizontal period.

In an embodiment, in the low grayscale image, the third switching control signal may have a switch-on period and a switch-off period corresponding to a first subframe, and may be delayed with the fourth switching control signal in a subframe.

In one embodiment, the switching unit includes second odd-numbered switches connected to the odd-numbered light-emitting lines and second even-numbered switches connected to the even-numbered light-emitting lines, and the second odd-numbered switches include the first switching control signal. is applied, and the second switching control signal may be applied to the second even-numbered switches.

In order to achieve the other object, according to example embodiments, a display device including a display unit including a plurality of data lines and a plurality of pixels connected to a plurality of gate lines crossing the plurality of data lines. The driving method includes generating a normal gate signal having a first gate-on pulse when the image data is a normal grayscale image, and using a second gate-on section smaller than the first gate-on section when the image data is a low-grayscale image. generating a low grayscale gate signal having a second gate-on period of the low grayscale gate signal to the odd-numbered gate line during a first subframe in the low grayscale image; and applying a signal of a second gate-on period of the low grayscale gate signal to an even-numbered gate line.

In an embodiment, in the normal grayscale image, an initial signal of the first gate-on period may be applied to an odd-numbered gate line during a frame, and a later signal of the first gate-on period may be applied to the even-numbered gate line. there is.

In an embodiment, the method may include calculating an on-pixel rate corresponding to image data of a current frame when the image data is the low-grayscale image, and generating correction data obtained by correcting the image data based on the on-pixel rate. and applying a data voltage to the plurality of data lines using the correction data.

In one embodiment, the display unit further includes a plurality of light emitting lines that intersect the plurality of data lines and are connected to the plurality of pixels, and when the image data is a normal grayscale image, a first light emission on period is set to normal. The method may further include generating a light emitting signal and generating a low gradation light emitting signal having a second light emitting on period smaller than the first light emitting on period when the image data is a low gradation image.

In one embodiment, in the normal grayscale image, an initial signal of the first light-on period is applied to odd-numbered light-emitting lines and a later signal of the first light-on period is applied to even-numbered light-emitting lines during a frame; In the grayscale image, the signal of the second light-on period of the low-grayscale light-emitting signal is applied to the odd-numbered light-emitting line during the first subframe, and the third light-emitting signal of the low-grayscale light-emitting signal is applied to the even-numbered light-emitting line during the second subframe. 2 The signal of the light-on period can be applied.

In an exemplary embodiment, the display device includes first odd-numbered switches connected to the odd-numbered gate lines and first even-numbered switches connected to the even-numbered gate lines, and second odd-numbered switches connected to the odd-numbered emission lines. and second even-numbered switches connected to the even-numbered light emitting lines, wherein a first switching control signal is applied to the first and second odd-numbered switches, and a second switching control signal is applied to the first and second even-numbered switches. A signal may be applied.

In an embodiment, in the normal grayscale image, the first switching control signal may have a switch-on period and a switch-off period corresponding to one horizontal period, and may be delayed from the second switching control signal by one horizontal period.

In one embodiment, in the low grayscale image, the first switching control signal may have a switch-on period and a switch-off period corresponding to a first subframe, and may be delayed with the second switching control signal in a subframe.

According to the display device and its driving method according to embodiments of the present invention as described above, only the odd-numbered horizontal lines are driven in the first sub-frame of the low-grayscale frame image displayed in the OPR mode to display the odd-numbered line images, and In subframe 2, only the even-numbered horizontal lines are driven to display even-numbered line images. Accordingly, it is possible to improve a flicker phenomenon caused by light emitting pixels and non-emitting pixels according to the OPR mode.

1 is a block diagram of a display device according to an exemplary embodiment of the present invention.
2 is a pixel equivalent circuit diagram according to an embodiment of the present invention.
3 is a block diagram of a control unit according to an embodiment of the present invention.
4 is a conceptual diagram for explaining an OPR mode according to an embodiment of the present invention.
5 is a circuit diagram of a switching unit according to an embodiment of the present invention.
6 is a waveform diagram of gate signals of a display device in a normal mode according to an embodiment of the present invention.
7 is a waveform diagram of emission signals of a display device in a normal mode according to an embodiment of the present invention.
8 is a conceptual diagram illustrating a driving method of a display device according to an exemplary embodiment in a normal mode.
9 is a waveform diagram of gate signals of a display device according to an OPR mode according to an embodiment of the present invention.
10 is a waveform diagram of emission signals of a display device according to an OPR mode according to an embodiment of the present invention.
11A and 11B are conceptual views illustrating a driving method of a display device in an OPR mode according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted.

1 is a block diagram of a display device according to an exemplary embodiment of the present invention.

Referring to FIG. 1 , the display device includes a display unit 110, a control unit 120, a voltage generator 130, a data driver 140, a gate driver 150, a light emitting driver 160, and a switching unit 170. includes

The display unit 110 includes a plurality of pixels P, a plurality of gate lines GL1, ..., GLN, a plurality of light emitting lines EL1, ..., ELN, and a plurality of data lines DL1. ,..., DLM) (N and M are natural numbers). Each pixel P is connected to a gate line, a data line, and a light emitting line.

The data lines DL1 , ..., DLM may extend in the column direction CD and may be arranged in the row direction RD. The data lines DL1 to DLM are connected to the data driver 140 to transmit data voltages to the pixel P.

The gate lines GL1 , .. and GLN may extend in a row direction RD and may be arranged in a column direction CD. The gate lines GL1 , .. and GLN are connected to the gate driver 150 to transfer gate signals to the pixels P.

The emission lines EL1 to ELN may extend in the row direction RD and be arranged in the column direction CD. The light emitting lines EL1 to ELN are connected to the light emitting driver 160 to transmit light emitting signals to the pixel P.

The controller 120 receives image data DATA1 and a control signal CONT from an external device. The image data DATA1 may include red, green, and blue data. The control signal CONT may include a horizontal sync signal, a horizontal sync signal, and a main clock signal.

The control unit 120 converts the image data DATA1 according to specifications such as a pixel structure and resolution of the display unit 110 and outputs the converted image data.

The controller 120 analyzes the converted image data frame by frame to determine whether the image data of the current frame is a low grayscale image or a normal grayscale image. When the image data of the current frame is the low-grayscale image, the control unit 120 calculates an on-pixel ratio of the current frame to drive in the OPR mode, and calculates an on-pixel ratio of the current frame based on the on-pixel ratio. Correct the video data. Meanwhile, when the image data of the current frame is the normal grayscale image, the controller 120 provides the image data to the data driver 140 .

A defect in the form of a panel stain occurs due to a deviation of pixel current due to a low current for driving a pixel at low brightness/low gradation. It is driven in OPR (On Pixel Ratio) mode to improve panel stains caused by such low current driving. In the OPR mode, some pixels emit light (turned on) with a target current and some pixels do not emit light (turned off) to maintain the same luminance. For example, when adjacent first and second pixels are driven with a low current to display luminance of 20 cd/m2, respectively, according to the OPR mode, a relatively high current is applied to only the first pixel to achieve a luminance of 40 cd/m2. It emits light and the second pixel does not emit light.

For example, when the average gray level of the current frame is lower than the reference low gray level, the controller 120 calculates an on-pixel rate using image data of the current frame, and based on the on-pixel rate, the image of the current frame Data is corrected and the corrected image data is output to the data driver 140 . Meanwhile, when the average gray level of the current frame is higher than the reference low gray level, the controller 120 outputs image data of the current frame to the data driver 140 .

The controller 120 generates a data control signal CONT1 for driving the data driver 140 and a gate control signal CONT2 for driving the gate driver 150 based on the control signal CONT. A light emission control signal CONT3 for driving the light driving unit 160 and a switching control signal CONT4 for driving the switching unit 170 are generated.

According to this embodiment, the gate control signal CONT2 includes a normal gate control signal corresponding to the normal mode and a low gray level gate control signal corresponding to the OPR mode. The emission control signal includes a general emission control signal corresponding to the normal mode and a low grayscale emission control signal corresponding to the OPR mode. The switching control signal CONT4 includes a normal switching control signal corresponding to the normal mode and a low grayscale switching control signal corresponding to the OPR mode.

The voltage generator 130 generates a plurality of driving voltages for driving the display device using an external voltage. The driving voltages include a data driving voltage for driving the data driver 140 , a gate driving voltage for driving the gate driver 150 , a light emitting driving voltage for driving the light emitting driver 160 , and the display unit 110 . ) to generate a display driving voltage for driving.

The data driving voltage includes an analog power supply voltage (AVDD) for converting image data into a data voltage, and the gate driving voltage is a first on voltage (VGH1) and a first off voltage (VGL1) for generating a gate signal. wherein the light emitting driving voltage includes a second on voltage VGH2 and a second off voltage VGL2 for generating the light emitting signal, and the display driving voltage includes light emitting power supply voltages ELVDD and ELVSS do.

The data driver 140 converts image data into data voltages in response to the data control signal CONT1 and outputs the data voltages to the data lines DL1, ..., DLM.

The gate driver 150 generates a plurality of gate signals in response to the gate control signal CONT2.

According to this embodiment, the number of output channels of the gate driver 150 is n (= N/2), and one output channel of the gate driver 150 includes two gate lines, that is, odd and even gates. connected to the lines The gate driver 150 generates n (= N/2) gate signals corresponding to the N first to N th gate lines GL1 , ..., GLN.

For example, in the normal mode, the gate driver 150 generates a normal gate signal having a gate-on period corresponding to two horizontal periods, and generates n normal gate signals (G1_NOR, ..., Gn_NOR) during one frame. ) is sequentially output once. In the OPR mode, the gate driver 150 generates a low grayscale gate signal having a gate-on period corresponding to one horizontal period, and generates n low grayscale gate signals G1_OPR, ..., Gn_OPR during one frame. are output twice sequentially.

The light emitting driver 160 generates a plurality of light emitting signals in response to the light emitting control signal CONT3.

According to this embodiment, the light emitting driver 160 has n (= N/2) output channels, and one output channel of the light emitting driver 160 has two light emitting lines, that is, odd and even light emitting lines. connected to the lines The light emitting driver 160 generates n (= N/2) light emitting signals corresponding to the N first to N th light emitting lines EL1 , ..., ELN.

For example, in the normal mode, the light emitting driver 160 generates a normal light emitting signal having a light on period corresponding to 2 horizontal cycles, and n normal light emitting signals EM1_NOR, ..., EMn_NOR during one frame. ) is sequentially output once. In the OPR mode, the light emitting driver 160 generates a low grayscale light emitting signal having an emission on period corresponding to one horizontal period, and n low grayscale light emitting signals EM1_OPR, ... , EMn _OPR during the one frame. ) is sequentially output twice.

The switching unit 170 is connected to the output channels of the gate driving unit 150 and the output channels of the light emitting driving unit 160, and in response to the switching control signal CONT4, the n gate signals and the n light emitting signals are selectively provided to the N gate lines and the N light emitting lines.

According to the present embodiment, in the normal mode, the switching unit 170 provides the n gate signals to the N gate lines and provides the n light-emitting signals to the N light-emitting lines during one frame. do.

In the OPR mode, the switching unit 170 provides the n gate signals to odd-numbered gate lines and the n light-emitting signals to odd-numbered light-emitting lines during an initial subframe. The switching unit 170 provides the n gate signals to even-numbered gate lines and the n light-emitting signals to even-numbered light-emitting lines during the later subframe.

FIG. 2 is an equivalent circuit diagram of the pixel shown in FIG. 1 .

1 and 2 , the pixel P includes an organic light emitting diode (OLED), a driving transistor T1, a capacitor CST, a switching transistor T2, and an emission control transistor T3. ).

The driving transistor T1 includes a control electrode connected to the switching transistor T2, a first electrode receiving the first light emitting power supply voltage ELVDD, and a second electrode connected to the light emitting control transistor T3.

The capacitor CST includes a first electrode receiving the first light emitting power supply voltage ELVDD and a second electrode connected to the control electrode of the driving transistor T1.

The switching transistor T2 includes a control electrode receiving the gate signal G, a first electrode receiving the data voltage VDATA, and a second electrode connected to the control electrode of the driving transistor T1.

The emission control transistor T3 includes a control electrode receiving an emission signal EM, a first electrode connected to the second electrode of the driving transistor T1, and a second electrode connected to the organic light emitting diode OLED. .

The organic light emitting diode OLED includes a first electrode connected to the light emitting control transistor T3 and a second electrode receiving the second light emitting power supply voltage ELVSS.

When the emission control transistor T3 is turned on, the current I flowing through the driving transistor T1 is applied to the organic light emitting diode OLED, and the organic light emitting diode OLED emits light. An emission period of the organic light emitting diode OLED is determined corresponding to a turn-on period of the emission control transistor T3.

3 is a block diagram of a control unit according to an embodiment of the present invention. 4 is a conceptual diagram for explaining an OPR mode according to an embodiment of the present invention.

1 and 3 , the controller 120 includes a controller 121, an on-pixel rate (OPR) calculator 123, a data corrector 125, and a signal generator 127.

The control unit 120 converts the image data DATA1 according to specifications such as a pixel structure and resolution of the display unit 110 and outputs the converted image data.

The controller 121 analyzes the converted image data frame by frame to determine whether the image data of the current frame is a low grayscale image or a normal grayscale image, and selects an OPR mode corresponding to the low grayscale image or the normal grayscale image. A mode signal for driving in the corresponding normal mode is provided to the OPR calculator 123 and the signal generator 127 .

For example, when the average gray level of the current frame is lower than the reference low gray level, the control unit 121 determines the current frame as a low gray level image and transmits a first mode signal for operating in the OPR mode to the OPR calculating unit 123. And it is provided to the signal generator 127.

On the other hand, when the average gray level of the current frame is higher than the reference low gray level, the control unit 121 determines the current frame as a normal gray level image and transmits a second mode signal for operation in the normal mode to the OPR calculating unit 123. And it is provided to the signal generator 127.

The OPR calculator 123 calculates an on-pixel rate of the image data of the current frame in response to the first mode signal of the controller 121 .

The OPR calculator 123 calculates on-pixel rates of a plurality of pixels using image data of a current frame. The on-pixel ratio is a ratio of light emitting pixels to all pixels in one frame.

For example, referring to FIG. 4 , when the on-pixel ratio of the current frame is 50%, red, green, and blue pixels of even-numbered pixel rows PR2 and PR4 all emit light, and odd-numbered pixel rows emit light. In (PR1, PR3, PR5), only some green pixels (G) among the green sub-pixels may emit light, and the remaining red, green, and blue pixels may not emit light.

The data correction unit 235 corrects the image data of the current frame based on the on-pixel rate of the current frame and outputs the corrected image data.

The signal generator 127 generates a data control signal CONT1 for driving the data driver 140 and a gate control signal CONT2 for driving the gate driver 150 based on the control signal CONT. , a light emission control signal CONT3 for driving the light driving unit 160 and a switching control signal CONT4 for driving the switching unit 170 are generated.

The gate control signal CONT2 includes a normal gate control signal corresponding to the normal mode and a low grayscale gate control signal corresponding to the OPR mode. The normal gate control signal may include a plurality of clock signals for controlling a gate-on period of the gate signal for the normal mode, and the low gray level gate control signal controls a gate-on period of the gate signal for the OPR mode. may include a plurality of clock signals for The emission control signal includes a general emission control signal corresponding to the normal mode and a low grayscale emission control signal corresponding to the OPR mode. The normal light emission control signal may include a plurality of clock signals for controlling an emission-on period of the normal mode light emission signal, and the low gray level emission control signal controls an emission-on period of the OPR mode light emission signal. may include a plurality of clock signals for The switching control signal CONT4 includes a normal switching control signal corresponding to the normal mode and a low grayscale switching control signal corresponding to the OPR mode.

For example, the signal generator 127 generates the low gray level gate control signal, the low gray level light emission control signal, and the low gray level switching control signal in response to the first mode signal corresponding to the OPR mode. The low gray level gate control signal is applied to the gate driver 150 , the low gray level emission control signal is applied to the light emission driving part 160 , and the low gray level switching control signal is applied to the switching unit 170 .

The signal generator 127 generates a general gate control signal, a general emission control signal, and a general switching control signal in response to the second mode signal corresponding to the normal mode. The general gate control signal is applied to the gate driver 150 , the general light emission control signal is applied to the light emission driver 160 , and the general switching control signal is applied to the switch 170 .

5 is a circuit diagram of a switching unit according to an embodiment of the present invention.

1 and 5 , the switching unit 170 is connected to a plurality of gate output channels of the gate driving unit 150 and a plurality of light emitting output channels of the light driving unit 160 .

For example, the gate driver 150 includes first through n-th gate output channels GO1 , GO2 , ..., GOn. The first gate output channel GO1 is connected to the first gate line GL1 and the second gate line GL2, and the second gate output channel GO2 is connected to the third gate line GL3 and the fourth gate line ( GL4) is connected. In this way, the nth gate output channel GOn is connected to the N−1th gate line GLN−1 and the Nth gate line GLN.

The light driving unit 160 includes first through nth light output channels EO1, EO2, ..., EOn. The first light emitting output channel EO1 is connected to the first light emitting line EL1 and the second light emitting line EL2, and the second light emitting output channel EO2 is connected to the third light emitting line EL3 and the fourth light emitting line ( EL4) is connected. In this way, the nth light emitting output channel EOn is connected to the N−1th light emitting line ELN−1 and the Nth light emitting line ELN.

The switching unit 170 includes a first switch unit 171 and a second switch unit 172 . The first switch unit 171 is driven in response to a first normal switching control signal in the normal mode and driven in response to a first low gray level switching control signal in the OPR mode. The second switch unit 172 is driven in response to a second general switching control signal in the normal mode and driven in response to a second low gray level switching control signal in the OPR mode.

The first switch unit 171 includes first odd-numbered switches SW11, SW12, ..., and SW1n and second odd-numbered switches SW31, SW32, ..., and SW3n. The first odd-numbered switches SW11, SW12, .. and SW1n respectively switch odd-numbered gate lines.

The eleventh odd switch SW11 is connected to the first gate line GL1 and the first gate output channel GO1. The twelfth odd switch SW12 is connected to the third gate line GL3 and the second gate output channel GO2. The 1n odd switch SW1n is connected to the N−1th gate line GLN−1 and the nth gate output channel GOn.

The second odd-numbered switches SW31, SW32, ..., and SW3n respectively switch odd-numbered light emitting lines.

The thirty-first odd switch SW31 is connected to the first emission line EL1 and the first emission output channel EO1. The 32nd odd switch SW32 is connected to the third emission line EL3 and the second emission output channel EO2. The 3n odd switch SW3n is connected to the N−1th light emitting line ELN−1 and the nth light emitting output channel EOn.

The second switch unit 172 includes first even-numbered switches SW21, SW22, ..., SW2n and second even-numbered switches SW41, SW42, ..., SW4n. The first even-numbered switches SW21, SW22, ..., and SW2n respectively switch even-numbered gate lines.

The twenty-first even switch SW21 is connected to the second gate line GL2 and the first gate output channel GO1. The twenty-second even-numbered switch SW22 is connected to the fourth gate line GL4 and the second gate output channel GO2. The 2n-th even-numbered switch SW2n is connected to the Nth gate line GLN and the nth gate output channel GOn.

The second even-numbered switches SW41, SW42, ..., and SW4n respectively switch the even-numbered light emitting lines.

The forty-first even-numbered switch SW41 is connected to the second emission line EL2 and the first emission output channel EO1. The forty-second even-numbered switch SW42 is connected to the fourth emission line EL4 and the second emission output channel EO2. The 4n-th even-numbered switch SW4n is connected to the Nth light emitting line ELN and the nth light emitting output channel EOn.

6 is a waveform diagram of gate signals of a display device in a normal mode according to an embodiment of the present invention. 7 is a waveform diagram of emission signals of a display device in a normal mode according to an embodiment of the present invention. 8 is a conceptual diagram illustrating a driving method of a display device according to an exemplary embodiment in a normal mode.

5 and 6, in the normal mode, the first switch unit 171 receives a first normal switching control signal SW_NOR1, and the second switch unit 172 receives a second normal switching control signal. (SW_NOR2) is received.

The first normal switching control signal (SW_NOR1) has a first switch-on period (ON_S1) corresponding to 1 horizontal period (1H) and a first switch-off period (OFF_S1) corresponding to 1 horizontal period (1H), The first switch-on period (ON_S1) is repeated in two horizontal periods (2H).

The second normal switching control signal (SW_NOR2) has a second switch-on period (ON_S2) corresponding to 1 horizontal period (1H) and a second switch-off period (OFF_S2) corresponding to 1 horizontal period (1H), The second switch-on period (ON_S2) is repeated in two horizontal periods (2H).

The gate driver 150 outputs a normal gate signal having a gate-on period (ON_G) corresponding to two horizontal periods (2H) based on a normal gate control signal provided from the controller. As shown, the gate driver 150 sequentially outputs the first to nth general gate signals G_NOR1, G_NOR2, ..., G_NORn−1, and G_NORn.

The eleventh odd-numbered switch SW11 connected to the first gate line GL1 is turned on in response to the first switch-on period ON_S1 of the first normal switching control signal SW_NOR1 and the first switch-on period. The first normal gate signal G_NOR1 of the initial 1H period corresponding to (ON_S1) is applied to the first gate line GL1 as a first gate signal G1.

The twenty-first even-numbered switch SW21 connected to the second gate line GL2 is turned on in response to the second switch-on period ON_S2 of the second general switching control signal SW_NOR2, and accordingly, the second switch SW21 is turned on. The first normal gate signal G_NOR1 of the later 1H period corresponding to the on period ON_S2 is applied to the second gate line GL2 as a second gate signal G2.

In this way, the switching unit 170 receives the first to nth general gate signals output from the gate driver 150 in response to the first and second general switching control signals SW_NOR1 and SW_NOR2 ( G_NOR1, G_NOR2, ..., G_NORn-1, G_NORn) are sequentially provided to the first to Nth gate lines GL1, ..., GLN.

Referring to FIGS. 5 and 7 , the light driving unit 160 outputs a general light emission signal having a light on period (ON_E) corresponding to two horizontal periods (2H) based on a general light emission control signal provided from the controller. As shown, the light emitting driver 160 sequentially outputs the first to n th normal light emitting signals E_NOR1, E_NOR2, ..., E_NORn−1, and E_NORn.

The 31st odd-numbered switch SW31 connected to the first emission line EL1 is turned on in response to the first switch-on period ON_S1 of the first normal switching control signal SW_NOR1 and the first switch-on period. The first normal emission signal E_NOR1 of the initial 1H period corresponding to (ON_S1) is applied to the first emission line EL1 as the first emission signal E1.

The forty-first even-numbered switch SW41 connected to the second emission line EL2 is turned on in response to the second switch-on period ON_S2 of the second general switching control signal SW_NOR2, and accordingly, the second switch SW41 is turned on. The first normal light emitting signal E_NOR1 of the later 1H period corresponding to the on period ON_S2 is applied to the second light emitting line EL2 as the second light emitting signal E2.

In this way, the switching unit 170 outputs the first to n th general light emitting signals (output from the light emitting driver 160) in response to the first and second general switching control signals SW_NOR1 and SW_NOR2. E_NOR1, E_NOR2, ..., E_NORn-1, E_NORn) are sequentially provided to the first to Nth light emitting lines EL1, ..., ELN.

Referring to FIG. 8 , in the normal mode, the display unit displays a first pixel row PR1 , a second pixel row PR2 , a third pixel row PR3 , a fourth pixel row PR4 , and a fifth pixel row PR1 during one frame. The pixel row PR5 is sequentially driven, and all red, green, and blue pixels of the display unit emit light.

9 is a waveform diagram of gate signals of a display device according to an OPR mode according to an embodiment of the present invention. 10 is a waveform diagram of emission signals of a display device according to an OPR mode according to an embodiment of the present invention. 11A and 11B are conceptual views illustrating a driving method of a display device in an OPR mode according to an embodiment of the present invention.

5 and 9, in the OPR mode, the first switch unit 171 receives the first low grayscale switching control signal SW_OPR1, and the second switch unit 172 receives the second low grayscale switching control signal SW_OPR1. Receives control signal (SW_OPR2).

The first low grayscale switching control signal SW_OPR1 has a corresponding first switch-on period ON_S1 during an initial subframe (first subframe) and a corresponding first switch during a later subframe (second subframe). It has an off period (OFF_S1).

The second low grayscale switching control signal SW_OPR2 has a second switch-off period OFF_S2 corresponding to the first subframe and a second switch-on period ON_S1 corresponding to the second subframe.

The gate driver 150 outputs a low gray gate signal having a gate-on period (ON_G) corresponding to one horizontal period (1H) based on a low gray gate control signal provided from the controller.

As shown, the gate driver 150 sequentially outputs the first to nth low grayscale gate signals G_OPR1, G_OPR2,..., G_OPRn-1, G_OPRn during the first subframe SUB_FRAME1. and repeatedly outputs the first through nth low grayscale gate signals G_OPR1, G_OPR2, ..., G_OPRn-1, G_OPRn during the second subframe SUB_FRAME2.

During the first sub-frame SUB_FRAME1, the odd-numbered switches SW11, SW31, SW12, SW32, ..., SW1n, and SW3n of the first switch 171 control the first low grayscale switching control signal SW_OPR1. It is turned on in response to a first switch-on period (ON_S1) and the first through n-th low grayscale gate signals (G_OPR1, G_OPR2,... . It is applied as signals G1, G3, ..., GN-1.

Meanwhile, during the first subframe SUB_FRAME1, the even-numbered switches SW21, SW41, SW22, SW42, ..., SW2n, and SW4n of the second switch unit 172 transmit the second low grayscale switching control signal SW_OPR2. ) is turned off in response to the second switch-off period OFF_S2 and the even-numbered gate lines GL2, ..., GLN connected to the even-numbered switches SW21, SW22, .., SW2n have gates. No signal is applied.

During the second subframe SUB_FRAME2, the even-numbered switches SW21, SW41, SW22, SW42, ..., SW2n, and SW4n of the second switch 172 transmit the second low grayscale switching control signal SW_OPR2. 2 is turned on in response to a switch-on period (ON_S2) and the first to nth low grayscale gate signals (G_OPR1, G_OPR2,..., The even-numbered low-gray level gate signals (G_OPR2, ..., G_OPRn) of G_OPRn-1 and G_OPRn are connected to the even-numbered gate lines (GL2, ..., GLN) to the even-numbered gate signals (G2, G4, ..., G_OPRn). ., GN).

Meanwhile, during the second subframe SUB_FRAME1, the odd-numbered switches SW11, SW31, SW12, SW32, ..., SW1n, and SW3n of the first switch unit 171 transmit the first low grayscale switching control signal SW_OPR1. The odd-numbered gate lines GL1, GL3, ..., GLN- are turned off in response to the first switch-off period OFF_S1 of 1), no gate signal is applied.

Referring to FIGS. 5 and 10 , the light emitting driver 160 outputs a low gradation light emitting signal having a light emitting on period (ON_E) corresponding to one horizontal period (1H) based on a low gradation light emitting control signal provided from the control unit. do. As shown, the light emitting driver 160 sequentially outputs the first to nth low gray level light emitting signals EM_OPR1, EM_OPR2, ..., EM_OPRn-1, EM_OPRn during the first subframe SUB_FRAME1. EM_OPR1, EM_OPR2, ..., EM_OPRn-1, EM_OPRn are repeatedly output in sequence during the second subframe SUB_FRAME2.

During the first sub-frame SUB_FRAME1, the odd-numbered switches SW11, SW31, SW12, SW32, ..., SW1n, and SW3n of the first switch 171 control the first low grayscale switching control signal SW_OPR1. It is turned on in response to a first switch-on period (ON_S1) and the first to nth low grayscale light emitting signals EM_OPR1, EM_OPR2, ... , EM_OPRn-1, EM_OPRn), the odd-numbered low-gray level emission signals EM_OPR1, EM_OPR3, ..., EM_OPRn-1 emit odd-numbered emission signals on the odd-numbered emission lines EL1, EL3, ..., ELN-1. Signals EM1, EM3,..., EMN-1 are applied.

Meanwhile, during the first subframe SUB_FRAME1, the even-numbered switches SW21, SW41, SW22, SW42, ..., SW2n, and SW4n of the second switch unit 172 transmit the second low grayscale switching control signal SW_OPR2. The 1st to nth low grayscale light-emitting signals EM_OPR1, EM_OPR2, ..., EM_OPRn-1, EM_OPRn are turned off in response to the first switch-off period OFF_S2 of ) and output from the light-emitting driver 160. ) is not applied to the even-numbered light-emitting lines EL2, EM4, ..., ELN connected to the even-numbered switches SW41, SW42, ..., SW4n.

During the second subframe SUB_FRAME2, the even-numbered switches SW21, SW41, SW22, SW42, ..., SW2n, and SW4n of the second switch 172 transmit the second low grayscale switching control signal SW_OPR2. 2 The first to nth low-grayscale light-emitting signals (which are turned on in response to the switch-on period ON_S2 and output from the light-emitting driver 160 through the even-numbered switches SW41, SW42, ..., SW4n) The even-numbered low-gray level emission signals EM_OPR2, ..., EM_OPRn among EM_OPR1, EM_OPR2, ..., EM_OPRn-1, EM_OPRn are even-numbered light-emitting lines EL2, EL4, ..., ELN. It is applied as light emitting signals EM2, EM4, ..., EMN.

Meanwhile, during the second subframe SUB_FRAME1, the odd-numbered switches SW11, SW31, SW12, SW32, ..., SW1n, and SW3n of the first switch unit 171 transmit the first low grayscale switching control signal SW_OPR1. ) in response to the first switch-off period (OFF_S1), and accordingly, the first to nth low grayscale light emitting signals EM_OPR1, EM_OPR2, ..., EM_OPRn-1 output from the light emitting driver 160 , EM_OPRn) is not applied to the odd-numbered light-emitting lines EL1, EL3, ..., ELN-1 connected to the odd-numbered switches SW31, SW32, ..., SW3n.

Referring to FIG. 11A of the display unit in the OPR mode, odd-numbered pixel rows PR1 , PR3 , and PR5 are sequentially driven during the first subframe. Based on the on-pixel ratio (eg, 50%) according to the OPR mode, only some green pixels of odd-numbered pixel rows PR1 , PR3 , and PR5 emit light, and the remaining red, green, and sub-pixels do not emit light.

Referring to FIG. 11B , even-numbered pixel rows PR2 and PR4 are sequentially driven during the second subframe. All red, green, and blue pixels of even-numbered pixel rows PR2 and PR4 emit light based on the on-pixel ratio (eg, 50%) according to the OPR mode.

According to the above embodiment, in the frame image driven in the OPR mode, only odd-numbered horizontal lines are driven in the first subframe to display odd-numbered line images, and only even-numbered horizontal lines are driven in the second subframe to display even-numbered line images. display Accordingly, it is possible to improve a flicker phenomenon caused by light emitting pixels and non-emitting pixels according to the OPR mode.

The present invention can be applied to a display device and various devices and systems including the display device. Accordingly, the present invention relates to mobile phones, smart phones, PDAs, PMPs, digital cameras, camcorders, PCs, server computers, workstations, notebooks, digital TVs, set-top boxes, music players, portable game consoles, navigation systems, smart cards, and printers. It can be usefully used in various electronic devices such as

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the claims below. you will understand that you can

Claims (20)

a display unit including a plurality of pixels connected to a plurality of data lines and a plurality of gate lines crossing the plurality of data lines;
When the image data is a normal grayscale image, a normal gate signal having a first gate-on pulse is generated, and when the image data is a low-grayscale image, a low-grayscale gate signal having a second gate-on interval smaller than the first gate-on interval and a gate driver connected to at least two gate lines in one output channel; and
In the low grayscale image, the second gate-on period signal of the low grayscale gate signal is applied to odd-numbered gate lines during the first subframe, and the second gate signal of the low grayscale gate signal is applied to even-numbered gate lines during the second subframe. A display device including a switching unit for applying a gate-on signal. 2 . The method of claim 1 , wherein the switching unit applies an initial signal of the first gate-on period to the odd-numbered gate line and transmits a later signal of the first gate-on period to an even-numbered gate line during a frame in the normal grayscale image. A display device characterized by applying. The method of claim 1 , further comprising: a control unit calculating an on-pixel rate corresponding to image data of a current frame when the image data is the low-grayscale image, and generating correction data by correcting the image data based on the on-pixel rate; and
and a data driver configured to drive the plurality of data lines using the correction data. The method of claim 1 , wherein the switching unit includes first odd-numbered switches connected to the odd-numbered gate lines and first even-numbered switches connected to even-numbered gate lines,
The display device of claim 1 , wherein a first switching control signal is applied to the first odd-numbered switches, and a second switching control signal is applied to the first even-numbered switches. 5. The method of claim 4, wherein in the normal grayscale image, the first switching control signal has a switch-on period and a switch-off period corresponding to one horizontal period, and is delayed from the second switching control signal by one horizontal period. display device. 6. The method of claim 5 , wherein in the low grayscale image, the first switching control signal has a switch-on period and a switch-off period corresponding to a first subframe, and is delayed from the second switching control signal by a subframe. display device. 7. The method of claim 6, wherein the display unit further comprises a plurality of emission lines crossing the plurality of data lines and connected to the plurality of pixels,
When the image data is a normal grayscale image, a general light-emitting signal is generated in a first light-on period, and when the image data is a low-gray level image, a low-gray light-emitting signal having a second light-on period smaller than the first light-on period. and a light emitting driver connected to a plurality of light emitting lines in one output channel. The method of claim 7, wherein the switching unit
In the normal grayscale image, applying an initial signal of the first light-on period to odd-numbered light-emitting lines and applying a later signal of the first light-on period to even-numbered light-emitting lines during a frame;
In the low grayscale image, the signal of the second light-on section of the low-grayscale light-emitting signal is applied to the odd-numbered light-emitting lines during the first subframe, and the low-grayscale light-emitting signal is applied to the even-numbered light-emitting lines during the second subframe. A display device characterized in that a signal of a second light emission-on period of is applied. The method of claim 8, wherein the switching unit comprises second odd-numbered switches connected to the odd-numbered light-emitting lines and second even-numbered switches connected to even-numbered light-emitting lines,
A third switching control signal is applied to the second odd-numbered switches, and a fourth switching control signal is applied to the second even-numbered switches. 10. The method of claim 9, wherein in the normal grayscale image, the third switching control signal has a switch-on period and a switch-off period corresponding to one horizontal period, and is delayed from the fourth switching control signal by one horizontal period. display device. 11. The method of claim 10, wherein in the low grayscale image, the third switching control signal has a switch-on period and a switch-off period corresponding to a first subframe, and is delayed from the fourth switching control signal by a subframe. display device. The method of claim 8, wherein the switching unit comprises second odd-numbered switches connected to the odd-numbered light-emitting lines and second even-numbered switches connected to even-numbered light-emitting lines,
The display device of claim 1 , wherein the first switching control signal is applied to the second odd-numbered switches, and the second switching control signal is applied to the second even-numbered switches. In a method of driving a display device including a display unit including a plurality of data lines and a plurality of pixels connected to a plurality of gate lines crossing the plurality of data lines,
generating a normal gate signal having a first gate-on pulse when the image data is a normal grayscale image;
generating a low grayscale gate signal having a second gate-on interval smaller than the first gate-on interval when the image data is a low-grayscale image;
In the low grayscale image, the signal of the second gate-on period of the low grayscale gate signal is applied to odd-numbered gate lines during the first subframe, and the third gate signal of the low grayscale gate signal is applied to the even-numbered gate lines during the second subframe. 2 A method of driving a display device comprising applying a gate-on signal. 14. The method of claim 13, wherein in the normal grayscale image, an initial signal of the first gate-on period is applied to the odd-numbered gate line and a later signal of the first gate-on period is applied to the even-numbered gate line during a frame. A method of driving a display device, characterized in that for doing. 14. The method of claim 13, further comprising: calculating an on-pixel rate corresponding to image data of a current frame when the image data is the low grayscale image;
generating correction data by correcting image data based on the on-pixel rate; and
and applying a data voltage to the plurality of data lines using the correction data. 14. The method of claim 13, wherein the display unit further comprises a plurality of emission lines crossing the plurality of data lines and connected to the plurality of pixels,
generating a general emission signal for a first emission-on period when the image data is a general grayscale image; and
and generating a low-gray light emitting signal having a second light-on period smaller than the first light-on period when the image data is a low-gray level image. 17. The method of claim 16, wherein in the normal grayscale image, an initial signal of the first light-on period is applied to odd-numbered light-emitting lines and a later signal of the first light-on period is applied to even-numbered light-emitting lines during a frame;
In the low grayscale image, the signal of the second light-on section of the low-grayscale light-emitting signal is applied to the odd-numbered light-emitting lines during the first subframe, and the low-grayscale light-emitting signal is applied to the even-numbered light-emitting lines during the second subframe. A method of driving a display device, characterized in that by applying a signal of a second light-on period of . The display device of claim 13 , wherein the display device comprises first odd-numbered switches connected to the odd-numbered gate lines and first even-numbered switches connected to even-numbered gate lines, and second odd-numbered switches connected to odd-numbered emission lines. and second even-numbered switches connected to the even-numbered light emitting lines;
The method of claim 1 , wherein a first switching control signal is applied to the first and second odd-numbered switches, and a second switching control signal is applied to the first and second even-numbered switches. 19. The method of claim 18, wherein in the normal grayscale image, the first switching control signal has a switch-on period and a switch-off period corresponding to one horizontal period, and is delayed from the second switching control signal by one horizontal period. How to drive a display device. 19. The method of claim 18, wherein in the low grayscale image, the first switching control signal has a switch-on period and a switch-off period corresponding to a first subframe, and is delayed from the second switching control signal by a subframe. How to drive a display device.

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