KR102664004B1 - Display device, data driver and method for driving thereof - Google Patents

Abstract

The present embodiments relate to a display device driven by a DRD (Double Rate Driving) method and a data driver included therein. When a subpixel displaying the same color repeats strong and weak charging along a data line, the device is applied during weak charging. By overshooting and outputting the waveform of the initial section of the data voltage, the pre-charging delay according to the applied data voltage can be reduced. By reducing the pre-charging delay during weak charging of subpixels where strong and weak charging are repeated, the difference in charge amount between subpixels due to pre-charging delay is reduced and the image such as luminance difference and vertical dim due to the difference in charge amount is reduced. Make sure nothing goes wrong.

Description

Display device, data driver, and data driver driving method {DISPLAY DEVICE, DATA DRIVER AND METHOD FOR DRIVING THEREOF}

These embodiments relate to a display device, a data driver included in the display device, and a method of driving the same.

As the information society develops, various demands for display devices that display images are increasing, and various types of display devices such as liquid crystal displays, plasma displays, and organic light emitting displays are being used.

In such a display device, a plurality of gate lines and a plurality of data lines are arranged to intersect on the display panel, and a plurality of subpixels are arranged in the area where the gate lines and data lines intersect.

Each subpixel is driven by a scan signal applied through a gate line, and displays an image by expressing gray levels according to the data voltage applied through the data line in accordance with the timing when the scan signal is applied.

Data lines to which such data voltages are applied may be arranged one by one for each column of subpixels.

Recently, in order to reduce the number of source driver integrated circuits driving the data lines, DRDs have been developed that place one data line per column of two subpixels and drive two subpixels with one data line placed on either side. (Double Rate Driving) structure is being applied.

In the DRD-type subpixel structure, a data voltage for driving two subpixels is applied through a data line during one horizontal period.

Additionally, a display device driven by the DRD method applies a data voltage with the polarity reversed to each subpixel row in order to minimize flicker and reduce power consumption.

That is, in the DRD method, two data voltages with positive polarity (+) are applied during one horizontal period, and two data voltages with negative polarity (-) are applied during the next horizontal period.

At this time, the data voltage applied to the subpixel may have the same polarity as the data voltage applied to the previous subpixel, or a data voltage with the polarity reversed may be applied.

When a data voltage with a polarity reversed from the data voltage applied to the previous subpixel is applied, the pre-charging time required to reach the level of the data voltage applied to the subpixel increases as the polarity is reversed. It gets longer.

Due to this pre-charging delay, a difference occurs between subpixels with a short pre-charging time and the charging amount, and there is a problem of image abnormalities such as vertical dims where luminance between subpixels becomes uneven due to the difference in charging amount.

The purpose of the present embodiments is to provide a display device, a data driver, and a driving method that prevent image abnormalities such as vertical dimming due to differences in charging amounts of subpixels in a double rate driving (DRD) display device.

The purpose of the present embodiments is to provide a display device, a data driver, and a driving method that can easily resolve differences in the charging amount of subpixels depending on the characteristics of the display panel in a DRD type display device.

In one aspect, the present embodiments include a display panel in which a plurality of subpixels are arranged along rows and columns, and two subpixels arranged on both sides, one in each column of the two subpixels arranged in the display panel. A display device including a plurality of data lines that transmit voltage and a data driver that drives the plurality of data lines is provided.

The data driver of such a display device outputs two data voltages supplied to two subpixels placed on both sides of one data line during one horizontal period, with the subpixels placed on one side of the data line and the other provided on the other side. The data voltage is alternately applied to the subpixels.

In addition, the data driver supplies a data voltage with the polarity reversed for each row of subpixels through multiple data lines, and displays the same color among multiple subpixels and repeats strong and weak charging depending on the data lines. The waveform of the initial section of the data voltage applied when the pixel is lightly charged is modulated and output.

As an example, the data driver modulates the waveform of the initial section of the data voltage applied to the subpixel to which the data voltage applied to the previous subpixel and the data voltage of the inverted polarity are applied in the subpixel where strong charging and weak charging are repeated. do.

At this time, the data driver may modulate and output the waveform of the initial section of the data voltage applied when the subpixel is lightly charged in accordance with the timing of the source output enable signal received from the controller.

Here, the data driver may amplify and output the waveform of the initial section of the data voltage applied during weak charging of the subpixel where strong charging and weak charging are repeated.

Specifically, if the data voltage applied during weak charging of the subpixel is (+) polarity, the waveform of the initial section of the data voltage is amplified in the (+) direction, and if the data voltage is (-) polarity, the waveform of the initial section of the data voltage is amplified in the (-) direction. Amplifies the waveform of the section.

Alternatively, the data driver sets the initial section of the data voltage applied during weak charging of the subpixel in which strong charging and weak charging are repeated as part of the section to which the data voltage is applied, and in the initial section of the data voltage according to the length of the set initial section. You can also decide the voltage level to amplify.

The data driver described above includes a data voltage generator that generates a data voltage by converting the image data signal received from the controller, and an initial section of the data voltage applied at the timing when the polarity is inverted among the data voltages supplied to a specific data line. It may include a data modulation waveform generator that modulates the waveform, and a data voltage output portion that outputs the modulated data voltage through a specific data line.

Additionally, the data modulation waveform generator of the data driver may include a delay circuit that adjusts the initial section of the data voltage and a voltage amplifier that amplifies the voltage level of the initial section of the data voltage.

This data driver converts the image data signal received from the controller to generate a data voltage, and generates a waveform of the initial section of the data voltage supplied to a specific data line in accordance with the timing of the source output enable signal received from the controller. It can be driven in a step of modulating and a step of outputting a data voltage having a modulated waveform.

According to the present embodiments, in a DRD (Double Rate Driving) display device, pre-charging of the data voltage is performed by amplifying the waveform of the initial section of the data voltage applied during weak charging of the subpixel where strong charging and weak charging are repeated. Allows to reduce delay.

According to the present embodiments, by reducing the pre-charging delay of the data voltage applied during weak charging, the difference in charge amount compared to the case of strong charging is reduced to prevent vertical dims due to the difference in charge amount.

According to the present embodiments, vertical dims are improved through waveform modulation of the initial section of the data voltage applied during weak charging, so that the improvement method can be easily applied according to the characteristics of the display panel.

1 is a diagram showing a schematic configuration of a display device according to the present embodiments.
Figure 2 is a diagram showing an example of a subpixel structure of a display device according to the present embodiments.
Figure 3 is a diagram showing an example of a subpixel driving method of a display device according to the present embodiments.
FIG. 4 is a diagram illustrating examples of waveforms of a scan signal and a data voltage applied when driving a subpixel of a display device according to the present embodiments.
Figure 5 is a diagram showing an example of the data voltage charging state of a subpixel when driven according to the method of Figures 3 and 4.
Figure 6 is a diagram illustrating an example of modulation of a data voltage in a display device according to the present embodiments.
Figure 7 is a diagram showing a method of modulating data voltage in the display device according to the present embodiments.
Figure 8 is a diagram showing an example of a waveform of a data voltage applied to each data line in the display device according to the present embodiments.
FIG. 9 is a diagram illustrating an example of the driving state of a subpixel for each data line in the display device according to the present embodiments.
Figure 10 is a diagram showing the schematic configuration of a data driver in the display device according to the present embodiments.
Figure 11 is a flowchart showing the process of a data driver driving method according to the present embodiments.

Hereinafter, some embodiments of the present invention will be described in detail with reference to the exemplary drawings. In adding reference numerals to components in each drawing, identical components may have the same reference numerals as much as possible even if they are shown in different drawings. Additionally, when describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description may be omitted.

Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the essence, sequence, order, or number of the components are not limited by the term. When a component is described as being “connected,” “coupled,” or “connected” to another component, that component may be directly connected or connected to that other component, but there are no other components between each component. It should be understood that may be “interposed” or that each component may be “connected,” “combined,” or “connected” through other components.

Figure 1 shows a schematic configuration of a display device 100 according to the present embodiments.

Referring to FIG. 1, the display device 100 according to the present embodiments has a plurality of gate lines (GL) and a plurality of data lines (DL) arranged, and the gate lines (GL) and data lines (DL) intersect. A display panel 110 including a plurality of subpixels arranged in an area, a gate driver 120 driving a plurality of gate lines GL, and a data voltage supplying data to the data lines DL. It includes a driver 130 and a controller 140 that controls the operation of the gate driver 120 and data driver 130.

The gate driver 120 sequentially drives a plurality of gate lines GL by sequentially supplying scan signals (gate signals) to the plurality of gate lines GL.

The gate driver 120 sequentially supplies gate signals of an ON voltage or an OFF voltage to the plurality of gate lines GL according to the control of the controller 140. Operates sequentially.

The gate driver 120 may be located on only one side or both sides of the display panel 110 depending on the driving method.

Additionally, the gate driver 120 may include one or more gate driver integrated circuits.

Each gate driver integrated circuit is connected to a bonding pad of the display panel 110 using a Tape Automated Bonding (TAB) method or a Chip On Glass (COG) method, or is connected to a bonding pad (GIP) of the display panel 110. It can be implemented as a Gate In Panel (Gate In Panel) type and placed directly on the display panel 110.

Additionally, it may be integrated and disposed on the display panel 110, or may be implemented using a chip on film (COF) method that is mounted on a film connected to the display panel 110.

The data driver 130 drives multiple data lines DL by supplying data voltages to the multiple data lines DL.

When a specific gate line (GL) is opened, the data driver 130 converts the image data received from the controller 140 into an analog data voltage and supplies it to the plurality of data lines (DL). Run .

The data driver 130 may include at least one source driver integrated circuit and drive multiple data lines DL.

Each source driver integrated circuit is connected to a bonding pad of the display panel 110 using a tape automated bonding (TAB) method or a chip on glass (COG: chip on glass) method. It may be placed directly on 110 or may be integrated and placed on the display panel 110.

Additionally, each source driver integrated circuit may be implemented in a chip on film (COF: Chip On Film) method. In this case, one end of each source driver integrated circuit is bonded to at least one source printed circuit board (Source Printed Circuit Board), and the other end is bonded to the display panel 110.

The controller 140 controls the gate driver 120 and the data driver 130 by supplying various control signals to the gate driver 120 and the data driver 130.

This controller 140 starts scanning according to the timing implemented in each frame, converts the input image data input from the outside to fit the data signal format used by the data driver 130, and outputs the converted image data. , Control data drive at an appropriate time according to the scan.

The controller 140 sends various timing signals including a vertical synchronization signal (Vsync), a horizontal synchronization signal (Hsync), an input data enable (DE) signal, and a clock signal (CLK) along with input image data. Receive from outside (e.g. host system).

The controller 140 converts the input image data input from the outside to suit the data signal format used by the data driver 130 and outputs the converted image data, as well as the gate driver 120 and the data driver 130. In order to control, timing signals such as vertical synchronization signal (Vsync), horizontal synchronization signal (Hsync), input data enable signal (DE), and clock signal (CLK) are input, and various control signals are generated to generate gate driver ( 120) and data driver 130.

For example, in order to control the gate driver 120, the controller 140 generates a gate start pulse (GSP), a gate shift clock (GSC), and a gate output enable signal (GOE: Outputs various gate control signals (GCS: Gate Control Signal) including Gate Output Enable.

Here, the gate start pulse (GSP) controls the operation start timing of one or more gate driver integrated circuits constituting the gate driver 120. The gate shift clock (GSC) is a clock signal commonly input to one or more gate driver integrated circuits, and controls the shift timing of the gate signal. The gate output enable signal (GOE) specifies timing information of one or more gate driver integrated circuits.

In addition, the controller 140 uses a source start pulse (SSP), a source sampling clock (SSC), and a source output enable signal (SOE) to control the data driver 130. Outputs various data control signals (DCS: Data Control Signal) including Enable).

Here, the source start pulse (SSP) controls the data sampling start timing of one or more source driver integrated circuits constituting the data driver 130. The source sampling clock (SSC) is a clock signal that controls the sampling timing of data in each source driver integrated circuit. The source output enable signal (SOE) controls the output timing of the data driver 130.

The controller 140 is a control printed circuit board connected to a source printed circuit board to which a source driver integrated circuit is bonded through a connection medium such as a flexible flat cable (FFC: Flexible Flat Cable) or a flexible printed circuit (FPC: Flexible Printed Circuit). It can be placed on the (Control Printed Circuit Board).

On this control printed circuit board, a power controller (not shown) is further disposed to supply various voltages or currents to the display panel 110, gate driver 120, and data driver 130, or to control various voltages or currents to be supplied. It can be. These power controllers are also called power management integrated circuits (Power Management ICs).

The subpixel is disposed in an area where the gate line GL and the data line DL intersect in the display panel 110.

The subpixel is driven by a scan signal applied by the gate driver 120, and displays an image by expressing gray levels according to the data voltage applied from the data driver 130 in accordance with the timing when the scan signal is applied.

These subpixels may be composed of circuit elements such as transistors and capacitors, and may be designed in various ways depending on the characteristics of the display device 100.

Figure 2 shows an example of a subpixel structure in the display device 100 according to the present embodiments, and shows an example of a subpixel structure in a liquid crystal display device.

Referring to FIG. 2, the subpixel of the display device 100 according to the present embodiments is defined in the area where the gate line (GL) and the data line (DL) intersect, and the transistor (TR) and liquid crystal capacitor (Clc) , storage capacitor (Cst), etc.

The transistor TR is electrically connected between the data line DL and the pixel electrode and is controlled by a signal applied to the gate line GL.

The transistor TR is turned on when a scan signal is applied through the gate line GL and applies the data voltage supplied through the data line DL to the pixel electrode.

The liquid crystal capacitor Clc is electrically connected between the pixel electrode and the common electrode and is charged by the voltage difference between the data voltage applied to the pixel electrode and the common voltage applied to the common electrode when the transistor TR is turned on. .

The storage capacitor (Cst) is charged at the same time as the liquid crystal capacitor (Clc) and serves to reduce the voltage drop of the liquid crystal capacitor (Clc) due to leakage current when the transistor (TR) is turned off, providing stable grayscale expression for one frame. make it possible

Data lines DL that transmit data voltage to subpixels are arranged one by one in each column of one subpixel and transmit data voltage to one subpixel during one horizontal period.

In this case, a source driver integrated circuit driving the data line DL is required as many columns of subpixels.

In order to reduce the number of source driver integrated circuits, one data line (DL) is arranged in each column of two subpixels, and the data voltage is supplied to the two subpixels arranged on both sides of one data line (DL). The supplied DRD (Double Rate Driving) method can be used.

FIG. 3 is for explaining the structure and driving method when the display device 100 according to the present embodiments is driven in the DRD method.

Referring to FIG. 3, a case where the display device 100 according to the present embodiments is a liquid crystal display device is shown, and a case where subpixels are composed of red (R), green (G), and blue (B) is shown. .

The display device 100 driven in the DRD method has one data line (DL) disposed in each of two subpixel columns in the display panel 110, and two gate lines (GL) above and below each subpixel row. ) is placed.

During one horizontal cycle, data voltage is supplied to two subpixels through one data line (DL), and the gate line (GL) is driven at twice the frequency compared to normal driving to scan each subpixel. Apply a signal.

In addition, in order to minimize the occurrence of flicker and reduce power consumption, data voltages are alternately applied to subpixels arranged on both sides of one data line DL, and a data voltage with the polarity reversed is applied to each row of the subpixels. Authorize.

Taking the case where the first data line DL1 shown in FIG. 3 is driven as an example, two data voltages with positive polarity are applied to the red (R) subpixel and the green (G) subpixel during one horizontal period. are approved sequentially.

During the next horizontal period, two data voltages with (-) polarity are sequentially applied to the red (R) subpixel and the green (G) subpixel.

Likewise, two data voltages are sequentially applied to subpixels disposed on both sides of the data line DL during one horizontal period through the second data line DL2 and the third data line DL3, and the subpixels are sequentially applied through the second data line DL2 and the third data line DL3. A data voltage with the polarity reversed is applied to each row.

At this time, a pre-charging delay occurs in the subpixel to which the data voltage is applied at the timing when the polarity of the data voltage is reversed, resulting in a relatively weakly charged state.

For example, the green (G) subpixel driven by the first data line DL1 is applied with a data voltage having the same polarity as the red (R) subpixel to which the data voltage was previously applied, and thus is subject to pre-charging. Because the time required is short, no pre-charging delay occurs, resulting in a strong charging state.

On the other hand, a pre-charging delay occurs in the red (R) subpixel driven by the first data line DL1 because a data voltage having an inverted polarity is applied to the green (G) subpixel to which a data voltage was previously applied. This results in a weakly charged state.

The strong charge and weak charge of each subpixel can be clearly confirmed through the waveform of the data voltage applied to the data line (DL).

FIG. 4 shows waveforms of scan signals and data voltages applied when the display device 100 according to the present embodiments is driven in the DRD method.

Referring to FIG. 4, a scan signal is sequentially applied to the first gate line GL1 to the fourth gate line GL4, and two data voltages are applied to the first data line DL1 during one horizontal period. .

During the first horizontal cycle, two data voltages with (+) polarity are applied, and during the second horizontal cycle, two data voltages with (-) polarity are applied.

The first data voltage applied during the first horizontal cycle is applied to the red (R) subpixel driven by the first gate line (GL1), and the second data voltage is applied to the green subpixel driven by the second gate line (GL2). (G) Approved as a subpixel.

Therefore, the red (R) subpixel to which the data voltage is applied at the timing when the polarity is reversed is in a weakly charged state due to the pre-charging delay, and the green (G) subpixel to which the data voltage of the same polarity is applied is in a pre-charging state. There is no delay, so it is in a strong charging state.

The first data voltage applied during the second horizontal cycle is applied to the red (R) subpixel driven by the third gate line (GL3), and the second data voltage is applied to the green subpixel driven by the fourth gate line (GL4). (G) Approved as a subpixel.

Likewise, the red (R) subpixel is in a weakly charged state due to the pre-charging delay as the data voltage at the timing of the polarity inversion is applied, and the green (G) subpixel is in a weakly charged state due to the pre-charging delay due to the data voltage of the same polarity being applied. There is no delay, so it is in a strong charging state.

Accordingly, a relative strong charge state and a weak charge state appear for each row of subpixels driven by the data line DL.

Figure 5 shows an example in which a strong charge state and a weak charge state occur in the above-described subpixel structure.

Referring to FIG. 5, the row of red (R) subpixels driven by the first data line DL1 is in a weakly charged state, and the row of green (G) subpixels is in a strongly charged state.

Additionally, the row of blue (B) subpixels driven by the second data line DL2 is in a strongly charged state, and the row of red (R) subpixels is in a weakly charged state.

Additionally, the row of green (G) subpixels driven by the third data line DL3 is in a strongly charged state, and the row of blue (B) subpixels is in a weakly charged state.

Therefore, when subpixels are composed of red (R), green (G), and blue (B) and are driven in the DRD method described above, all rows of red (R) subpixels are in a weakly charged state and green (G) subpixels are in a weakly charged state. All rows of subpixels are in a highly charged state. On the other hand, the row of blue (B) subpixels repeats the strongly charged state and weakly charged state depending on the data line (DL).

In other words, red (R) subpixels or green (G) subpixels repeat the same charging state, so image abnormalities such as vertical dims are not recognized well, but like blue (B) subpixels, strong charging and weak charging are repeated. In this case, there is a problem in which image abnormalities such as vertical dimming are recognized.

When driven in the DRD method, the display device 100 according to the present embodiments reduces the pre-charging delay of the subpixel row where strong charging and weak charging are repeated, thereby reducing the vertical charge due to repeated strong charging and weak charging. Helps improve dims.

FIG. 6 shows an example of a modulation waveform of a data voltage when the display device 100 according to the present embodiments is driven in the DRD method.

Referring to FIG. 6, during normal driving, the data driver 130 converts the image data signal and outputs the waveform of the generated data voltage as is to the data line DL.

Even if the data driver 130 generates and outputs a waveform of the data voltage at a level according to the grayscale of the image data, if the data voltage and polarity applied to the previous subpixel are reversed, the time required for pre-charging becomes longer. .

Therefore, as shown in Normal Driving of FIG. 6, the pre-charging time for the voltage charged in the subpixel to reach the level of the data voltage applied through the data line DL becomes long.

Due to this pre-charging delay, the data voltage charge amount of the subpixel is reduced, and a difference in luminance between subpixels may occur due to the difference with the data voltage charge amount of the subpixel in which no pre-charging delay occurs.

The display device 100 according to the present embodiments reduces the time required for pre-charging by modulating the waveform of the initial section of the data voltage applied to the specific data line DL, thereby reducing the amount of charge due to the pre-charging delay. Prevent decline from occurring.

Referring to overshooting driving shown in FIG. 6, the data driver 130 generates a data voltage according to the image data signal, modulates the waveform of the initial section of the generated data voltage, and outputs it.

The waveform of the initial section of the data voltage may be amplified from the level of the generated data voltage.

By amplifying the waveform of the initial section of the data voltage to a certain level, the time required for pre-charging is reduced and the charge amount does not decrease due to pre-charging delay.

That is, by modulating only the initial section of the data voltage waveform, the pre-charging delay is reduced and the gray scale according to the level of the data voltage can be expressed as is.

The initial section in which the waveform of the data voltage is modulated can be set based on the time when the pre-charging delay of the data voltage occurs, and the voltage level amplified in the initial section of the data voltage can be set according to the length of the initial section. .

For example, the initial section in which the waveform of the data voltage is modulated may be set to the same time as the time required for pre-charging in another data voltage in which the waveform of the data voltage is not modulated.

Additionally, the voltage level to be amplified in the initial section of the data voltage can be set so that the charged voltage reaches the level of the data voltage at the end point of the initial section where the waveform of the data voltage is modulated.

Therefore, the pre-charging time of the data voltage applied to the data line DL can be controlled through waveform modulation of the initial section of the data voltage, and the length of the initial section and the voltage level amplified in the initial section can be adjusted to control other data. By making the voltage the same as the pre-charging time, it is possible to prevent differences in charge amount due to differences in pre-charging time.

By preventing differences in the charge amount of data voltage between subpixels, it is possible to prevent image abnormalities such as brightness unevenness and vertical dims that occur due to differences in charge amount due to pre-charging delay.

FIG. 7 shows an example of a method of modulating the waveform of a data voltage in the display device 100 according to the present embodiments.

Referring to FIG. 7, the data driver 130 receives a source output enable signal (SOE), which is a signal for controlling the operation of the data driver 130, from the controller 140, and receives an image data signal for displaying an image. Receive.

The data driver 130 converts the image data signal to generate a data voltage and supplies it to each data line DL according to the timing of the source output enable signal SOE.

The data driver 130 may convert the image data signal and output the generated data voltage waveform as is (Vdata in FIG. 7).

Alternatively, the data voltage applied to the specific data line DL may be output by modulating the waveform of the initial section of the data voltage applied at the timing when the polarity is inverted (Vdata' in FIG. 7).

Here, the specific data line (DL) is a data line (DL) that transmits a data voltage to a weakly charged subpixel among the rows of subpixels that are repeatedly strongly and weakly charged in a row of subpixels displaying the same color. it means.

In other words, if all rows of subpixels displaying the same color are only in a strongly charged state or only in a weakly charged state, there is no difference in luminance between subpixels, so image abnormalities such as vertical dims are not recognized well.

On the other hand, when a row of subpixels displaying the same color repeats strong and weak charging depending on the data line (DL), a difference in luminance between subpixels occurs due to the difference in charging amount, and is recognized as an image abnormality such as vertical dimming. It will happen.

Accordingly, when a row of subpixels displaying the same color is only strongly charged or only weakly charged, the data driver 130 outputs a data voltage waveform such as Vdata and applies it to the data line DL.

In addition, when the row of subpixels displaying the same color is repeatedly strongly and weakly charged according to the data line (DL), a data voltage waveform such as Vdata is output to the row of the strongly charged subpixel as well, and the data line (DL) ) is approved.

In addition, the data voltage applied to the row of subpixels where strong charging and weak charging are repeated is output as a data voltage waveform such as Vdata' to reduce the time required for pre-charging. .

A data voltage waveform such as 'Vdata' can be generated by amplifying the waveform of the initial section of the data voltage in accordance with the timing of the source output enable signal (SOE) from the waveform of the data voltage generated by converting the image data signal.

Like 'Vdata', the initial section of the data voltage is overshooted, reducing the time required for pre-charging, thereby preventing a decrease in the data voltage charge amount of the corresponding subpixel and preventing uneven brightness and vertical dimming due to differences in charge amount. Prevent this from happening.

Hereinafter, with reference to FIGS. 8 and 9, specific examples of the above-described data voltage modulation waveform and the phenomenon of vertical dim improvement resulting therefrom will be described in detail.

FIG. 8 shows the data voltage waveform applied to each data line DL when the display device 100 according to the present embodiments is driven in the DRD method, and each data in the subpixel structure shown in FIG. 3 This shows the data voltage waveform applied to the line (DL).

Referring to FIG. 8, Vdata_DL1, which is a data voltage applied to the first data line DL1, is applied as a data voltage waveform during normal driving.

The red (R) subpixel to which the data voltage is applied by the first data line (DL1) is a subpixel that is weakly charged for every data line (DL), and the green (G) subpixel is a subpixel that is strongly charged for every data line (DL). Because it is a charged subpixel, vertical dims are not recognized well.

Accordingly, Vdata_DL1, which is the data voltage applied to the first data line DL1, is applied as the data voltage waveform during normal driving without waveform modulation.

Vdata_DL2, which is the data voltage applied to the second data line DL2, is also applied as the data voltage waveform during normal driving.

Among the subpixels to which the data voltage is applied through the second data line DL2, the red (R) subpixel is a subpixel that is weakly charged in all data lines DL, so there is no need to modulate the waveform of the data voltage.

Also, among the subpixels to which the data voltage is applied by the second data line DL2, the blue (B) subpixel undergoes repeated strong and weak charges depending on the data line DL, but is not connected to the second data line DL2. When a data voltage is applied, a data voltage of the same polarity as the previous subpixel is applied, so the subpixel is in a strongly charged state.

Therefore, since waveform modulation of the data voltage applied to the blue (B) subpixel is not required, the data voltage Vdata_DL2 applied to the second data line DL2 is applied as the waveform during normal driving.

Vdata_DL3, which is the data voltage applied to the third data line DL3, is applied as a data voltage waveform during overshooting driving.

Among the subpixels to which the data voltage is applied by the third data line DL3, the green (G) subpixel is a subpixel that is strongly charged in all data lines DL, so waveform modulation of the data voltage is not required.

On the other hand, the blue (B) subpixel to which the data voltage is applied by the third data line (DL3) repeats strong and weak charging according to the data line (DL), and the data voltage applied to the previous subpixel is inverted. Since the data voltage of the polarity is applied, it is in a weakly charged state due to the pre-charging delay.

Accordingly, the blue (B) subpixel to which the data voltage is applied by the second data line (DL2) is in a strongly charged state, and the blue (B) subpixel to which the data voltage is applied by the third data line (DL3) is in a strongly charged state. Because it is in a weakly charged state, vertical dimming may occur due to differences in luminance.

Therefore, the timing at which the polarity of the data voltage applied to the third data line DL3 is reversed, that is, the initial section of the data voltage applied to the blue (B) subpixel, is amplified and output.

Due to this overshooting driving, the pre-charging delay of the blue (B) subpixel driven by the third data line DL3 is reduced, and the reduction of the pre-charging delay causes the second data line (DL3) to decrease. Compared to the blue (B) subpixel driven by DL2), it is not in a relatively weakly charged state.

Since the blue (B) subpixel driven by the third data line DL3 is not in a weakly charged state, the luminance difference with the blue (B) subpixel driven by the second data line DL2 is reduced to increase the brightness. Ensure that vertical dims caused by traffic are not recognized.

FIG. 9 shows the driving state of each subpixel driven according to the data voltage waveform of FIG. 8.

Referring to FIG. 9, both the red (R) subpixel driven by the first data line (DL1) and the red (R) subpixel driven by the second data line (DL2) have the polarity of the data voltage reversed. The data voltage is applied at the timing to enter a weakly charged state.

In addition, the data voltages of both the green (G) subpixel driven by the first data line DL1 and the green (G) subpixel driven by the third data line DL3 are applied with the same polarity, making them strong. It is in charging state.

Accordingly, the red (R) subpixel is in a weakly charged state for each data line (DL), and the green (G) subpixel is in a strongly charged state for each data line (DL), so that vertical dims due to the luminance difference are not well recognized, so modulation is possible. It is driven by a normal driving method that drives with an unused data voltage waveform.

When the blue (B) subpixel is driven by the second data line DL2, the data voltage is applied with the same polarity and is in a strongly charged state. And, when driven by the third data line DL3, the polarity of the data voltage is applied at a reversed timing, resulting in a weakly charged state.

Since the blue (B) subpixel repeats strong and weak charging for each data line (DL), a vertical dim due to a difference in luminance can be recognized.

Therefore, the data voltage applied from the blue (B) subpixel, in which strong and weak charging is repeated, to the blue (B) subpixel driven by the weakly charged third data line (DL3), is overshooting driving. This reduces pre-charging delay.

As the pre-charging time of the blue (B) subpixel driven by the third data line DL3 decreases, the difference in charging amount with the blue (B) subpixel driven by the second data line DL2 decreases. This can prevent burn abnormalities such as vertical dimming from occurring due to differences in charge amount.

FIG. 10 shows the configuration of the data driver 130 that outputs a data voltage waveform for normal driving and a data voltage modulation waveform for overshooting driving in the display device 100 according to the present embodiments. will be.

Referring to FIG. 10 , the data driver 130 according to the present embodiments includes a data voltage generator 131, a data modulation waveform generator 132, and a data voltage output 133.

Additionally, the data modulation waveform generator 132 may include a voltage amplifier 132a and a delay circuit 132b.

When the data voltage generator 131 receives an image data signal from the controller 140, it converts the received image data signal to generate an analog data voltage.

The data modulation waveform generator 132 outputs the data voltage generated by the data voltage generator 131 as is or modulates the waveform of the generated data voltage and outputs it.

The data modulation waveform generator 132 may modulate and output the waveform of the initial section of the data voltage applied to the specific data line DL.

For example, depending on the data voltage applied to the subpixel displaying the same color, the waveform of the initial section of the data voltage applied during weak charging of the subpixel, which repeats strong and weak charging due to the pre-charging delay, may be amplified and output. You can.

The data modulation waveform generator 132 generates an initial section of the data voltage applied during weak charging of the subpixel in which strong charging and weak charging are repeated in accordance with the timing of the source output enable signal (SOE) received from the controller 140. Modulate the waveform.

Waveform modulation of the data voltage may be performed by the voltage amplifier 132a and the delay circuit 132b included in the data modulation waveform generator 132.

The voltage amplifier 132a amplifies the voltage level of the initial section of the data voltage generated by the data voltage generator 131, and the delay circuit 132b adjusts the initial section of the data voltage for which the voltage level is amplified.

In order to reduce pre-charging delay, the initial period of the data voltage may be set to the same time as the pre-charging time of the data voltage applied to the subpixel in which no pre-charging delay occurs.

The voltage level amplified in the initial section of the data voltage may be set according to the length of the initial section set to reduce pre-charging delay.

That is, the shorter the length of the initial section in which the waveform is modulated, the larger the amplified voltage level can be set, and if the length of the initial section is longer, the amplified voltage level can be set relatively small.

The data voltage of the waveform modulated by the data modulation waveform generator 132 is transmitted to the data voltage output unit 133.

The data voltage output unit 133 outputs the data voltage received from the data modulation waveform generator 132 to each data line DL.

Through this, when a subpixel displaying the same color is only strongly charged or only weakly charged, a data voltage whose waveform is not modulated is applied.

And, among the subpixels where strong and weak charging are repeated, the data voltage whose waveform is not modulated is applied to the strongly charged subpixel, and the waveform of the initial section of the data voltage is amplified to the weakly charged subpixel. This ensures that vertical dims do not occur due to differences in charge amount in subpixels displaying the same color.

Figure 11 shows the process of the driving method of the data driver 130 according to the present embodiments.

Referring to FIG. 11, the data driver 130 according to the present embodiments receives a source output enable signal (SOE) and an image data signal from the controller 140 (S1100).

The data driver 130 converts the received image data signal to generate an analog data voltage waveform (S1110).

The data driver 130 checks whether the generated data voltage is a data voltage applied to a specific data line DL (S1120).

Here, the specific data line DL refers to a data line DL that applies a data voltage from a subpixel that is repeatedly strongly and weakly charged to a weakly charged subpixel among subpixels that display the same color.

The data driver 130 modulates the data voltage applied during weak charging of a subpixel in which strong charging and weak charging are repeated by amplifying the initial section in accordance with the timing of the source output enable signal (SOE) (S1130).

The data driver 130 outputs a data voltage with an unmodulated waveform and a data voltage with a modulated waveform to each data line DL (S1140).

Therefore, according to the present embodiments, the pre-charging delay of the weakly charged subpixel can be reduced by modulating and applying the waveform of the initial section of the data voltage applied during weak charging of the subpixel where strong charging and weak charging are repeated. make it possible

By reducing the pre-charging delay of a weakly charged subpixel, the difference in relative charge amount with that of a strongly charged subpixel is reduced, and image abnormalities such as luminance difference and vertical dimming due to the difference in charge amount are prevented from occurring.

In addition, by reducing the pre-charging delay through waveform modulation of the initial section of the data voltage, the pre-charging delay can be easily reduced according to the characteristics of the display panel 110, and the data voltage while reducing the pre-charging delay. It allows the gradation according to the color to be expressed as is.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. In addition, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but rather to explain it, and therefore the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

100: display device 110: display panel
120: gate driver 130: data driver
131: data voltage generator 132: data modulation waveform generator
132a: voltage amplifier 132b: delay circuit
133: data voltage output unit 140: controller

Claims (16)

A display panel with multiple subpixels arranged along rows and columns;
a plurality of data lines, one for each column of the two subpixels disposed on the display panel, and transmitting data voltages to the two subpixels disposed on both sides; and
The data voltage whose polarity is inverted is supplied to each row of the subpixels through the plurality of data lines, and among the plurality of subpixels, a subpixel that displays the same color and is repeatedly strongly charged and weakly charged according to the data lines. A data driver that modulates and outputs the waveform of the initial section of the data voltage applied during weak charging.
Including,
The data driver is,
A display device that overshoots a waveform of an initial section of the data voltage applied during weak charging of the subpixel in which the strong charging and weak charging are repeated, amplifies the waveform to a level higher than the level of the data voltage, and outputs the result.
According to paragraph 1,
The data driver is,
Modulating the waveform of the initial section of the data voltage applied to the subpixel to which the data voltage of the inverted polarity is applied to the data voltage applied to the previous subpixel in the subpixel where the strong charging and the weak charging are repeated. Display device.
According to paragraph 1,
The data driver is,
A display device that modulates and outputs a waveform of an initial section of the data voltage applied when the subpixel is lightly charged in accordance with the timing of a source output enable signal received from a controller.
delete According to paragraph 1,
The data driver is,
If the data voltage applied during weak charging of the subpixel is (+) polarity, the waveform of the initial section of the data voltage is amplified in the (+) direction, and if the data voltage is (-) polarity, the waveform of the initial section of the data voltage is amplified in the (-) direction. A display device that amplifies the waveform of the initial section of .
According to paragraph 1,
The data driver is,
The initial section of the data voltage applied during weak charging of the subpixel in which the strong charging and the weak charging are repeated is set as part of the section to which the data voltage is applied, and the initial section of the data voltage is set according to the length of the set initial section. A display device that determines the voltage level to be amplified.
According to paragraph 1,
The data driver is,
A display device that alternately applies the data voltage to subpixels disposed on one side of the data line and subpixels disposed on the other side.
According to paragraph 1,
The data driver is,
A display device that outputs two data voltages supplied to two subpixels placed on either side of one data line during one horizontal cycle.
According to paragraph 1,
Among the subpixels displaying the same color in the plurality of subpixels, all subpixels displaying a first color are strongly charged when driven, and all subpixels displaying a second color are weakly charged when driven.
a data voltage generator that converts the image data signal received from the controller to generate a data voltage;
a data modulation waveform generator that modulates the waveform of the initial section of the data voltage supplied to a specific data line at a timing when the polarity is inverted; and
A data voltage output unit that outputs the modulated data voltage through the specific data line.
Including,
The data modulation waveform generator,
a delay circuit that adjusts the initial section of the data voltage; and
A data driver including a voltage amplifier that amplifies the voltage level of the initial section of the data voltage.
delete According to clause 10,
The data modulation waveform generator,
A data driver that modulates the waveform of the initial section of the data voltage according to the timing of the source output enable signal received from the controller.
According to clause 10,
The specific data line displays the same color and is a data line to which a data voltage is applied when a subpixel is repeatedly strongly and weakly charged by a data voltage applied through the data line.
converting an image data signal received from a controller to generate a data voltage;
Modulating the waveform of the initial section of the data voltage supplied to a specific data line in accordance with the timing of the source output enable signal received from the controller; and
Outputting a data voltage having the modulated waveform
Including,
The step of modulating the waveform of the initial section of the data voltage is amplified to a level higher than the level of the data voltage by overshooting the waveform of the initial section of the data voltage applied during weak charging of the subpixel where strong charging and weak charging are repeated. How to drive a data driver.
According to clause 14,
The step of modulating the waveform of the initial section of the data voltage is,
A method of driving a data driver that amplifies the voltage level of the initial section of the data voltage applied to the specific data line at a timing when the polarity of the data voltage is reversed.
According to clause 14,
The specific data line displays the same color and is a data line to which a data voltage is applied when a subpixel is repeatedly strongly and weakly charged by a data voltage applied through the data line.

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