KR20150078354A - Liquid Display Device And Driving Method Of The Same - Google Patents

Abstract

Provided is a liquid crystal display device which comprises: a liquid crystal display panel; a timing controller for supplying image data to the liquid crystal display panel; a backlight control unit for receiving duty-on information, a frame synchronization signal, a backlight dimming signal from the timing controller and generating a backlight synchronization signal calculated as a gain value; and a backlight driving unit for turning a backlight unit on and off by receiving the backlight synchronization signal.

Description

[0001] The present invention relates to a liquid crystal display device and a method of driving the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device and a driving method thereof for reducing a flicker phenomenon and a motion blur phenomenon which are generated according to a PWM frequency variation during driving of a backlight module.

In a liquid crystal display device, an incident light passes through a liquid crystal layer and a color filter layer to express an image. In general, a backlight module is provided because self-emission is impossible.

A liquid crystal display panel for directly implementing a screen in a liquid crystal display device generally carries out 60 Hz / s driving. In the case of a backlight module, it is recognized as a flicker when driving at a frequency of about 75 Hz / s or less, Drive.

However, when a liquid crystal display device is driven at a frequency of 60 Hz / s and a backlight module is driven at a rate of 120 Hz / s, the liquid crystal display device exhibits high quality images when the backlight module and the liquid crystal display panel are driven at the same frequency. Distortion and image quality degradation.

Due to such a problem, the conventional liquid crystal display device keeps the frequency of the backlight module equal to the frequency of the liquid crystal display panel when the flicker is recognized in the lower gray level in the liquid crystal display panel, and drives the backlight module at 120 Hz / s in other areas Flicker awareness was minimized.

At this time, in the conventional liquid crystal display device, frequency driving is set through experiments. This will be described with reference to FIG. 1 below.

FIG. 1 is a timing chart showing driving of each frame of a conventional backlight module which changes its driving from 60 Hz / s to 120 Hz / s.

As shown in FIG. 1, when the conventional backlight module changes driving from 60 Hz / s to 120 Hz / s due to the backlight synchronization signal, the backlight dimming signal BDS is not immediately changed to 120 Hz / , 100 Hz / s drive, etc., and the output is changed to 120 Hz / s.

At this time, the backlight dimming signal BDS is output by PWM driving, and the frequency is changed by the PWM driving and the start and end of the output backlight dimming signal BDS are set so as to match the data Vsync.

Since the backlight dimming signal BDS thus outputted represents the optimum value according to the experimental result, the frequency to be constantly changed is constantly measured.

Such a structure has two problems. First, there are many limitations in proposing a new technology, including improvement of a dynamic picture response time (Motion Picture Response Time).

For example, in order to reduce the motion blur of an image, a driving method has been proposed in which the backlight module is extinguished during the time period during which the liquid crystal is rearranged according to the change of the gray level of the image data. The output of the backlight dimming signal (BDS) Is outputted as a fixed value according to the optimum value of the experimental result, it is difficult to turn off the backlight module corresponding to the change of the gray level.

Secondly, since the backlight dimming signal (BDS) is set to be driven to the optimum value according to the experimental result, it is necessary to calculate all the optimum values according to resolution and size of the liquid crystal display device, So that a driving speed and an additional storage space are required, which increases the manufacturing cost.

That is, according to the above-described problems, it is required to apply a new technology, and a liquid crystal display device and a driving method thereof which are driven by a simple algorithm and do not cause problems such as speed reduction and additional storage space.

It is difficult for a liquid crystal display device to be mixed with other driving methods according to a driving method of outputting a fixed frequency value when a frequency of a backlight dimming signal is changed and a complex algorithm And the manufacturing cost is increased.

In order to solve the above problems, the present invention provides a liquid crystal display comprising: a liquid crystal display panel; A timing controller for supplying image data to the liquid crystal display panel; A backlight control unit receiving the duty-on information, the frame synchronization signal, and the backlight dimming signal from the timing controller and generating a backlight synchronization signal calculated as one gain value; And a backlight driver for receiving the backlight synchronization signal to turn off and light the backlight unit.

The backlight control unit includes a comparator for outputting the first and second logic signals; A frequency conversion selector for receiving the first and second logic signals output according to a comparison result of the comparison unit and outputting first to fourth selection signals; A backlight synchronization signal generating unit receiving the first to fourth selection signals from the frequency conversion selecting unit to generate first to fourth backlight synchronization signals; And a dimming signal generator receiving the first to fourth backlight synchronization signals, the duty-on information, and the gate control signal.

Also, the first logic signal is characterized in that the reference duty-on information is smaller than the duty-on information, and the reference duty-on information of the second logic signal is larger than the duty-on information.

In response to the first logic signal, the frequency of the previous frame is the same as the frequency of the frame synchronizing signal. In response to the first logic signal, Wherein the frequency of the previous frame is the same as the frequency of the frame synchronizing signal in response to the second logic signal and the frequency of the previous frame in response to the second logic signal is higher than the frequency of the previous frame, Which is higher than the frame synchronizing signal.

The dimming signal generator includes: a determiner for receiving the first to fourth selection signals; A gain calculation unit for calculating a gain value according to the determination of the determination unit; A frequency calculator for receiving a gain value from the gain calculator and calculating a frequency; A duty calculator for calculating a duty on and off timing by receiving a gain value from the gain calculator; And a dimming signal generator for receiving a result value from the frequency calculator and the duty calculator and outputting a dimming signal.

The determination unit receives the first and fourth selection signals and outputs the same to the dimming signal generator.

The determination unit receives the second and third selection signals and determines whether the frequency is increased or the frequency is decreased.

The gain calculator calculates a gain value according to Equation (1) or Equation (2) according to the frequency variable length and the determination of the determination unit,

이고, Equation (1)

ego,

Equation (2)

to be.

The frequency calculator receives the gain value from the gain calculator and calculates a driving frequency according to equation (3)

Equation (3)

to be.

The duty calculator receives the gain value from the gain calculator and generates a duty-on off signal according to equation (4)

Equation (4)

to be.

Also, the backlight module includes driving with one selected from 120 Hz / s or 60 Hz / s.

According to another aspect of the present invention, Sensing a frequency variation in the received backlight driving signal; Selecting a frequency before the sensing step and calculating a gain value; Performing frequency variable driving with the gain value; Generating a dimming signal with a current frequency and a duty-off signal calculated according to the frequency variable driving; Comparing the dimming signal with a frequency of a dimming signal to be varied and the duty-on off signal; Comparing the frame synchronizing signal of the dimming signal with the frame synchronizing signal of the dimming signal to be varied; And outputting the dimming signal. The present invention also provides a method of driving a liquid crystal display device.

The receiving of the backlight driving signal may include receiving the frame synchronizing signal, the duty-on information, and the backlight dimming signal.

The step of detecting the variable frequency may include calculating the gain value when the duty-on information received from the previous frame differs from the duty-on information received from the current frame, And outputting the dimming signal when the duty-on information received in the current frame is the same.

The calculating of the gain value may include calculating a gain value by substituting the number of frames corresponding to the variable frequency applied length into Equation 1 or Equation 2,

Equation (1)

이고,

ego,

Equation (2)

to be.

The performing the frequency variable driving operation may include substituting the gain value into Equation (3) and Equation (4) to obtain a driving frequency and a lighting frequency,

Equation (3)

이고,

ego,

Equation (4)

이다.

to be.

The step of comparing the frame synchronizing signal may further include comparing the frame synchronizing signal of the current frequency with the frame synchronizing signal of the dimming signal to be varied and checking whether the frame synchronizing signal coincides with the starting point of the frame for one period .

The frame synchronization signal of the current frequency is delayed at the frame start or frame end of the current frequency in order to synchronize with the frame synchronization signal of the dimming signal to be varied.

The liquid crystal display device according to the embodiment of the present invention is an algorithm for performing frequency variable driving with a single gain value and can be applied without limitation to the resolution and size of the display panel to simplify the algorithm, It is effective.

In addition, since the frequency variable driving according to the isobaric watering theory is performed without changing the frequency to a fixed value, it is possible to show high compatibility with the image enhancement technology including the backlight point and the extinction technique for reducing motion blur.

FIG. 1 is a timing chart showing driving of each frame of a conventional backlight module which changes its driving from 60 Hz / s to 120 Hz / s.
2 is a block diagram schematically showing a configuration of a liquid crystal display device according to an embodiment of the present invention.
FIG. 3 is a block diagram schematically illustrating a backlight module of a liquid crystal display device according to an embodiment of the present invention. FIGS. 4A to 4D are diagrams illustrating a method of driving a backlight module according to an embodiment of the present invention, Fig.
5 is a block diagram illustrating a dimming signal generator according to an embodiment of the present invention.
FIG. 6A is a timing chart for a driving frequency of the backlight dimming signal generated by the dimming signal generator according to an exemplary embodiment of the present invention, and FIG. 6B is a timing diagram illustrating a backlight duty- Respectively.
7 is an algorithm illustrating a method of driving a backlight module of a liquid crystal display device according to an embodiment of the present invention.

Hereinafter, a liquid crystal display device and a driving method thereof according to an embodiment of the present invention will be described with reference to the drawings.

2 is a block diagram schematically showing a configuration of a liquid crystal display device according to an embodiment of the present invention.

2, the liquid crystal display device according to the embodiment of the present invention may include a display panel 100, a timing controller 110, and a backlight module 120. [

The display panel 100 displays an image by rearranging the liquid crystal by applying an electric voltage to generate an electric field, thereby passing or blocking light.

The timing controller 110 transmits image data to the display panel 100 and is connected to the backlight module 120 to generate Duty On Information (DOI), frame synchronization signal (Vsync), and backlight dimming signal (BDS).

The backlight module 120 receives the duty-on information (DOI), the frame synchronizing signal (Vsync) and the backlight dimming signal (BDS) of the timing controller 110. The backlight module 120 includes a backlight controller 121, And a backlight driving unit 122 for driving the backlight unit 125 by the backlight control unit 121.

The backlight module 120 of the liquid crystal display device having the above structure drives the backlight unit 125 by maintaining or increasing or decreasing the output frequency based on the signal output from the timing controller 110, The structure will be described in detail with reference to FIGS. 3 and 4 below.

FIG. 3 is a block diagram schematically illustrating a backlight module of a liquid crystal display device according to an embodiment of the present invention. FIGS. 4A to 4D are diagrams illustrating a method of driving a backlight module according to an embodiment of the present invention, Fig.

3, the backlight module of the liquid crystal display device includes a backlight control unit 121, a backlight driving unit 122, and a backlight unit 125.

The backlight control unit 121 includes a comparator 131 for comparing the reference duty-on information (RDOI) with the duty-on information DOI of the current frame, and a comparator 131 for comparing the duty- A backlight synchronization signal generation unit 135 receiving a selection signal CS from the frequency conversion selection unit 133 and a backlight synchronization signal generation unit 135 And a dimming signal generator 138 receiving the backlight synchronization signal Bsync and the duty-on information DOI.

The comparison unit 131 compares the reference duty-on information RDOI with the duty-on information DOI of the current frame and outputs a logic signal LS. When the reference duty-on information RDOI corresponds to the duty- And outputs the second logic signal when the reference duty-on information RDOI is larger than the duty-on information DOI.

The frequency conversion selection unit 133 receives the logic signal LS and the frame synchronization signal Vsync. When the first logic signal is input and the frequency of the previous frame is the same as the frame synchronization signal Vsync And outputs a first selection signal CS1 and outputs a second selection signal CS2 when the first logic signal is input and the frequency of the previous frame is a second frequency higher than the frame synchronization signal Vsync.

On the other hand, when the second logic signal is input and the frequency of the previous frame is the first frequency, which is the same as the frame synchronizing signal Vsync, the third selecting signal CS3 is output. When the second logic signal is inputted and the frequency of the previous frame is And outputs the fourth selection signal CS4 when the second frequency is higher than the frame synchronization signal Vsync.

The backlight synchronization signal generator 135 receives the first to fourth selection signals CS1 to CS4 to generate a backlight synchronization signal Bsync. The backlight synchronization signal generator 135 generates a backlight synchronization signal Bsync, The synchronizing signal Bsync represents the first backlight synchronizing signal Bsync1 which is the same as the frame synchronizing signal Vsync and the backlight synchronizing signal Bsync which is outputted when the second selecting signal CS2 is applied is the first PWM frequency The backlight synchronization signal Bsync output when the third selection signal CS3 is applied is input to the second PWM frequency filter 140 The backlight synchronization signal Bsync output when the fourth selection signal CS4 is applied represents the third backlight synchronization signal Bsync3 and the fourth backlight synchronization signal Bsync4 which is the same as the second frequency.

At this time, the first PWM frequency filter 139 gradually decreases the frequency to drive the first frequency, and the second PWM frequency filter 140 gradually increases the frequency to drive the second frequency will be.

Any one of the first to fourth backlight synchronization signals Bsync1 to Bsync4 is applied to the dimming signal generator 138 as shown in Figs. 4a to 4d to generate a duty-on signal On, And is converted into a backlight dimming signal BDS having an off signal Off.

In the case of the first backlight synchronization signal Bsync1 representing the first frequency F1 that is the same as the frame synchronization signal Vsync, the dimming signal generator 138 generates the first backlight synchronization signal Bsync1 at the first frequency F1 And the backlight dimming signal BDS which alternately represents the duty-on signal (On) and the duty-off signal (Off), and is applied to the backlight driver 122. [

In the case of the second backlight synchronization signal Bsync2 indicating the second frequency F2 higher than the frame synchronization signal Vsync, the dimming signal generator 138 generates the second frequency F2 to gradually decrease to the first frequency F1 and is converted into a backlight dimming signal BDS which alternately represents the duty-on signal On and the duty-off signal Off and is applied to the backlight driver 122. [

In the case of the third backlight synchronization signal Bsync3 representing the first frequency F1 that is the same as the frame synchronization signal Vsync, the dimming signal generator 138 generates the first frequency F1 ) Gradually increases to the second frequency F2 and is converted into a backlight dimming signal BDS which alternately represents the duty-on signal On and the duty-off signal Off and is applied to the backlight driver 122. [

In the case of the fourth backlight synchronization signal Bsync4 indicating the second frequency F2 higher than the frame synchronization signal Vsync, the dimming signal generator 138 generates the second frequency F2 to the backlight dimming signal BDS which alternately represents the duty-on signal On and the duty-off signal Off and is applied to the backlight driver 122. [

The backlight driver 122 drives the backlight unit 125 with the backlight dimming signal BDS applied from the dimming signal generator 138.

The liquid crystal display device according to the embodiment of the present invention configured to display the measured values by the experiment in the process of converting the second and third backlight synchronization signals (Bsync2) to the backlight dimming signal (BDS) The gain value is obtained by a single calculation and then the variable frequency located between the frequency before the conversion and the frequency after the conversion is calculated. This makes it possible to simplify the algorithm.

This advantage is revealed by the dimming signal generator 138, which will be described in detail with reference to FIG. 5 below.

5 is a block diagram illustrating a dimming signal generator according to an embodiment of the present invention.

5, the dimming signal generating unit 138 formed in the liquid crystal display device according to the embodiment of the present invention includes a determining unit 141, a gain calculating unit 143, and a frequency calculating unit 145 And a driving signal generation unit 149. The backlight synchronization signal Bsync is input to the determination unit 141 to generate a driving signal.

The determination unit 141 receives the backlight synchronization signal Bsync and determines a frequency size before and after the variable frequency and a variable frequency application length.

In this case, the frequency magnitude before and after the variable represents the first frequency and the second frequency, and the backlight synchronization signal Bsync is the same as the first and fourth backlight synchronization signals (Bsync1 in Fig. 3, Bsync4 in Fig. 3) 1 frequency, or the second frequency is unchanged, it is moved to the drive signal generation unit 149 and output to the backlight dimming signal (BDS in FIG. 4A, BDS in FIG. 4B) for each of them, thereby simplifying the algorithm.

On the other hand, when the backlight synchronization signal Bsync maintains the second frequency or the third frequency as in the second and third backlight synchronization signals (Bsync2 in FIG. 3, Bsync3 in FIG. 3) And determines the frequency size and the variable frequency applied length after the variable.

Here, the first frequency is 60 Hz / s and the second frequency is 120 Hz / s.

At this time, the frequency of the second backlight synchronization signal (Bsync2 in FIG. 3) decreases. The determination unit 141 sets the frequency before the variable backlight synchronization signal (Bsync2 in FIG. 3) 3, the determination unit 141 determines that the frequency of the third backlight synchronization signal (Bsync3 in FIG. 3) is higher than the frequency of the third backlight synchronization signal (Bsync3) is determined to be 60Hz / s, which is the first frequency, and 120Hz / s, which is the second frequency, after the variable.

The variable frequency applied length for each of the second and third backlight synchronization signals (Bsync2 in Fig. 3 and Bsync3 in Fig. 3) is based on the frame synchronization signal Vsync, and the number of frames to which the variable frequency is applied is set to a value And in the embodiment of the present invention, the change is performed for 5 frames.

In the case where the frequency before and after the variable and the variable frequency applied length are determined as described above, the gain calculation unit 143 obtains the gain value based on these values.

In this case, the gain calculator 143 calculates the gain value once for one change, and can represent a simple logic as compared with calculating the gain value several times in order to represent the frequency measured through the experiment in the past .

In particular, the gain calculator 143 computes using the infinite isoquant series theory that obtains the solution of the isoquant series, thereby achieving the highest efficiency in digital data processing and simplifying the algorithm.

The gain calculator 143 can obtain the gain value based on the number of frames set in the variable frequency applied length, which can be obtained by the following Equations (1) and (2).

[Equation 1]

&Quot; (2) "

3, the gain value for the second backlight synchronization signal (Bsync2 in FIG. 3) is 1.25, and the third backlight synchronization signal (shown in FIG. 3 The gain value for Bsync3 is -0.75.

At this time, since the frequency can not represent a negative value, the gain value is represented by an absolute value, and accordingly, the gain value is 0.75.

The calculated gain value and the second and third backlight synchronization signals (Bsync2 in FIG. 3 and Bsync3 in FIG. 3) are supplied to the frequency calculator 145 and the duty calculator 147 by the driving frequency and the backlight dimming signal 3), and off-time.

The frequency calculator 145 and the duty calculator 147 can calculate the frequency to be driven for each frame and the duty-off time within the calculated frequency after the variable is started based on the gain value calculated above, This will be described in detail below with reference to the drawings.

The frequency and the lighting frequency calculated by the frequency calculator 145 and the duty calculator 147 are transmitted to the backlight driver (122 in FIG. 3) through the driving signal generator 149.

The frequency of the signal output from the dimming signal generator 138 is increased or decreased in accordance with the frequency drive to be changed. 6a and 6b will now be described.

FIG. 6A is a timing chart for a driving frequency of the backlight dimming signal generated by the dimming signal generator according to an exemplary embodiment of the present invention, and FIG. 6B is a timing diagram illustrating a backlight duty- Respectively.

The dimming signal generator according to the embodiment of the present invention can obtain the driving frequency and duty-off signal to be driven in the next frame through the frequency calculator through the following Equations (3) and (4).

&Quot; (3) "

&Quot; (4) "

In this case, β _n and γ _n are the first frequency and the duty-off time, respectively, and β _n-1 and γ _n-1 are the output frequency and the duty-off time, respectively.

As shown in FIG. 6A, the frequency calculator calculates the second to fifth frequencies F5 (F5) through F5 until the sixth frequency F6 is represented by the first frequency F1, The frequency to be driven is calculated.

In the case of the second backlight synchronization signal (Bsync2 in FIG. 3), the frequency initially output is 120 Hz / s and the gain value is 1.25.

In this case, according to Equation (3), the first frequency F1 has the same value as the previously output frequency, and the first frequency F1 is 120 Hz / s.

The second frequency F2 has a frequency lower than that of the second backlight synchronization signal Bsync2 driven in the first frame F1 in the first frame and the first frequency F1 is repeatedly driven 150 times The second frequency F2 is set so as to perform the 120 times repetitive driving for the time.

That is, the second frequency F2 is determined to be 96 Hz / s which is lower than the first frequency F1 by 24 Hz / s.

Thereafter, the third frequency F3 has a lower frequency than the second backlight synchronization signal (Bsync2 in Fig. 3) driven in the previous frame at the second frequency F2, and the first frequency F1 repeats 187.5 times The third frequency F3 is set so as to perform 120 times repetitive driving during the driving time.

That is, the third frequency F3 is determined to be 76.8 Hz / s, which is lower than the second frequency F2 by 19.2 Hz / s.

Thereafter, the fourth frequency F4 has a lower frequency than the second backlight synchronization signal (Bsync2 in FIG. 3) driven in the previous frame at the third frequency F3, and the first frequency F1 repeats 234.375 times The fourth frequency F4 is set so as to perform 120 times repetitive driving during the driving time.

That is, the fourth frequency F4 is determined to be 61.44 Hz / s, which is lower than the third frequency F3 by 15.36 Hz / s.

Then, the fifth frequency F5 has a frequency lower than that of the second backlight synchronization signal (Bsync2 in FIG. 3) driven by the fourth frequency F4 in the previous frame. However, when the driving according to the expression When the fifth frequency F5 is set so as to perform the 120 times repetitive driving for the time period in which the first frequency F1 is repeatedly driven 292.9685 times, 49.152Hz / s, which is lower than the target 60Hz / s, is displayed.

In this case, the fifth frequency F5 can be directly changed to 60 Hz / s without performing the driving according to Equation (3) by treating the fifth frequency F5 as a synchronization period, and from the sixth frame to 60 Hz / s In the case of driving, the remaining frequency of the target frequency at the fourth frequency F4 may be divided and driven at a certain rate.

That is, in the embodiment of the present invention, the fifth frequency F5 is obtained by subtracting the target frequency 60 Hz / s from 61.44 Hz / s, which is the fourth frequency F4, (60.72 Hz / s) subtracted from the output signal (F4).

Meanwhile, as shown in FIG. 6B, the duty calculator 147 may calculate the duty-on and off-time driving frequencies according to the first to fifth frequencies F5 through Equation (4).

According to Equation (4), when the duty ON and the OFF time at the first first frequency F1 are alternately switched on and off, the duty on and off time are respectively set to a first ON state at the first frequency F1 It is determined that the frequency DF1 drive is performed.

At this time, the first lighting frequency DF1 is 60 Hz.

Thereafter, when the duty on and off time at the second frequency DF2 are alternately switched on and off, the duty on and off time respectively drive the second lighting frequency DF2 at the second frequency F2 .

At this time, the second lighting frequency DF2 is calculated as 48Hz which is 12Hz / s lower than the first lighting frequency DF1.

Thereafter, when the duty on and off time at the third lighting frequency DF3 are alternately switched on and off, the duty on and off time respectively drive the third lighting frequency DF3 at the third frequency .

At this time, the third lighting frequency DF3 is calculated as 38.4Hz which is 9.6Hz lower than the second lighting frequency DF2.

Thereafter, when the duty-on and off-time at the fourth lighting frequency DF4 are alternately switched on and off, the duty on and off time are respectively set to drive the fourth lighting frequency DF4 at the fourth frequency F4 .

At this time, the fourth lighting frequency DF4 is calculated to be 30.72Hz which is 7.68Hz lower than the third lighting frequency DF.

Thereafter, the duty on and off time at the fifth lighting frequency DF5 are alternately switched on and off, the duty on and off time are set to 24.576 (fifth lighting frequency DF5) at the fifth frequency F5, Hz, it is possible to maintain the normal ratio and to be unable to repeatedly turn on and off.

In this case, since the fifth lighting frequency DF5 is regarded as a synchronization period and represents a delay time D2 representing a frequency of 0.72 Hz, it is possible to change it to 30 Hz without performing driving according to Equation (4) When it is desired to adjust the length, the remainder of the target frequency at the fourth frequency (F4) can be divided and driven at a certain rate.

That is, in the embodiment of the present invention, the fifth lighting frequency DF5 is changed to 30 Hz, and then the delay time D1 representing the 0.36 Hz frequency is represented twice, , And off-time.

In the above case, the variation width is increased by setting the variable frequency application length to 5 frames. However, when the number of frames corresponding to the variable frequency application length is increased, the variation width is narrowed and the flicker phenomenon is greatly reduced.

According to the above procedure, the frequency of the liquid crystal display device can be changed without changing the resolution and the size of the panel, and the frequency, duty-on, and off-driving can be changed to a single gain value, thereby simplifying the algorithm.

The backlight module driving algorithm of the liquid crystal display device performing the above driving will be described with reference to FIG.

7 is an algorithm illustrating a method of driving a backlight module of a liquid crystal display device according to an embodiment of the present invention.

As shown in FIG. 7, the backlight driving algorithm of the liquid crystal display device according to the embodiment of the present invention can perform dimming signal changing driving through eight steps.

In a first step S1, a backlight control signal is input.

At this time, the backlight control signal is transmitted from the timing controller, and may include a frame synchronization signal, duty-on information, and a backlight dimming signal.

In addition, the timing controller can transmit a variable frequency applied length, which will be described in the third step S3 below.

In a second step (S2), it is checked whether a frequency variation has occurred.

At this time, it can be confirmed that the frequency variable occurs when the duty-on information received from the previous frame is different from the duty-on information received from the current frame, as described above.

On the other hand, if the duty-on information received in the previous frame is the same as the duty-on information received in the current frame, it is determined that the frequency variable does not occur, and the eighth step S8 is performed.

In the third step S3, the previous frequency is selected.

Since the liquid crystal display device according to the embodiment of the present invention is characterized by the driving method of obtaining the current frequency at the previous frequency, a variable frequency applied length can be received from the timing controller to change the driving frequency.

At this time, the variable frequency applied length is divided into frames, and the gain value is obtained by substituting the number of frames corresponding to the variable frequency applied length into Equation 1 or Equation 2 as described above.

In particular, the calculated gain value is held until after the output corresponding to the eighth step S8 and before being driven again through the second step S2.

Since the backlight module is driven at 60 to 120 Hz / s in the liquid crystal display device according to the embodiment of the present invention, the frequency reduction driving is performed when the previous frequency is 120 Hz / s at the initial driving, The frequency increase drive is performed.

In a fourth step S4, frequency variable driving according to the previous frequency is performed.

The previous frequency is equal to the frequency before the variable frequency, and the initial frequency can be calculated as 120 Hz / s when the frequency variable driving is performed from 120 Hz / s to 60 Hz / s. The previous frequency can be calculated as 60 Hz / s.

At this time, the duty on and off signals according to the current frequency and frequency can be calculated by substituting the gain value and the previous frequency calculated in the third step into Equation (3) and Equation (4).

In a fifth step S5, a dimming signal is generated based on the calculated current frequency, the duty ON signal, and the OFF signal.

The calculated current frequency, duty-on, and off signals are changed to a backlight driving signal, and the changed backlight driving signal is transmitted to the backlight driving unit to determine the periods of turning on and off the backlight unit.

In a sixth step S6, the generated dimming signal is compared with a dimming signal to be varied.

The generated dimming signal is used to indicate a dimming signal to be varied. When the driving frequency of the generated dimming signal is equal to or lower than the driving frequency of the dimming signal to be varied, the third step is performed again.

On the other hand, if the driving frequency of the generated dimming signal exceeds the driving frequency of the dimming signal to be varied, the subsequent driving is performed using the dimming signal generated before the most recently generated dimming signal.

The reason for driving as described above is that it is extremely rare that the generated dimming signal exactly coincides with the driving frequency of the dimming signal to be varied because the generated dimming signal indicates the property of the isobaric water supply. It is extremely rare that the frame synchronization signal of the generated dimming signal coincides with the frame synchronization signal of the dimming signal to be changed.

That is, when the frame synchronization signal of the generated dimming signal matches the frame synchronization signal and the driving frequency of the dimming signal to be changed, the frame synchronization signal can be output without proceeding to synchronize the frame synchronization signal.

In the seventh step S7, the frame synchronization signal of the generated dimming signal is compared with the frame synchronization signal of the dimming signal to be varied.

If the frame synchronizing signal of the generated dimming signal matches the frame synchronizing signal of the dimming signal to be varied, the residual frame according to the variable frequency applied length can be ignored and output. However, if the generated frame synchronizing signal of the dimming signal is variable It is possible to perform the first drive S7a if it is different from the frame synchronization signal of the dimming signal.

The first drive S7a delays a signal output for a predetermined period of time after outputting the generated dimming signal for a predetermined period of time. In order to prevent a flicker due to a delay, a frame sync of a dimming signal generated as a residual frame according to a variable- The difference between the signal and the frame synchronization signal of the dimming signal to be varied can be delayed and the generated dimming signal can be delayed by the calculated value.

The above driving is one example, and the generated dimming signal may be delayed by a fixed number of times.

In the eighth step S8, a dimming signal synchronized with the frame synchronizing signal is output to the backlight driving unit according to the seventh step S7.

The liquid crystal display device driven according to the algorithm described above does not need a storage unit for storing a fixed value because it outputs a driving frequency value according to the necessity based on inputted image data, It is possible to apply various variable frequency lengths compared to the technique of FIG. 1, so that it is possible to output an optimized value for each frame, thereby reducing the motion blur.

The liquid crystal display device according to the embodiment of the present invention is an algorithm for performing frequency variable driving with a single gain value and can be applied without limitation to the resolution and size of the display panel to simplify the algorithm, It is effective.

In addition, since the frequency variable driving according to the isobaric watering theory is performed without changing the frequency to a fixed value, it is possible to show high compatibility with the image enhancement technology including the backlight point and the extinction technique for reducing motion blur.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It can be understood that

100: display panel 110: timing controller
120: backlight module 121: backlight control unit
122: backlight driver 125: backlight unit
131: comparison unit 133: frequency conversion selection unit
135: backlight synchronization signal generation unit 138: dimming signal generation unit
139: first PWM frequency filter 140: second PWM frequency filter
141: Judgment section 143: gain calculation section
145: frequency calculator 147: duty calculator
148: Calculator 149: Drive signal generator

Claims (18)

A liquid crystal display panel;
A timing controller for supplying image data to the liquid crystal display panel;
A backlight control unit receiving the duty-on information, the frame synchronization signal, and the backlight dimming signal from the timing controller and generating a backlight synchronization signal calculated as one gain value;
A backlight driving unit for receiving the backlight synchronization signal and performing lighting and lighting of the backlight unit,
And the liquid crystal display device.
The method according to claim 1,
The backlight control unit includes:
A comparator for outputting first and second logic signals;
A frequency conversion selector for receiving the first and second logic signals output according to a comparison result of the comparison unit and outputting first to fourth selection signals;
A backlight synchronization signal generating unit receiving the first to fourth selection signals from the frequency conversion selecting unit to generate first to fourth backlight synchronization signals;
The first to fourth backlight synchronization signals, the duty-on information, and the gate control signal are applied to the dimming signal generator
And the liquid crystal display device further comprises:
3. The method of claim 2,
Wherein the first logic signal has a duty cycle that is less than the duty-
And the second logic signal is characterized in that the reference duty-on information is larger than the duty-on information.
3. The method of claim 2,
Wherein the first selection signal in response to the first logic signal is the same as the frame synchronization signal in the frequency of the previous frame,
The second selection signal in response to the first logic signal is higher in frequency of the previous frame than the frame synchronization signal,
Wherein the third selection signal in response to the second logic signal is the same as the frame synchronization signal in the frequency of the previous frame,
And the fourth selection signal in response to the second logic signal is higher in frequency of the previous frame than the frame synchronization signal.
3. The method of claim 2,
The dimming signal generator
A determination unit receiving the first to fourth selection signals;
A gain calculation unit for calculating a gain value according to the determination of the determination unit;
A frequency calculator for receiving a gain value from the gain calculator and calculating a frequency;
A duty calculator for calculating a duty on and off timing by receiving a gain value from the gain calculator;
And a dimming signal generator for receiving a result value from the frequency calculator and the duty calculator and outputting a dimming signal,
And the liquid crystal display device.
6. The method of claim 5,
Wherein the determination unit receives the first and fourth selection signals and outputs the received first and fourth selection signals to the dimming signal generation unit.
6. The method of claim 5,
Wherein the determination unit receives the second and third selection signals to determine a frequency rise or a frequency fall.
6. The method of claim 5,
The gain calculator calculates a gain value according to Equation (1) or Equation (2) according to the frequency variable length and the determination of the determination unit,
Equation (1)

ego,
Equation (2)

.
6. The method of claim 5,
The frequency calculator receives the gain value from the gain calculator and calculates a driving frequency according to equation (3)
Equation (3)

.
6. The method of claim 5,
The duty calculator receives a gain value from the gain calculator and generates a duty-on off signal according to equation (4)
Equation (4)

.
The method according to claim 1,
Wherein the backlight module is driven by either one selected from 120 Hz / s or 60 Hz / s.
Receiving a backlight driving signal;
Sensing a frequency variation in the received backlight driving signal;
Selecting a frequency before the sensing step and calculating a gain value;
Performing frequency variable driving with the gain value;
Generating a dimming signal with a current frequency and a duty-off signal calculated according to the frequency variable driving;
Comparing the dimming signal with a frequency of a dimming signal to be varied and the duty-on off signal;
Comparing the frame synchronizing signal of the dimming signal with the frame synchronizing signal of the dimming signal to be varied;
The step of outputting the dimming signal
And a driving method of the liquid crystal display device.
13. The method of claim 12,
The step of receiving the backlight driving signal includes:
Wherein the frame synchronizing signal, the duty-on information, and the backlight dimming signal are received.
13. The method of claim 12,
Wherein the step of detecting the frequency variable comprises:
When the duty-on information received in the previous frame differs from the duty-on information received in the current frame, calculating the gain value,
And outputting the dimming signal when the duty-on information received from the previous frame is identical to the duty-on information received from the current frame.
13. The method of claim 12,
Wherein the step of calculating the gain value comprises:
A gain value is calculated by substituting the number of frames corresponding to the variable frequency applied length into Equation 1 or Equation 2,
Equation (1)

ego,
Equation (2)

And a driving method of the liquid crystal display device.
13. The method of claim 12,
Wherein the performing the frequency variable driving comprises:
Substituting the gain values into Equation (3) and Equation (4), the driving frequency and the lighting frequency are obtained,
Equation (3)

ego,
Equation (4)

And a driving method of the liquid crystal display device.
13. The method of claim 12,
Wherein the step of comparing the frame synchronization signal comprises:
Comparing the frame synchronizing signal of the current frequency with the frame synchronizing signal of the dimming signal to be varied and checking whether the frame synchronizing signal coincides with the starting point of the frame for one period.
18. The method of claim 17,
Wherein the frame synchronization signal of the current frequency delays the frame start or frame end of the current frequency to synchronize with the frame synchronization signal of the dimming signal to be varied.

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