KR20090040681A - Liquid crystal display device and driving method thereof - Google Patents

Abstract

A liquid crystal display device and a driving method thereof are provided to increase the contrast ratio by controlling the current value of the back light differently. The video signal is received from the outside and is signal-processed(S10). The histogram of the input video signal is analyzed based on the brightness signal of the signal-processed video signal(S20). The video signal level according to the histogram analyzed exceeds the reference threshold, it is determined(S30). If the video signal level exceeds the reference threshold, the driving current value supplied to the backlight part is maintained(S40). If the video signal level is less than the reference threshold, the first driving current value is supplied to the backlight part for the first section(S50). The driving current value already stored in the memory unit is supplied to the backlight part(S60) for the second section(S60).

Description

Liquid Crystal Display Device and Driving Method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, wherein a liquid crystal display device and a driving thereof to increase contrast ratio by differentially controlling a current value of a backlight for each section when performing a DFC (Digital Fine Contrasr) function. It is about a method.

In general, an image display device includes a non-emission method of displaying an image by a light source such as a backlight lamp, which is typically a liquid crystal display (LCD), and the LCD is a backlight. And a dimming circuit for continuously changing the brightness of the backlight and the inverter for supplying AC power. Therefore, a driving voltage for driving the backlight is supplied through the inverter, and the backlight is operated based on the supplied driving current, thereby displaying an image having a desired brightness.

In addition, the liquid crystal display device has a large power consumption because the backlight for displaying an image on the LCD panel must be kept on while the power is turned on, and the backlight generates a certain amount of light on the LCD panel, thereby providing a constant brightness. In order to solve the problem that power consumption is increased by consuming a lot of light because the brightness of the liquid crystal display is dark, the brightness of the liquid crystal display device is constant, even though a relatively large amount of light is not required. By varying the brightness of the backlight using an average luminance level (APL) of the video signal, a method of reducing power consumption and improving image quality is provided.

That is, as shown in FIG. 1, when the DFC is applied, the histogram of the image signal is analyzed, and when the analyzed histogram is equal to or more than a preset standard level, a lamp current value preset by the user is applied (Conventional) and the analysis is performed. If the histogram is less than the preset standard level, a higher contrast ratio (CR) can be realized by lowering the brightness of the LCD panel by adjusting a current value for adjusting the brightness of the backlight unit.

However, such a lamp current changing method according to the related art requires a time for the backlight to be discharged even when entering the DFC mode and lowering the current value of the backlight. There is a problem that does not meet the specification.

In other words, when entering the DFC mode while supplying the current to the backlight based on the value set by the user as shown in FIG. 2, the current value provided to the backlight at the same time as the entry is set for each model. Changed to supply.

However, at this time, since a predetermined time (A) must elapse due to the discharge of the backlight until the image is displayed on the actual screen with the brightness according to the current value changed in the backlight, the screen between the tools of the predetermined time (A) The contrast ratio of the image displayed on the screen does not satisfy the standard specification, causing a problem of user dissatisfaction.

The present invention has been made to solve the above problems, and an object thereof is to enable a higher contrast ratio by differentially adjusting the current value of the backlight according to a section.

A liquid crystal display device according to the present invention for achieving the above object is a liquid crystal panel for displaying an image signal; A backlight unit for supplying light to the front surface of the liquid crystal panel; A backlight controller supplying a driving current for emitting the backlight; A histogram analyzer for analyzing a histogram of an image signal input from the outside; And a controller for outputting a control signal to the backlight controller so that a driving current for driving the backlight unit is differentially supplied according to a histogram of the input image signal analyzed by the histogram analyzer.

In addition, the driving method of the liquid crystal display device according to the present invention for achieving the above object comprises the steps of analyzing the histogram of the image signal input from the outside; Determining whether a current value for driving the backlight unit is changed based on the analyzed histogram; And differentially supplying a driving current value supplied to the backlight unit for each predetermined section according to the determination result.

The liquid crystal display and the driving method thereof according to the present invention provide a high contrast ratio at a faster time by reducing the time until the image is displayed at the desired contrast ratio (CR) by differentially supplying the current value of the backlight for each section when entering the DFC mode. There is an effect that can display the optimum picture quality.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily made by adding, changing, or deleting other elements. I can suggest.

As shown in FIG. 3, the liquid crystal display according to the present invention includes a video signal input unit 10 for receiving and processing a video signal input from the outside, and a video signal processed through the video signal input unit 10. A video signal processor 20 for signal processing of the display device, a display driver 30 for generating a corresponding drive signal according to the video signal inputted by the video signal processor 20, and a drive signal of the display driver 30 A liquid crystal panel 40 driven to display an image signal processed through the image signal processing unit 20, a backlight unit 50 supplying light to the front surface of the liquid crystal panel 40, and the backlight unit A backlight control unit 60 for supplying a driving current for the light emitting unit 50 to emit light, a histogram analyzing unit 70 for analyzing a histogram based on a luminance signal Y of an image signal input from the outside, and the hiss Outputs a control signal to the backlight controller 60 so that a driving current for driving the backlight unit 50 is differentially supplied for each preset section according to the histogram of the input image signal analyzed by the togram analyzer 70. And a memory unit 90 storing driving current values for controlling brightness of the backlight unit 50 according to the histogram of the input image signal.

The operation of the liquid crystal display device according to the present invention configured as described above is as follows.

First, the video signal input unit 10 receives a video signal input from the outside and performs signal processing. That is, the image signal input from the outside is separated into a luminance signal Y and a color difference signal UV.

Here, each of the luminance signal Y and the color difference signals U and V is obtained by the first to third equations.

Y = 0.229 * R + 0.587 * G + 0.114 * B

U = 0.493 * (B-Y)

V = 0.887 * (R-Y)

The video signal processor 20 performs signal processing to display a video signal processed through the video signal input unit 10. That is, the signal processed by the video signal input unit 10 is converted into a displayable signal format.

The image signal processed through the image signal processor 20 is input to the display driver 30, and the display driver 30 responds to the signal input through the image signal processor 20. A driving signal for driving the liquid crystal panel 40 is generated.

Accordingly, the liquid crystal panel 40 is driven in response to the driving signal generated by the display driver 30, and thus the liquid crystal panel 40 displays the transmitted image signal.

In this case, if the backlight unit 50 is not driven even while the image signal is being displayed through the liquid crystal panel 40, the user cannot view the image displayed through the liquid crystal panel 40.

That is, the user can watch the image displayed through the liquid crystal panel 40 as the backlight unit 50 applied with the driving current through the backlight controller 60 emits light.

In this case, the screen brightness of the displayed liquid crystal panel 40 is adjusted by changing a driving current value (for example, PWM) supplied to the backlight unit 50 through the backlight controller 60. As the driving current value supplied to the high and low is changed, the brightness of the displayed screen also changes.

In addition, the backlight unit 50 includes a plurality of backlights installed to overlap the liquid crystal panel 40. Therefore, the light is supplied to the front surface of the liquid crystal panel 40 while being controlled according to the driving current supplied through the backlight controller 60. Accordingly, the liquid crystal channel 40 has a high luminance and a wide light emitting surface.

The histogram analyzer 70 analyzes the histogram according to the brightness level based on the luminance signal Y of the input image signal processed through the image signal input unit 10. That is, the histogram analyzer 70 arranges the luminance components corresponding to the gray scales in units of frames to obtain a histogram of the input image signal.

The controller 80 determines whether the brightness of the currently displayed image is required based on the histogram of the input image signal obtained through the histogram analyzer 70.

In other words, when the brightness level according to the histogram of the currently input video signal is low, the DFC (Digital Fine Contrast) increases the contrast ratio (CR, contrast ratio) and reduces power consumption by darkening the output image accordingly. ) Function is provided.

Accordingly, the brightness level of the input video signal according to the analyzed histogram is compared with a preset reference threshold level, and it is determined whether the brightness of the video signal currently displayed through the liquid crystal panel is necessary according to the comparison result of the level. .

In general, the reference threshold is set to 20Level, but the present invention is not limited thereto, and it is preferable to allow the user to arbitrarily set or change the reference threshold level. However, the reference threshold level is provided to help understanding of the present invention. It is assumed that this is set to 20.

The controller 80 determines whether the level of the input image signal analyzed by the histogram analyzer 70 is higher than the preset 20Level, and accordingly changes the driving current supplied to the backlight unit 50 or Selective control over retention.

That is, when the level of the input video signal is higher than the reference threshold, the drive current currently supplied to the backlight unit 50, that is, the drive current value arbitrarily set by the user is maintained, and the level of the input video signal is the reference. If the threshold value is lower than the threshold value, the control signal is output such that the brightness of the backlight unit 50 is changed based on a driving current value according to a histogram previously stored in the memory unit 90.

At this time, as the driving current value input to the backlight unit 50 is varied, there is an overtool section (first section) and a stabilization section (second section), respectively.

For example, when the brightness level is 100 when the driving current value is 40 and the brightness level is 50 when the driving current value is 20, the backlight unit is reduced even if the driving current value is lowered from 40 to 20. Due to the discharge time of 50, it takes a certain time for the brightness level to actually fall to 50.

In this case, a section until the brightness level displayed on the screen becomes a level corresponding to the actual input driving current value due to the discharge time of the backlight unit 50 is referred to as a first section (between tools). A section other than the first section (after) is called a second section (stabilization section).

Therefore, the controller 80 outputs a control signal so that the driving current value of the backlight unit 50 is differentially supplied to each section.

In other words, the control signal is output such that the driving current values supplied to the backlight unit 50 are different according to the first section and the second section.

Herein, in the second section (stabilization section), a driving current value that is actually to be supplied to the backlight unit 50, that is, a driving current value (second driving current value) previously stored in the memory unit 90 is supplied. In the first section (transient section), a driving current value (first driving current value) lower than the second driving current value by a predetermined level is supplied to the backlight unit 50.

That is, a first driving current value is supplied to the backlight unit 50 during the first section (transient section), and a second driving current value (driving current value previously stored in the memory section) in the second section (stabilization section). To be supplied.

The first driving current value may be stored in the memory unit 90 to correspond to the second driving current value, or may be calculated by subtracting a predetermined level from the second driving current value through the controller 80. have.

In addition, since the division between the first section and the second section is not actually revealed, when the change of the driving current value is required, the first current value is displayed in the backlight unit 50 during a preset time (that is, the first section). After the preset time, the driving current value (second driving current value) to be actually supplied is supplied to the backlight unit 50.

The backlight controller 60 is more constant than a driving current value (second driving current value) that should be actually supplied to the backlight unit 50 during the first period (or a predetermined predetermined time) according to the control signal of the controller 80. The low driving current value (first driving current value) is supplied, and the actual driving current value pre-stored in the memory unit 90 is supplied to the second section (after the predetermined time).

That is, as shown in FIG. 4, if the driving current value needs to be changed while driving the backlight unit 50 based on the backlight driving current value set by the user (when entering the DFC mode), the first section A should be actually input. The first driving current value (temporary driving current value) lower than the driving current value (second driving current value) is supplied, and the driving current value to be actually input in the second section (stabilization section) other than the first section. Supply.

Accordingly, as shown in FIG. 5, it is conventionally required that B ′ time is required to display the screen at the luminance level according to the actual backlight driving current value when entering the DFC mode. However, in the present invention, the differential driving current value is supplied for each section when entering the DFC mode. Therefore, it takes A` time (A` <B`) until the screen is displayed at the actual luminance level.

As described above, the liquid crystal display according to the present invention supplies the current value of the backlight differentially in each section when entering the DFC mode, thereby reducing the time until the image is displayed at the actual desired contrast ratio (CR). The picture quality can be displayed.

In the driving method of the liquid crystal display according to the present invention configured as described above, as shown in FIG.

Subsequently, the histogram of the input image signal is analyzed based on the luminance signal of the signal processed image signal (S20).

In operation S30, it is determined whether an image signal level according to the analyzed histogram exceeds a reference threshold. That is, it is determined whether to enter the DFC mode.

Subsequently, when the image signal level exceeds the reference threshold, the determination result (S30) maintains the current value of the driving current currently supplied to the backlight unit 50 (S40).

In addition, when the image signal level is equal to or less than the reference threshold value, the determination result (S30), a first driving current value (temporary driving current value) is supplied to the backlight unit 50 during a first section (preset time) (S50). ).

In operation S60, a driving current value (second driving current value) previously stored in the memory unit 90 is supplied to the backlight unit 60 in a second section (after a preset time).

That is, based on the backlight driving current value set by the user, if the driving current value needs to be changed during the driving of the backlight unit 50 (when entering the DFC mode), the driving current value that should be actually input in the first section A (second driving). The first driving current value (temporary driving current value) lower than a predetermined level is supplied, and the driving current value to be actually input is supplied to a second section (stabilization section) other than the first section (S50 to S60). .

As described above, the liquid crystal display and the driving method thereof according to the present invention differentially supply the current value of the backlight for each section when entering the DFC mode, thereby reducing the time until the image is displayed at the actual desired contrast ratio (CR). Optimal image quality can be displayed with contrast ratio, improving user satisfaction.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram for explaining contrast ratio (CR) in a general DFC mode. FIG.

2 is a view for explaining a backlight driving current value and luminance level in the DFC mode according to the prior art.

3 is a view showing the configuration of a liquid crystal display device according to the present invention;

4 is a view for explaining a driving current value supplied to the backlight unit for each section in the DFC mode according to the present invention.

5 is a view for explaining a luminance level that is variable in the DFC mode according to the present invention.

6 is a flowchart illustrating a step-by-step method of driving a liquid crystal display according to the present invention.

Claims (12)

A liquid crystal panel for displaying an image signal; A backlight unit for supplying light to the front surface of the liquid crystal panel; A backlight controller supplying a driving current for emitting the backlight; A histogram analyzer for analyzing a histogram of an image signal input from the outside; And, And a controller which outputs a control signal to the backlight controller so that a driving current for driving the backlight unit is differentially supplied according to a histogram of the input image signal analyzed by the histogram analyzer. Display device. The method of claim 1, And a memory unit which stores a driving current value for controlling brightness of the backlight unit according to the histogram of the input image signal. The method of claim 2, The section is divided into a first section (between the tool) and a second section (stabilization section) for a predetermined time when the current value supplied to the backlight unit is changed according to the analyzed histogram. Display device. The method of claim 3, wherein The controller controls a first driving current value (temporary current value) to be supplied to the backlight unit in the first section, and a driving current value (second driving current) according to a histogram previously stored in the memory unit in the second section. Outputting a control signal such that a value) is sequentially supplied to the backlight unit. The method of claim 4, wherein And the first driving current value is less than a predetermined level than the second driving current value. In a driving method of a liquid crystal display device having a backlight unit, Analyzing a histogram of an image signal input from an external source; Determining whether a current value for driving the backlight unit is changed based on the analyzed histogram; And, And differentially supplying a driving current value supplied to the backlight unit for each predetermined section according to the determination result. The method of claim 6, Determining whether or not the current value for driving the backlight unit is changed Comparing the histogram of the analyzed input video signal with a preset reference threshold; Changing the driving current value if the histogram is less than the preset reference threshold level; And maintaining the drive current value when the histogram is equal to or greater than the preset reference threshold level. The method of claim 6, The step of differentially supplying the drive current value for each section When the current value supplied to the backlight unit is changed according to the analyzed histogram, a driving current value supplied to the backlight for each of a first section (between the fruits) and another second section (stabilization section) for a predetermined time period is determined. Method of driving a liquid crystal display device characterized in that the step of differentially supplying. The method of claim 8, Differentially supplying a driving current value supplied to the backlight for each of the first and second sections; Supplying a first driving current value (temporary current value) to the backlight unit during the first period; And driving the driving current value supplied to the backlight unit in the second section to a driving current value (second driving current value) according to the analyzed histogram. . The method of claim 9, And the first driving current value (temporary current value) is less than a predetermined level than the second driving current value. A liquid crystal panel for displaying an image signal; A backlight unit for supplying light to the front surface of the liquid crystal panel; A backlight controller supplying a driving current for emitting the backlight; A histogram analyzer for analyzing a histogram of an image signal input from the outside; A memory unit for storing a driving current value of the backlight unit according to a histogram; And, The driving current value according to the histogram of the input image signal analyzed by the histogram analysis unit is extracted from the memory unit, and the driving current value less than a predetermined level of the extracted driving current value is supplied to the backlight unit for a predetermined time. And a control unit for outputting a control signal to the backlight control unit. The method of claim 11, The control unit And outputting a corresponding control signal such that a corresponding drive current value extracted from the memory unit is supplied to the backlight unit when the preset time elapses.

Images