KR20130095500A - Liquid crystal display having after-image improvement effect and driving method thereof - Google Patents

Abstract

PURPOSE: A liquid crystal display device having afterimage-improving effect and a driving method thereof are provided to adjust the driving time of a backlight as much as the delay time of an image signal, thereby removing afterimages through the synchronization of the image signal and the driving time of the backlight. CONSTITUTION: An image signal measuring part (110) is vertically arranged at the front of a liquid crystal display panel (150). An image signal control part (130) outputs an X-time value, a Y-time value, and a pre-stored delay compensation value. A liquid crystal display panel timing control part (140) displays an image on the liquid crystal display panel with an image signal outputted from the image signal control part. A backlight control part (160) drives a backlight (170) through a compensated X-time value and the Y-time value. The backlight is turned on by the control of the backlight control part. [Reference numerals] (110) Image signal measuring part; (120) Delay compensation value measuring part; (130) Image signal control part; (140) Liquid crystal display panel timing control part; (150) Liquid crystal display panel; (160) Backlight control part; (170) Backlight; (AA) Image signal

Description

Liquid crystal display having an afterimage improvement effect and a driving method thereof {LIQUID CRYSTAL DISPLAY HAVING AFTER-IMAGE IMPROVEMENT EFFECT AND DRIVING METHOD THEREOF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device having an afterimage improvement effect and a driving method thereof, and more particularly, to detect a delay time of an image signal by capturing an image displayed on a liquid crystal display panel, and to adjust the driving time of the backlight by the delay time. The present invention relates to a liquid crystal display and a driving method thereof having an afterimage improving effect of removing an afterimage by matching a backlight driving time with an image signal displayed on a liquid crystal display panel.

 Recently, various flat panel display devices that can reduce weight and volume, which are disadvantages of cathode ray tubes, have emerged. Such flat panel display devices include liquid crystal display devices, field emission display devices, plasma display devices, and organic electroluminescence display devices. There is this.

Among the display devices, the liquid crystal display is mainly composed of a color filter, a liquid crystal display panel, and a backlight, and the image is driven by driving a liquid crystal.

In the liquid crystal display, the image is represented by the light generated from the backlight positioned on the rear side of the liquid crystal passing through the liquid crystal display panel. In this case, the bright part of the image turns on the liquid crystal display panel, and the dark part of the image turns off the liquid crystal display panel to express the image.

The liquid crystal of the liquid crystal display panel is a material having an intermediate property between a solid and a liquid. When the liquid crystals are arranged in a state where the polarizers are orthogonal to each other in front of and behind the liquid crystal, only a very small amount of light passes along the liquid crystal, a passage through which light can pass. If the liquid crystal is made to be in a sub-array state, a large amount of light passes along the widened liquid crystal surface. The structure of the liquid crystal is changed when the voltage is applied. Since the liquid crystal has an intermediate property between the solid and the liquid, it takes a certain time to change the structure, which is called the response speed. In the case of the cathode ray tube or the plasma display device, the response speed is very high because the light is directly emitted and controlled without such a structure, whereas in the case of the liquid crystal display device, the response speed is very slow compared to the cathode ray tube and the plasma display device because the light is controlled through the liquid crystal.

Therefore, the response speed of the liquid crystal display device is 1,000 times higher than that of the cathode ray tube and the plasma display device.

The display device cannot express a continuous image in time as in the natural world. Therefore, in general, 60 pictures are taken per second and displayed on the screen at regular intervals to express an image. At this time, an afterimage effect occurs due to the optic nerve of the human eye. In general, the human eye has an afterimage of about 1/16 seconds when a momentary still image is viewed. Therefore, in order to implement an image having no afterimage, it is necessary to delete a generated afterimage. To this end, a black screen may be inserted between the frame and the image to remove the afterimage.

In the case of the cathode ray tube and the plasma display, the light emits light instantaneously and maintains the black state without light until the next frame, so that a black screen is naturally inserted between the frame and the frame of the image, so that an image without an afterimage can be viewed. However, in the case of the liquid crystal display, since the image is represented by changing the liquid crystal while the backlight is continuously turned on, afterimages are generated due to the afterimage effect of the eyes.

In more detail, the liquid crystal display uses a vertical electrode and a horizontal electrode when driving the liquid crystal. The circuit is briefly expressed as shown in FIG. 1.

The liquid crystal driving method of the liquid crystal display device is as follows.

The first line of FIG. 1, that is, the signal of the image to be expressed in the gate 1 (Vg1) is applied to the source (Vs1, Vs2, Vs3), and then applied to the gate 1 (Vg1) to charge each capacitor in the first line. After operating the liquid crystal of the first line up to the frame and cutting off the gate 1 (Vg1), apply the signal of the image to be in the second line to the source (Vs1, Vs2, Vs3) and then apply the gate 2 (Vg2) The liquid crystal of the first line is charged and the image is repeated until the last line.

Therefore, when the image is displayed on the screen, the liquid crystal display cannot display one frame at a time at the same time. At this time, as the liquid crystal is charged and discharged, noise or an afterimage appears in the image.

As such an afterimage removal method, Korean Laid-Open Patent Publication No. 10-2011-0041266 (liquid crystal display device and its afterimage removal method) has been developed and filed.

The liquid crystal display includes a liquid crystal display panel in which a plurality of data lines and a plurality of gate lines intersect and liquid crystal cells are arranged in a matrix form; A backlight for irradiating light onto the liquid crystal display panel; And turning off the backlight in the afterimage removal mode and supplying an afterimage removal data voltage to the data lines of the liquid crystal display panel, and supplying a video data voltage to the data lines of the liquid crystal display panel in a normal driving mode. A panel driving circuit for turning on is provided.

The afterimage removing method of the LCD may include turning off the backlight and supplying an afterimage removing data voltage to data lines of the LCD panel in an afterimage removing mode; And supplying a video data voltage to data lines of the liquid crystal display panel and lighting the backlight in the normal driving mode.

However, the above-described liquid crystal display and its afterimage removal method are simply provided that the afterimage removal data voltage is applied to the liquid crystal cells of the liquid crystal display panel and the backlight is turned off within the period when the afterimage removal function is not used. If the afterimage removal function is not set, there is a problem in that the afterimage cannot be removed.

The present invention has been made to solve the above problems, by taking an image displayed on the liquid crystal display panel to detect the delay time of the image signal, by adjusting the driving time of the backlight by the delay time image signal displayed on the liquid crystal display panel It is an object of the present invention to provide a liquid crystal display and a driving method thereof having an afterimage improving effect of removing afterimages by matching the driving time of the backlight and the backlight.

According to an aspect of the present invention,

In a liquid crystal display device having a liquid crystal display panel and a backlight, the processed image signal is processed after processing an input video signal at a timing required by the liquid crystal display panel, and a vertical sync signal among the processed video signals; A horizontal time (Horizontal Sync), an X time value that is the time from the falling edge of the vertical synchronization signal to the backlight lighting pulse rising edge, a Y time value that is the time from the rising edge of the backlight lighting pulse to the falling edge, and An image signal controller outputting a stored delay correction value; A liquid crystal display panel timing controller configured to display an image on the liquid crystal display panel as an image signal output from the image signal controller; And a backlight controller configured to correct an X time value through a delay correction value output from the image signal controller, and to remove an afterimage by driving the backlight through a corrected X time value and a Y time value.

Here, the liquid crystal display device having the afterimage improvement effect is disposed perpendicular to the front surface of the liquid crystal display panel, and a plurality of light receiving elements are arranged so that a full-white pattern and a full-black pattern for each frame in the liquid crystal display panel. An image signal measuring unit for acquiring brightness values of respective regions of each frame when the outputs are alternately outputted; A vertical sync signal is output among the processed image signals from the image signal controller, and after the X time, the LCD is photographed by the image signal measuring unit to obtain brightness values of respective frames to obtain the brightness value of each frame. The area A of the brightness value of each frame of each frame photographed by the measurement unit detects the area A where the value of light corresponding to the image is photographed and the area B of which the value of the light corresponding to the image is not photographed, and the X time value Delay correction for repeating the measurement of the video signal while detecting the interval matching the image output value of the area A and the liquid crystal display panel and outputting the delay correction value, which is the increased X time value, to the image signal controller. It further comprises a value measuring unit.

Here, each of the light receiving elements of the image signal measuring unit is formed with a partition wall to block the inflow of external light.

Here, the video signal measuring unit and the delay correction value measuring unit are each modularized and provided separately to the outside, and are connected to the video signal controller.

Here, each of the light receiving elements of the video signal measuring unit is a photodiode.

Here, the backlight is an LED light source type backlight having a fast response speed to the control signal of the backlight control unit.

According to another aspect of the present invention,

In the driving method using the liquid crystal display device having the afterimage improvement effect, the liquid crystal display panel receives a video signal input from the image signal controller so that a full-white pattern and a full-black pattern are alternately displayed for each frame. A first step of outputting the processed image signal to the liquid crystal display panel timing controller after processing at the timing required by the display panel; A vertical sync signal, a horizontal sync, an X time value that is a time from a falling edge of the vertical sync signal to the backlighting pulse rising edge of the video signal processed by the video signal controller; A second step of outputting a Y time value, which is a time from the rising edge of the backlight lighting pulse to the falling edge, to the backlight controller and the delay correction value measuring unit, respectively; A third process of acquiring a brightness value for each area of each frame from the image signal measuring unit and outputting the brightness value to the delay correction value measuring unit by alternately displaying a full-white pattern and a full-black pattern in each frame on the LCD panel; After the X time elapses, the delay correction value measuring unit acquires a brightness value of each frame photographed by the image signal measuring unit and captures a value of light corresponding to an image among the brightness values of each frame region. A region and a region B where the value of light corresponding to the image is not photographed are detected, and the image signal is repeatedly measured while increasing the X time value to match the region matching the image output value of the region A and the LCD panel. Detecting and outputting a delay correction value, which is an increased X time value, to the image signal controller; A fifth step of storing the delay correction value in the image signal controller; When the actual image is displayed, the image signal input from the image signal controller is processed at the timing required by the liquid crystal display panel, and then the processed image signal, a vertical sync signal among the processed image signals, and horizontal synchronization Sync), the sixth step of outputting the X time value, the Y time value and a pre-stored delay correction value; A seventh step of displaying an image on the liquid crystal display panel by an image signal output from the image signal controller by the liquid crystal display panel timing controller; And an eighth step of correcting the X time value through the delay correction value output from the image signal controller in the backlight controller, and removing the afterimage by driving the backlight through the corrected X time value and Y time value. It features.

According to the liquid crystal display device having the afterimage improvement effect and the driving method thereof according to the present invention, the delay time of the image signal is detected by capturing an image displayed on the liquid crystal display panel, and the driving time of the backlight is adjusted by the delay time. As a result, the afterimage may be removed by matching the image driving signal displayed on the LCD panel with the backlight driving time.

1 is a circuit diagram schematically showing a general liquid crystal display device.
2 is a block diagram showing the configuration of a liquid crystal display device having an afterimage improvement effect according to the present invention.
3 is a schematic diagram schematically illustrating a configuration of an image signal measuring unit and a delay correction value measuring unit of a liquid crystal display having an afterimage improvement effect according to the present invention.
4 is a perspective view illustrating a configuration of an image signal measuring unit of a liquid crystal display having an afterimage improvement effect according to the present invention.
5 to 7 are timing diagrams illustrating a vertical synchronization signal, a backlight lighting pulse, and a timing of an image output to explain a liquid crystal display device having an afterimage improvement effect according to the present invention.
8 is a flowchart illustrating a method of driving a liquid crystal display device having an afterimage improvement effect according to the present invention.

Hereinafter, a configuration of a liquid crystal display having an afterimage improvement effect according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

2 is a block diagram showing the configuration of a liquid crystal display device having an afterimage improvement effect according to the present invention, Figure 3 is a configuration of an image signal measuring unit and a delay correction value measuring unit of the liquid crystal display device having an afterimage improvement effect according to the present invention 4 is a schematic view showing a configuration of an image signal measuring unit of a liquid crystal display device having an afterimage improvement effect according to the present invention, and FIGS. 5 to 7 are liquid crystal displays having an afterimage improvement effect according to the present invention. To illustrate the device, it is a timing diagram showing the timing of the vertical synchronization signal, the backlight lighting pulse, and the video output.

2 to 7, the liquid crystal display 100 having the afterimage improvement effect according to the present invention includes an image signal measuring unit 110, a delay correction value measuring unit 120, and an image signal controller 130. ), A liquid crystal display panel timing controller 140, a liquid crystal display panel 150, a backlight controller 160, and a backlight 170.

First, the image signal measuring unit 110 and the delay correction value measuring unit 120 are each modularized to be formed separately from the liquid crystal display and separately provided to the outside, and the circuit is provided through the image signal controller 130 and the port. Is connected as an enemy. The image signal controller 130, the liquid crystal display panel timing controller 140, the liquid crystal display panel 150, the backlight controller 160, and the backlight 170 are provided in the liquid crystal display device. That is, the liquid crystal display device 100 having the afterimage improvement effect according to the present invention measures a delay correction value by measuring a delay correction value through an image signal measuring unit 110 and a delay correction value measuring unit 120 at the time of manufacturing a product. Is stored in the product, and the delay correction value eliminates the afterimage during operation after the product is released.

In addition, the image signal measuring unit 110 is disposed perpendicularly to the front surface of the liquid crystal display panel 150 to be described below, and the plurality of light receiving elements 111 are arranged so that each frame of the liquid crystal display panel 150 is full- When the white pattern and the full-black pattern are alternately output, the brightness value of each frame area is obtained. Here, each of the light receiving elements 111 of the image signal measuring unit 110 is formed with a partition wall 113 to block the inflow of external light on the outer surface, as shown in Figure 4, the photodiode Is applied.

In addition, the delay correction value measuring unit 120 receives a vertical sync signal among the processed video signals from the video signal controller 130 to be described later, and X time after the rising edge of the vertical sync signal. Afterwards, the liquid crystal display panel 150 is photographed through the image signal measuring unit 110 to obtain brightness values for each frame region, as shown in FIG. 6, and thus the area of each frame photographed by the image signal measuring unit 110. Detecting the area A where the value of light corresponding to the image among the brightness values of each star is photographed and the area B where the value of the light corresponding to the image is not captured, and repeatedly measuring the video signal while increasing the X time value A An area matching the area and the image output value of the liquid crystal display panel 150 is detected, and a delay correction value, which is an increased X time value, is output to the image signal controller 130.

In addition, the image signal controller 130 processes the input image signal at a timing required by the liquid crystal display panel 150, and then processes the processed image signal, a vertical sync signal among the processed image signals, and a horizontal synchronization ( Horizontal Sync), the X time value from the falling edge of the vertical sync signal to the rising edge of the backlight lighting pulse, the Y time value from the rising edge of the backlight lighting pulse to the falling edge, and the stored delay compensation value. do.

In addition, the liquid crystal display panel timing controller 140 outputs the image signal output from the image signal controller 130 to the liquid crystal display panel 150.

Subsequently, the liquid crystal display panel 150 displays an image signal output from the liquid crystal display panel timing controller 140.

Subsequently, as shown in FIG. 7, the backlight controller 160 uses the delay correction value output from the image signal controller 130 to determine the backlight lighting pulse from the falling edge of each pulse of the vertical sync signal of the video signal. The X time value, which is the time to the rising edge, is corrected, and the afterimage is removed by driving the backlight 170 to be described below through the corrected X time value and the Y time value.

Meanwhile, the backlight 170 is turned on under the control of the backlight controller 160. Here, the backlight 170 is preferably an LED light source type backlight having a fast response speed to the control signal of the backlight controller 160.

Hereinafter, a method of driving a liquid crystal display having an afterimage improvement effect according to the present invention will be described in detail with reference to the accompanying drawings.

8 is a flowchart illustrating a method of driving a liquid crystal display device having an afterimage improvement effect according to the present invention.

First, as shown in FIG. 5, an ideal timing for preventing afterimages from occurring should coincide with the timing at which the image output ends and the timing at which the backlight is turned on.

However, a delay is generated in the image actually output to the liquid crystal display panel 150. As shown in FIG. 6, a vertical synchronization signal exists at a portion where each frame of the image starts. After the vertical synchronization signal, an image of each frame is output. At this time, a delay D due to an image processing delay occurs. As a result, the actual output image and the lighting section B of the backlight 170 overlap each other. In this case, an afterimage occurs in the image.

Therefore, the present invention outputs an X time value that is the time from the falling edge of the vertical synchronization signal to the backlighting pulse rising edge, a Y time value that is the time from the rising edge of the backlight lighting pulse to the falling edge, and the stored delay correction value. By removing the overlapping section of the image is actually output and the lighting section of the backlight 170 to prevent the afterimage occurs.

In this order, the liquid crystal display panel 150 displays the image signals input from the image signal controller 130 such that the full-white pattern and the full-black pattern are alternately displayed for each frame. After processing at the required timing, the processed video signal is output to the liquid crystal display panel timing controller 140 (S100).

Subsequently, a vertical sync signal, a horizontal sync signal, a horizontal sync signal, and an X time value, which is the time from the falling edge of the vertical sync signal to the backlight lighting pulse rising edge, among the video signals processed by the video signal controller 130. In operation S110, the Y time value, which is the time from the rising edge of the backlight lighting pulse to the falling edge, is output to the backlight controller 160 and the delay correction value measuring unit 120.

In this state, when the full-white pattern and the full-black pattern are alternately displayed on each frame in the liquid crystal display panel 150, the image signal measuring unit 110 acquires the brightness value of each frame to delay correction value. Output to the measuring unit 120 (S120).

Then, after the X time elapses, the delay correction value measuring unit 120 acquires the brightness value of each frame photographed by the image signal measuring unit 110 and applies the light corresponding to the image among the brightness values of each frame area of each frame. It detects the area A where the value is taken and the area B where the value of light corresponding to the image is not taken, and repeatedly measures the video signal while increasing the X time value to match the image output value of the area A and the LCD panel. In step S130, the controller detects a section to be detected and outputs a delay correction value, which is an increased X time value, at this time (S130).

Then, when the delay correction value is transmitted from the delay correction value measuring unit 120, the image signal controller 130 stores the delay correction value in the storage means (not shown) (S140). Up to this point is a process performed in the manufacturing process.

In this state, when the actual image is displayed after the product is shipped and installed, the processed image signal and the processed image are processed after processing the image signal input from the image signal controller 130 at the timing required by the liquid crystal display panel 150. Among the signals, a vertical sync signal, a horizontal sync, an X time value, the Y time value, and a previously stored delay correction value are output (S150).

Then, the liquid crystal display panel timing controller 140 displays an image on the liquid crystal display panel 150 as an image signal output from the image signal controller 130 (S160).

In addition, the backlight controller 160 corrects the X time value using the delay correction value output from the image signal controller 130, and drives the backlight 170 through the corrected X time value and the Y time value to remove afterimages. (S170).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

110: image signal measuring unit 120: delay correction value measuring unit
130: video signal controller 140: liquid crystal display panel timing controller
150: liquid crystal display panel 160: backlight control unit
170: backlight

Claims (7)

In a liquid crystal display device comprising a liquid crystal display panel and a backlight,
Processing the input video signal at the timing required by the liquid crystal display panel, and then processing the processed video signal, a vertical sync signal among the processed video signals, horizontal sync, and polling of the vertical sync signal. An image signal controller for outputting an X time value that is an time from an edge to the backlight lighting pulse rising edge, a Y time value that is a time from a rising edge of the backlight lighting pulse to a falling edge, and a pre-stored delay correction value;
A liquid crystal display panel timing controller configured to display an image on the liquid crystal display panel as an image signal output from the image signal controller; And
And a backlight controller to correct an X time value through a delay correction value output from the image signal controller, and to remove an afterimage by driving the backlight through a corrected X time value and a Y time value. Liquid crystal display having a. The method of claim 1,
The liquid crystal display device having the afterimage improvement effect,
Vertically disposed on the front surface of the liquid crystal display panel, and a plurality of light receiving elements are arranged so that the full-white pattern and the full-black pattern are alternately outputted for each frame in the liquid crystal display panel. An image signal measuring unit to obtain a signal;
A vertical sync signal is output among the processed image signals from the image signal controller, and after the X time, the LCD is photographed by the image signal measuring unit to obtain brightness values of respective frames to obtain the brightness value of each frame. The area A of the brightness value of each frame of each frame photographed by the measurement unit detects the area A where the value of light corresponding to the image is photographed and the area B of which the value of the light corresponding to the image is not photographed, and the X time value Delay correction for repeating the measurement of the video signal while detecting the interval matching the image output value of the area A and the liquid crystal display panel and outputting the delay correction value, which is the increased X time value, to the image signal controller. A liquid crystal display device having an afterimage improvement effect, further comprising a value measuring unit. 3. The method of claim 2,
Each of the light receiving elements of the video signal measuring unit is
Liquid crystal display device having an afterimage improvement effect characterized in that the partition wall is formed on the outer surface to block the inflow of external light. 3. The method of claim 2,
The image signal measuring unit and the delay correction value measuring unit,
A liquid crystal display device having an afterimage improvement effect, characterized in that each module is provided separately from the outside, and is connected to the image signal controller. 5. The method of claim 4,
Each of the light receiving elements of the video signal measuring unit is
A liquid crystal display device having an afterimage improvement effect, which is a photodiode. The method of claim 1,
The backlight is,
And an LED light source-type backlight having a fast response speed with respect to a control signal of the backlight controller. In the driving method using the liquid crystal display device having the afterimage improvement effect of claim 1,
In the liquid crystal display panel, the image signal input from the image signal controller is processed at the timing required by the liquid crystal display panel so that the full-white pattern and the full-black pattern are alternately displayed for each frame. A first step of outputting to the panel timing controller;
A vertical sync signal, a horizontal sync, an X time value that is a time from a falling edge of the vertical sync signal to the backlighting pulse rising edge of the video signal processed by the video signal controller; A second step of outputting a Y time value, which is a time from the rising edge of the backlight lighting pulse to the falling edge, to the backlight controller and the delay correction value measuring unit, respectively;
A third process of acquiring a brightness value for each area of each frame from the image signal measuring unit and outputting the brightness value to the delay correction value measuring unit by alternately displaying a full-white pattern and a full-black pattern in each frame on the LCD panel;
After the X time elapses, the delay correction value measuring unit acquires a brightness value of each frame photographed by the image signal measuring unit and captures a value of light corresponding to an image among the brightness values of each frame region. A region and a region B where the value of light corresponding to the image is not photographed are detected, and the image signal is repeatedly measured while increasing the X time value to match the region matching the image output value of the region A and the LCD panel. Detecting and outputting a delay correction value, which is an increased X time value, to the image signal controller;
A fifth step of storing the delay correction value in the image signal controller;
When the actual image is displayed, the image signal input from the image signal controller is processed at the timing required by the liquid crystal display panel, and then the processed image signal, a vertical sync signal among the processed image signals, and horizontal synchronization Sync), the sixth step of outputting the X time value, the Y time value and a pre-stored delay correction value;
A seventh step of displaying an image on the liquid crystal display panel by an image signal output from the image signal controller by the liquid crystal display panel timing controller; And
And an eighth step of correcting the X time value through the delay correction value output from the image signal controller in the backlight controller, and removing the afterimage by driving the backlight through the corrected X time value and the Y time value. A driving method of a liquid crystal display device having an afterimage improvement effect.

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