KR101329705B1 - LC panel and display device and driving method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a driving method thereof, and more particularly, to a liquid crystal panel and a liquid crystal display device and a method of driving the same, which eliminate local local image retention by supplying a uniform common voltage to the display panel. By applying different common voltages, the uneven common voltage is applied to the center and side ends of the display panel, and the flicker and the uneven common voltage are applied due to the manufacturing characteristics of the source driver and the display panel. It provides the advantage of providing higher quality image quality by improving problems such as afterimages.

Description

Liquid crystal panel and display device and driving method thereof

1 is a block diagram showing a basic configuration of a general liquid crystal display device

Fig. 2 is a view schematically showing the configuration of the liquid crystal panel in the configuration of Fig. 1

3 is a view for explaining a common voltage supply method in a liquid crystal panel according to the related art.

4 is a diagram illustrating a voltage level of a common voltage required for each position in a general liquid crystal panel;

5 is a plan view of a liquid crystal panel according to the present invention.

6 is a plan view showing the configuration of a liquid crystal display according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

a ~ h: Sub display area 100,200: Liquid crystal panel

110: 250: disconnection part 220a ~ 220h: source driver

210a ~ 210d: Gate Driver 240a ~ 240h: Common Wiring

Vcom1 ~ Vcom8: Common voltage 230: Common voltage generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a driving method thereof, and more particularly, to a liquid crystal panel and a liquid crystal display device and a driving method thereof in which a local screen persistence is eliminated by supplying a uniform common voltage to the display panel.

Among display devices, liquid crystal display devices have advantages of small size, thinness and low power consumption and are used in notebook computers, office automation devices, audio / video devices, and the like. In particular, an active matrix type liquid crystal display device using a thin film transistor (hereinafter referred to as "TFT") as a switching element is suitable for displaying dynamic images.

1 is a block diagram showing a basic configuration of a general liquid crystal display device, which is largely divided into a liquid crystal panel 2 and an LCM driving circuit portion 26. [

In each configuration, the interface 10 includes data (RGB Data) and control signals (input clock, horizontal synchronizing signal, vertical synchronizing signal, data enable) input to the LCM driving circuit unit 26 from a driving system such as a personal computer. Signals) and the like are supplied to the timing controller 12. LVDS (Low Voltage Differential Signal) interface and TTL interface are mainly used for data and control signal transmission from the drive system. In addition, the interface function may be collected and used together with the timing controller 12 in a single chip.

2, the liquid crystal panel 2 includes a plurality of data lines DL1 to DLm and a plurality of gate lines GL1 to GLn intersecting each other on a substrate using a glass to form a plurality of pixel regions, A thin film transistor (TFT) and a liquid crystal (LC) are formed in the region to display a screen.

The timing controller 12 drives a gate driver 20 composed of a plurality of gate driver ICs and a source driver 18 composed of a plurality of drive ICs by using a control signal inputted through the interface 10 Lt; / RTI > And also transmits the data input through the interface 10 to the source driver 18. [

The reference voltage generator 16 generates reference voltages of a digital to analog converter (DAC) used in the source driver 18. The reference voltages are set by the manufacturer based on the transmittance-voltage characteristics of the panel.

The source driver 18 selects reference voltages of the input data in response to control signals input from the timing controller 12, and supplies the selected reference voltage to the liquid crystal panel 2 to control the rotation angle of the liquid crystal molecules.

The gate driver 20 performs on / off control of thin film transistors TFTs arranged on the liquid crystal panel 2 in response to control signals input from the timing controller 12. The thin film transistors TFT on the liquid crystal panel 2 are sequentially driven by one line by sequentially enabling the gate lines GL1 to GLn by one horizontal synchronizing time, so that the source driver 18 The analog image signals supplied from the N-th transistors are applied to the pixels connected to the respective TFTs.

The power supply voltage generator 14 supplies operating power of each component and generates and supplies a common voltage of the liquid crystal panel 2.

And a back-light unit (not shown), which includes at least one lamp to supply light to the liquid crystal panel 2.

In the liquid crystal display having the above-described configuration, in order to drive the liquid crystal panel 2, a common voltage for rotating the liquid crystal molecules by making a voltage difference with the analog image signal supplied from the source driver 18 for each pixel Vcom), which is normally supplied to the liquid crystal panel 2 through the source driver 18.

3 is a view illustrating a common voltage supply method in a liquid crystal panel according to the related art, and the direction in which the common voltage propagates in the liquid crystal panel 30 and the source drivers 40a to 40h and the liquid crystal panel 30 is different. Is shown.

The liquid crystal panel 30 has a common wiring (not shown) to which the whole is connected, and the liquid crystal panel through the source drivers 40a and 40h at the front end and the end of the source drivers 40a to 40h, respectively. The common voltage Vcom flowing into the liquid crystal panel 30 is applied to common wirings on both sides of the liquid crystal panel 30, and is gradually common to the inner pixels from the outer pixels of the liquid crystal panel 30 through the common wirings connected to each other. Indicates that the voltage vcom is supplied.

In addition, the common voltage supply method in the liquid crystal panel described above is a method commonly applied to all types of liquid crystal panels or a method mainly applied to IPS mode liquid crystal panels.

However, as described above with reference to FIG. 3, the common voltage is supplied to both ends of the liquid crystal panel through two source drivers, and then the common voltage propagates through the common liquid crystal panel has several problems. A description with reference to FIG. 4 is as follows.

FIG. 4 is a diagram illustrating voltage levels of common voltages required according to actual measurement for each position in the liquid crystal panel 50. Each region from A to H in the liquid crystal panel corresponding to the plurality of source drivers 60a to 60h is shown in FIG. It illustrates that a common voltage of various voltage levels is required. The reason why a common voltage of various voltage levels is required in the same liquid crystal panel is that each panel region where an image is displayed by each of the plurality of source drivers 60a to 60h. When the optimum state of the flicker is maintained for each region in the liquid crystal panel due to the characteristics of the source driver and the panel characteristics, the above-described various voltage levels, that is, the central region of the liquid crystal panel 50 has a higher voltage level than the side region. Common voltage is required.

Therefore, the method of supplying the same common voltage to all the regions of the liquid crystal panel by the method described with reference to FIG. 3 does not apply the common voltage of various voltage levels for each panel region, as shown in FIG. 4. This causes an after-image afterimage, which is accompanied by an undesirable result of deterioration of image quality.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide the best image quality by improving local afterimages by applying common voltages of various voltage levels for each region of a liquid crystal panel.

The present invention to achieve the above object, the substrate; A data line formed on the substrate to transmit image data; A gate line formed on the substrate to transmit a scan signal, the gate line crossing the data line; A plurality of liquid crystal pixels each formed in a section captured by the data line and the gate line; Provided is a liquid crystal panel including n sub display areas in which a single line is formed on the common line at each boundary of each sub display area with one area formed of common wiring connected to each other as one sub display area.

In the liquid crystal panel, each of the liquid crystal pixels includes a thin film transistor which is switched and controlled by the scan signal to output the image data, a storage capacitor which stores the image data output from the thin film transistor, and is output from the thin film transistor. And a liquid crystal capacitor whose light transmittance is controlled by the image data.

In the liquid crystal panel, each of the liquid crystal pixels is a transverse electric field type liquid crystal pixel.

In the liquid crystal panel, the common wiring between the sub display areas may be formed to be electrically disconnected from each other.

The common wiring formed in each of the sub display areas may have a mesh shape.

In addition, the present invention, the substrate; A plurality of liquid crystal pixels formed on the substrate; N sub display areas in which a single line is formed on the common line at each boundary of each sub display area with one area formed of the common wiring connected to each other as one sub display area; N source drivers for supplying image data to the liquid crystal pixels of the sub display areas and applying a common voltage to a common wiring of the sub display areas; A gate driver for supplying a scan signal for writing the image data to each of the liquid crystal pixels; The present invention provides a liquid crystal display including a common voltage generation unit configured to generate common voltages having different voltage levels and transfer them to the respective source drivers.

In the liquid crystal display, each of the liquid crystal pixels includes a thin film transistor configured to be controlled by the scan signal to output the image data, a storage capacitor to store the image data output from the thin film transistor, and an output from the thin film transistor. And a liquid crystal capacitor whose light transmittance is controlled by the image data.

In the liquid crystal display device, each liquid crystal pixel is a liquid crystal pixel having a transverse electric field formation structure.

In the LCD, the n source drivers correspond to the n sub display areas one by one to supply the image data and the common voltage.

In the liquid crystal display, the common voltages applied to the n sub display areas are different voltage levels.

In the liquid crystal display, the common wiring between the sub display areas may be formed in an electrically disconnected form.

In the liquid crystal display device, the common wiring formed in each of the sub display areas may have a mesh shape.

In addition, the present invention provides a single display area having a substrate, a plurality of liquid crystal pixels formed on the substrate, and a common wiring connected to each other as one sub display area, and a disconnection line is formed on the common wiring at each boundary of each sub display area. N source drivers for supplying image data to the formed n sub display areas, the liquid crystal pixels of the sub display areas, and applying a common voltage to a common wiring of the sub display areas, and A liquid crystal display device driving method comprising: a gate driver for supplying a scan signal to be written to a liquid crystal pixel, and a common voltage generator for generating a common voltage having a different voltage level and transferring the same to a source driver; A first step of dividing the area into n sub display areas; Applying a common voltage having a different voltage level to each of the n sub display areas; And a third step of displaying an image by applying image data to each of the sub display areas.

In the driving method, the first step includes: configuring n source drivers to output image data to the liquid crystal panel; The method may further include forming a common wiring of the liquid crystal panel corresponding to the control regions of the n source drivers and electrically disconnecting the n source drivers, and dividing the same into n sub display regions.

In the driving method, the second step includes: generating n common voltages having different voltage levels; The method may further include transmitting the n common voltages to the n source drivers, respectively.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

FIG. 5 is a plan view of the liquid crystal panel according to the present invention, and in particular, the characteristics of common wirings.

In the drawing, a plurality of data lines (not shown) are formed on the liquid crystal panel 50 in the vertical direction, and a plurality of gate lines (not shown) are formed in the horizontal direction, and although not shown, Liquid crystal pixels are formed in the crossing regions of the gate lines, respectively. In this case, the liquid crystal pixel includes a thin film transistor, a liquid crystal capacitor, and a storage capacitor.

As shown in the drawing, common wirings 105a to 105h for supplying a common voltage are formed in the liquid crystal pixels formed on the liquid crystal panel 100, and the common wirings 105a to 105h are formed in the display area of the liquid crystal panel. It is formed to be connected to each other over the whole, but forms a plurality of disconnected portions 110 to have a plurality of divided forms structurally independent for each sub display area (a ~ h), the formation of the disconnected portion (110) The position is formed based on the boundary of the control region between adjacent source drivers.

In summary, the common wirings 105a to 105h are electrically disconnected from each other through the plurality of disconnecting units 110, so that the liquid crystal panel 100 forms a plurality of sub display areas a to h. In this configuration, common voltages having different voltage levels may be applied to the sub display areas a to h.

For reference, the common wirings 105a to 105h illustrated in FIG. 5 illustrate a mesh form mainly adopted in a liquid crystal pixel having a transverse electric field (IPS) structure as an example.

As described above, when the common voltages 105a to 105h are electrically independent for each of the sub display areas a to h, and different common voltages are applied to each sub display area, a common voltage most suitable for the screen display is applied. Since the liquid crystal panel may be applied for each position, there is an advantage in that the flicker generated in some areas of the liquid crystal panel may be removed by the characteristics of the source driver and the panel characteristics.

6 is a plan view illustrating a configuration of a liquid crystal display device including the liquid crystal panel according to the present invention of FIG. 5 described above.

Referring to the configuration of FIG. 6, image data is transferred to the liquid crystal panel 200, the gate drivers 210a to 210d for outputting a scan signal to the liquid crystal panel 200, and the liquid crystal panel 200 in synchronization with the scan signal. Source drivers 220a to 220h to output and a common voltage generation unit 230 for supplying a common voltage (Vcom) having a plurality of voltage levels to the liquid crystal panel 200, the liquid crystal panel 200 is Since it is the same as the configuration and features of the liquid crystal panel 100 of FIG. 5 described above, no further description will be given. Particularly, reference numerals 240a to 240h denote common wirings, and reference numeral 250 denotes disconnection portions between common wiring lines 240a to 240h, and positions of the disconnection portions 250 are formed at boundaries between control regions between adjacent source drivers 220a to 220h. Form on the basis of.

The gate drivers 210a to 210d output scan signals to a plurality of gate lines configured in the liquid crystal panel 200, and the source drivers 220a to 220h are synchronized with the scan signals to the liquid crystal panel 200. Output video data.

In particular, the source drivers 220a to 220h are common wirings 240a to 240h of the plurality of sub display areas a to h divided by the disconnection unit 250, and common voltages Vcom1 having different voltage levels. Apply ~ Vcom8).

The common voltages Vcom1 to Vcom8 applied to each of the sub display areas a to h are output from the common voltage generator 230, and at this time, the common voltages Vcom1 to Vcom8 are output from the corresponding sub display areas. The optimum voltage without flicker and afterimage may be calculated through experiments.

In addition, the number of common voltages of different voltage levels generated and output from the common voltage generator 230 is the same as the number of source drivers and the number of sub display areas of the liquid crystal panel 200. Therefore, in FIG. 6, since eight source drivers 220a to 220h are configured as an example, the display area of the liquid crystal panel 200 is divided into eight sub display areas a to h through the disconnection unit 250. The common voltage generator 230 generates and outputs common voltages Vcom1 to Vcom8 having eight voltage levels to be applied to the common electrodes of the sub display areas a to h.

For reference, the common wirings 240a to 240h illustrated in FIG. 6 illustrate a mesh form mainly adopted in a liquid crystal pixel having a transverse electric field (IPS) structure as an example.

As described above, the independent common wiring 240a to 240h is applied to each of the sub display areas a to h, and different common voltages Vcom1 to Vcom8 are applied to each sub display area. Since the common voltage may be applied for each position of the liquid crystal panel, problems such as flicker and afterimages generated in some areas of the liquid crystal panel may be improved due to characteristics of the source driver and panel characteristics.

The operation of the liquid crystal display according to the present invention described above will be briefly described with reference to FIG. 6 again.

First, in the liquid crystal panel 200, a disconnection unit 250 is formed on the common electrode in accordance with a control area in which each of the source drivers 220a to 220h outputs image data. a ~ h). In other words, the sub display areas a to h are divided areas formed by common wires 240a to 240h that are electrically independent of the plurality of disconnection units 250.

Next, the common voltages Vcom1 to Vcom8 having different voltage levels generated by the common voltage generation unit 230 are transferred to each of the source drivers 220a to 220h, respectively, and then each common voltage ( The Vcom1 to Vcom8 are applied to the common wires 240a to 240h of the sub display areas a to h through the source drivers 220a to 220h, respectively.

Subsequently, an image is displayed in each of the sub display areas through the scan signal output driving of the gate drivers 210a to 210d and the image data output driving of the source drivers 220a to 220h. In this case, since different common voltages are appropriately applied to the sub display areas a to h, partial flicker and screen persistence do not occur.

The liquid crystal panel, the liquid crystal display device, and the driving method of the liquid crystal display device according to the present invention described above are non-uniform in the center and side ends of the display panel because different common voltages can be applied to the plurality of regions of the display panel. It is possible to improve the phenomenon that the common voltage is applied, and to solve the problems such as flicker and afterimage caused by the uneven common voltage applied due to the manufacturing characteristics of the source driver and the display panel. Can provide.

Claims (15)

A substrate; A data line formed on the substrate to transmit image data; A gate line formed on the substrate to transmit a scan signal, the gate line crossing the data line; A plurality of liquid crystal pixels each formed in a section captured by the data line and the gate line; A liquid crystal panel comprising n sub display areas in which a single line is formed on the common line at each boundary of each sub display area with one area formed of common wiring connected to each other as one sub display area. The method according to claim 1, Each liquid crystal pixel, A liquid crystal capacitor whose light transmittance is controlled by a thin film transistor switched by the scan signal to output the image data, a storage capacitor storing the image data output from the thin film transistor, and the image data output from the thin film transistor. Liquid crystal panel comprising a The method according to claim 1, Each liquid crystal pixel is a liquid crystal panel of a transverse electric field method The method according to claim 1, The common wiring between the sub display areas may be formed in an electrically disconnected form. The method according to claim 1, The common wiring formed in each sub display area has a mesh shape. A substrate; A plurality of liquid crystal pixels formed on the substrate; N sub display areas in which a single line is formed on the common line at each boundary of each sub display area with one area formed of the common wiring connected to each other as one sub display area; N source drivers for supplying image data to the liquid crystal pixels of the sub display areas and applying a common voltage to a common wiring of the sub display areas; A gate driver for supplying a scan signal for writing the image data to each of the liquid crystal pixels; A liquid crystal display comprising a common voltage generator for generating common voltages having different voltage levels and delivering the same to the source drivers. The method of claim 6, Each liquid crystal pixel, A liquid crystal capacitor whose light transmittance is controlled by a thin film transistor switched by the scan signal to output the image data, a storage capacitor storing the image data output from the thin film transistor, and the image data output from the thin film transistor. A liquid crystal display The method of claim 6, Each of the liquid crystal pixels is a liquid crystal pixel having a transverse electric field formation structure. The method of claim 6, The n source drivers correspond to the n sub display areas one by one to supply the image data and the common voltage. The method of claim 6, A common voltage applied to the n sub display areas is at a different voltage level. The method of claim 6, The common wiring between the sub display areas is formed in an electrically disconnected form. The method of claim 6, The common wiring formed in each of the sub display areas has a mesh shape. N sub-displays in which a single line is formed on the common line at each boundary of each sub-display area, with one sub display area having a substrate, a plurality of liquid crystal pixels formed on the substrate, and a common wiring connected to each other as one sub display area. N source drivers for supplying image data to an area, a liquid crystal pixel of each of the sub display areas, and applying a common voltage to a common wiring of each of the sub display areas, and the image data to be written to the liquid crystal pixels. A method of driving a liquid crystal display device comprising: a gate driver for supplying a scan signal; and a common voltage generator for generating a common voltage having a different voltage level and transferring the generated common voltage to each of the source drivers. A first step of dividing the display area of the liquid crystal panel into n sub display areas; Applying a common voltage having a different voltage level to each of the n sub display areas; A third step of displaying an image by applying image data to each of the sub display areas; Liquid crystal display driving method comprising The method of claim 13, In the first step, Configuring n source drivers to output image data to the liquid crystal panel; Forming common lines of the liquid crystal panel corresponding to the control regions of the n source drivers and electrically disconnecting the n source drivers, and dividing them into n sub display regions. Liquid crystal display device driving method further comprising The method of claim 14, The second step comprises: Generating n common voltages having different voltage levels; Transferring the n common voltages to the n source drivers, respectively Liquid crystal display device driving method further comprising

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