KR20040048447A - Driving method and panel structure of Liquid Crystal Display - Google Patents

Abstract

PURPOSE: A method for driving an LCD and a structure of an LCD panel are provided to increase density of pixels and improve an aperture ratio of the pixels by preventing a variation of image signals due to the mutual interference between image signals on each block boundary. CONSTITUTION: An LCD includes a data driver(310) having an image signal voltage supply source. NxM data lines are formed with M blocks having N data lines. The image signal voltage supply source(320) is used for supplying image signal voltages to the M data lines in block units. The image signal voltage supply source includes N output channels to apply image signal voltages to the N data lines of the M data lines and one or more compensation channels. The compensation channels are connected to the data lines of each boundary of the data line blocks through a switch.

Description

Driving method and panel structure of liquid crystal display device {Driving method and panel structure of Liquid Crystal Display}

According to an embodiment of the present invention, a data driver includes an N × M data line divided into M blocks of N data lines, and an image signal voltage supply source for sequentially applying an image signal voltage to each of the M data line blocks in block units. A panel block liquid crystal display device comprising: the image signal voltage source further comprises one or more compensation output channels in addition to the N output channels for applying the image signal voltage for each of the N data lines of each data line block. The compensation output channel further includes a liquid crystal display and a driving method thereof, which are connected to data lines existing at boundaries of the respective data line blocks through switches.

Liquid crystal display (LCD), one of the flat panel display devices for displaying letters, symbols, or graphics, is a display that combines liquid crystal technology and semiconductor technology by using the optical properties of liquid crystals whose molecular arrangement is changed by an electric field. Device. A thin film transistor (TFT) liquid crystal display uses a TFT as a switching element for turning an internal pixel on and off, and the pixels are turned on and off as the TFT is turned on and off. Therefore, independent video signal control between adjacent pixels is possible by the switching function of the TFT.

In a typical TFT liquid crystal display device, as shown in FIG. 1, cells 130 constituting pixels are arranged in an array, and each cell includes a liquid crystal cell 134, a storage capacitor (C _ST ), and a switch. It consists of TFT 132 which functions.

A source electrode of each TFT is connected to and then connected in common to a column (column) direction to form a data line (D1~D _X), the data driver 120, a gate electrode of each TFT is low (row) The scan lines S1 to S _Y are connected in common to each other, and then connected to the gate driver 110 to implement a display device having an X × Y resolution. The data driver 120 may also be referred to as a source driver or a column driver, and the gate driver may also be referred to as a row driver or a scan driver.

Conventionally, in manufacturing an active matrix panel including the data driver (hereinafter, the "data driver" includes both a digital data driver or an analog data driver unless otherwise specified), the data driver circuit and the After the panel was separated and manufactured, a method of connecting them was used.

However, when using this method, the pixels must be larger than a certain size because the space required for the connection must be secured. As such, since the pixels must be manufactured to a predetermined size or more, there is a limit in reducing the pixels to a predetermined size or less. Therefore, there was a limit to increasing the pixel density of the panel.

It is designed to solve this problem by embedding the data driver circuit on the panel. This approach reduces the space needed to connect the panel with the data driver circuitry, resulting in higher pixel density by reducing the pixel size of the panel.

However, it is still difficult to implement the entire data driver circuit on a panel due to a process technology problem. In other words, as the resolution of the panel increases, each data line arranged in the panel also increases, so that all data lines are connected to a video signal voltage supply source (e.g., in a video controller or a digital data driver in an analog data driver). In order to connect one-to-one with the output of the output buffer, the output channel of the video signal voltage source must be increased to match the number of data lines of the panel. In addition, since the output of the image signal voltage source and the data line of the panel must be connected, the pixels cannot be reduced to a predetermined size or less.

Therefore, a display panel having a high resolution and a high pixel density is currently designed using a hybrid scheme in which only a part of circuits are embedded on the panel.

One example of the hybrid method is a block address driving method. FIG. 2 illustrates a panel structure of a panel block liquid crystal display device having an analog data driver 210 driven by a conventional block address driving method.

In the panel block liquid crystal display, N × M data lines are divided into N blocks by N data lines and driven. The analog data driver 210 includes a video controller 220, and N video signal voltages V [0] to V [N] are output from the video controller 220, whereby N × M signals on the panel are output. It must be applied to N x M pixels through the data line.

However, since the video signal provided by the video controller 220 is provided through N channels, the video signal voltage cannot be simultaneously applied to the N × M data lines. Accordingly, the video controller must sequentially apply M signal voltages in data line block units B1 to BM by repeating M times during the low line time.

To this end, a shift register 230 for outputting M switch signals, a level shifter 240, an output buffer 250, and the like are required to apply M sequential outputs, and the output of the output buffer 250 is required. A switch array block 260 used as a control signal is located before each data line.

N switches of the switch array block 260 are turned on by the output of the output buffer 250 so that the image signal voltages are sequentially applied to each of the N data lines in block units so that the pixels are connected to each data line. The video signal voltage is provided.

For example, after the image signal voltage is applied to the pixels on C [1] to C [N] of the first data line block B1, another N image signal voltages provided by the video controller 220 are applied. Is applied to pixels on C [N + 1] to C [2N] of the adjacent data line block B2.

By repeating M times in this manner, an image signal voltage may be applied to all N × M pixels located on one row line.

Accordingly, the video signal voltage output from the video controller 220 may be supplied to the entire panel as N interconnection lines.

However, when driving using the block address method, the video signal is changed at the boundary of each data line block due to mutual interference of the video signals, and the image quality is degraded.

For example, in FIG. 2, after the image signal voltage is applied to the pixels P [1] to P [N] through C [1] to C [N] of the data line block B1 on the panel. The image signal voltage is applied to the pixels P [N + 1] to P [2N] through C [N + 1] to C [2N] of the data line block B2. At this time, the pixel electrode of the pixel P [N] to which the voltage is applied at the time of driving the previous block is in a floating state which is not connected to any voltage supply source. Accordingly, the image signal voltage of the pixel electrode of P [N] is applied to the parasitic coupling capacitance 370 when a voltage corresponding to C [N + 1], which is an adjacent data line, and a pixel P [N + 1] thereof is applied. The value is changed.

As the image signal voltage of the pixel electrode of P [N] is changed, a change occurs in the expression of the image gray level of the pixel, and thus the image quality of the entire panel is degraded. As described above, the change in the image signal voltage due to the parasitic coupling capacitance occurs at the block boundary of each data line whenever the image signal voltage is sequentially applied to each data line block.

In order to prevent such mutual interference of the video signal, the distance between the pixels must be widened to reduce the parasitic coupling capacitance, but as the distance between the pixels is widened, the aperture ratio of the pixel is lowered and the gray scale that can be expressed is also lowered. there is a problem.

Accordingly, the present inventors have studied to solve the above-described problems, and as a result, when the image signal voltage source applies the image signal voltage to a predetermined data line block, the inventors also apply to the last data line of the data line block adjacent to the data line block. When the video signal voltage is applied, it is confirmed that mutual interference between data line blocks can be prevented, and the present invention has been completed.

Accordingly, an object of the present invention is to provide a novel panel block liquid crystal display device and a driving method thereof which can prevent mutual interference between data line blocks.

1 shows a typical TFT-LCD,

2 illustrates a panel structure of a general panel block liquid crystal display device.

3 illustrates a panel structure of a panel block liquid crystal display device according to the present invention;

4 illustrates a digital data driver used when driving a panel block liquid crystal display device according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110: gate driver 120: data driver

122: video signal 130: pixel configuration cell

132: TFT134: liquid crystal cell

210: analog data driver 220: video controller

230: shift register 240: level shifter

250: output buffer 260: switch array block

B1 ~ BM: Panel Block 310: Data Driver

320: video signal voltage source 330: shift register

340: level shifter 350: output buffer

360: switch array block 370: parasitic capacitance

V [0] to V [N]: Video signal voltage C [1] to C [N × M]: Data line

P [1] to P [N × M]: Pixel 410: Sampling latch

420: holding latch 430: D / A converter

440: output buffer 450: 1 channel memory

Ch [0] ~ Ch [N]: Digital video signal channel

According to an embodiment of the present invention, a data driver includes an N × M data line divided into M blocks of N data lines, and an image signal voltage supply source for sequentially applying an image signal voltage to each of the M data line blocks in block units. A panel block liquid crystal display device comprising:

The image signal voltage source further includes at least one compensation output channel in addition to the N output channels for applying the image signal voltage for each of the N data lines of each data line block.

The additionally included compensation output channel is connected to a data line existing at a boundary of each data line block through a switch.

In the LCD, the compensation output channel is one, and the data line existing at the boundary of each data line block is preferably the last data line of each data line block.

In this case, when the video signal voltage source applies the video signal voltage to the k-th (where k is an integer greater than or equal to 2 and less than or equal to M) data line blocks of the M data line blocks, the k-th data line A switch connecting the last data line of the (k-1) th data line block adjacent to the compensation output channel is turned on to convert the image signal voltage of the compensation output channel to the last of the (k-1) th data line block. To the first data line.

In this case, the image signal voltage of the compensation output channel applied to the last data line of the (k-1) th data line block is the (k-1) th of the M data line blocks. When the image signal voltage is applied to the data line block, the voltage change of the data line may be prevented by being equal to the image signal voltage applied to the last data line of the (k-1) th data line block.

Here, when the data driver is an analog data driver, the video signal voltage supply source means a video controller.

When the analog data driver is used as described above, the video controller includes a memory in which the video controller stores an image signal voltage applied to the last data line of the (k-1) th data line block. When the controller applies an image signal voltage to the k-th data line block, the image signal voltage stored in the memory may be applied to the last data line of the (k-1) th data line block through the compensation output channel. .

In the present invention, when the data driver is a digital data driver, the video signal voltage supply means an output buffer of the digital data driver.

As such, when using a digital data driver, the data driver includes a memory for storing image signal data in which the output buffer has been applied to the last data line of the (k-1) th data line block. When the output buffer applies the image signal voltage to the k-th data line block, the image signal data stored in the memory may be applied to the last data line of the (k-1) th data line block through the compensation output channel. have.

The present invention also provides a video signal voltage supply source in which N × M data lines are divided into M blocks by N data lines, and the video signal voltages are sequentially applied to the M data line blocks in block units. A driving method of a panel block liquid crystal display device provided with a data driver,

The image signal voltage source is adjacent to the k-th data line block when the image signal voltage is applied to the k-th (where k is an integer greater than 2 and less than M) data line blocks of the M data line blocks. A driving method of a panel block liquid crystal display device is characterized by applying an image signal voltage to the last data line of the (k-1) th data line block.

In the method of driving the liquid crystal display device, the image signal voltage applied to the last data line of the (k-1) th data line block is the image signal voltage supply source of the (k−) of the M data line blocks. 1) When the image signal voltage is applied to the th data line block, the voltage change of the data line may be prevented when it is equal to the image signal voltage applied to the last data line of the (k-1) th data line block.

In particular, when the image signal voltage is applied to the k-th data line block, the process of applying the image signal voltage to the last data line of the (k-1) -th data line block may include: 1) storing the image signal voltage applied to the last data line of the (k-1) th data line block in a memory when the image signal voltage is applied to the th data line block, and storing the stored image signal voltage in the memory. and applying to the last data line of the (k-1) th data line block.

By doing this, the same voltage as the image signal voltage applied to the last data line of the (k-1) th data line block may be applied again when the image signal voltage is applied to the k th data line block.

Hereinafter, an embodiment of a panel block liquid crystal display device and a driving method thereof according to the present invention will be described in detail with reference to the drawings. However, the present invention is not limited by the following examples.

3 illustrates a panel structure of a panel block liquid crystal display according to the present invention.

In the panel block liquid crystal display of FIG. 3, the data lines are driven by being divided into M blocks by N data lines, and there are a total of N × M data lines. In addition, the data driver 310 includes an image signal voltage supply source 320 that sequentially applies the image signal voltage to each of the M data line blocks in block units.

The image signal voltage source 320 includes N output channels for applying an image signal voltage for each of the N data lines of each data line block, that is, V [1] to V [N], in addition to one compensation. It further includes an output channel, that is, V [0].

The additionally included compensation output channel V [0] is connected to the last data line (ie C [N], C [2N], ... and C [M) of each data line block via switch block 360. XN], etc.). However, when an image signal voltage is applied to the first data line block B1, since a data line to which V [0] is to be connected does not exist substantially, V [0] is a dummy line C [0]. ).

For example, when the image signal voltage source applies the image signal voltage to the first data line block B1 of the M data line blocks, N output channels of V [1] to V [N] are switched. It is connected to data lines C [1] through C [N] through SW1 [1] through SW1 [N], respectively, to apply an image signal voltage. Since there is no data line to which V [0] is to be connected, V [0] is connected to the dummy line C [0] at this time.

Thereafter, while the switches SW1 [1] to SW1 [N] are turned off, an image signal voltage is applied to the adjacent second data line block B2. At this time, the N output channels of V [1] to V [N] are connected to data lines C [N + 1] to C [2N] through switches SW2 [1] to SW2 [N], respectively, so that an image signal voltage is obtained. Is applied. The image signal voltage of the compensation output channel V [0] is a switch SW2 [0 connecting the last data line C [N] of the first data line block B1 to the compensation output channel V [0]. ]) To the last data line C [N] of the first data line block B1.

At this time, the image signal voltage of the compensation output channel V [0] applied to the last data line C [N] of the first data line block B1 is set so that the image signal voltage supply source 320 is the first signal. When an image signal voltage is applied to the data line block B1, it is the same as the image signal voltage applied to the last data line C [N] thereof. Since the same voltage is applied to the last data line C [N] when the first data line block B1 is driven and when the second data line block B2 is driven, the image by the parasitic coupling capacitance 370. Prevents signal changes

In order to reapply the image signal voltage applied to the C [N] data line of the first data line block B1, the image signal voltage source 320 or the data driver 310 may be applied to the image signal voltage source 320. ) Is provided with a memory (not shown) for storing the image signal voltage applied to the last data line C [N] of the first data line block B1. After the image signal voltage source 320 stores the image signal voltage applied to the last data line C [N] of the first data line block B1, the image signal is stored in the provided memory (not shown). When the voltage source 320 applies the image signal voltage to the second data line block B2, the voltage source 320 stores the image signal voltage stored in the memory (not shown) on the C [N] line of the first data line block B1. Can be authorized.

In FIG. 3, when the data driver 310 is an analog data driver, the image signal voltage supply source 320 refers to a video controller. In addition, when the data driver 310 is a digital data driver, the image signal voltage supply source 320 means an output buffer of the data driver 310.

4 shows an example of a digital data driver used when driving a panel block liquid crystal display device according to the present invention.

Herein, the digital data driver includes a sampling latch 410, a holding latch 420, a D / A converter 430, an output buffer 440, and the like from a video controller. N video signals are supplied through the 4 channels. Among the digital data drivers, the holding latch 420, the D / A converter 430, and the output buffer 440 have N channels (Ch [1]) for applying an image signal voltage to each of the N data lines of each data line block. To Ch [N] or V [1] to V [N]), it further includes one compensation output channel Ch [0] or V [0].

The compensation output channel V [0] additionally included in the output buffer 440 is a data line existing at the boundary of each data line block through a switch (preferably the last data line, that is, C). [N], C [2N], ... and C [M × N], etc.).

The digital data driver also includes a channel memory 450 for storing image signal data Ch [N] of the sampling latch 410, which is applied to the last data line of the (k-1) th data line block. do. The image signal data Ch [N] stored in the channel memory 450 is input to the compensation output channel Ch [0] of the holding latch 420 to be applied to a k-th data line block, thereby outputting the output buffer. When the image signal voltage is applied to the k-th data line block, it is applied to the last data line C [N] of the (k-1) th data line block through the compensation output channel V [0] of the output buffer. can do.

As described above, according to the liquid crystal display and the driving method thereof according to the present invention, it is possible to prevent a change in the video signal due to mutual interference of each video signal at each block boundary, which is a problem when driving the block address. Therefore, since the spacing between pixels can be made narrow, the pixel density can be increased, and the aperture ratio of the pixel and the gray level that can be expressed are also improved. Therefore, a high gray scale can be expressed with a small area, and a panel having a high pixel density can be realized.

Claims (11)

N × M data lines are divided into M blocks by N data lines, and each data line includes a data driver including a video signal voltage supply source for sequentially applying video signal voltages in block units to the M data line blocks. In a panel block liquid crystal display device, The image signal voltage source further includes at least one compensation output channel in addition to the N output channels for applying the image signal voltage for each of the N data lines of each data line block. And the compensation output channel is further connected to a data line existing at a boundary of each data line block through a switch. The liquid crystal display of claim 1, wherein the compensation output channel is one, and a data line existing at a boundary of each data line block is a last data line of each data line block. 3. The method of claim 2, wherein when the video signal voltage supply source applies the video signal voltage to a k-th (where k is an integer of 2 or more and M or less) data line block of the M data line blocks, the k signal is applied. A switch connecting the last data line of the (k-1) th data line block adjacent to the first data line and the compensation output channel is turned on to convert the image signal voltage of the compensation output channel to the (k-1) th data line. And applying to the last data line of the block. 4. The image signal voltage of the compensation output channel applied to the last data line of the (k-1) th data line block, wherein the image signal voltage supply source is the (k-) of the M data line blocks. 1) When the image signal voltage is applied to the th data line block, the liquid crystal display device being the same as the image signal voltage applied to the last data line of the (k-1) th data line block. 5. The liquid crystal display device according to claim 4, wherein the video signal voltage supply source is a video controller, and the data driver is an analog data driver. 6. The video controller of claim 5, wherein the video controller includes a memory in which the video controller stores an image signal voltage applied to the last data line of the (k-1) th data line block. And applying the image signal voltage stored in the memory to the last data line of the (k-1) th data line block through the compensation output channel. 5. The panel block liquid crystal display device according to claim 4, wherein the video signal voltage supply source is an output buffer of the data driver, and the data driver is a digital data driver. 8. The data driver of claim 7, wherein the data driver comprises a memory for storing image signal data in which the output buffer has been applied to the last data line of the (k-1) th data line block. And when the image signal voltage is applied to the block, the image signal data stored in the memory is applied to the last data line of the (k-1) th data line block through the compensation output channel. N × M data lines are divided into M blocks by N data lines, and each data line includes a data driver including a video signal voltage supply source for sequentially applying video signal voltages in block units to the M data line blocks. In the driving method of a panel block liquid crystal display device, The image signal voltage source is adjacent to the k-th data line block when the image signal voltage is applied to the k-th (where k is an integer greater than 2 and less than M) data line blocks of the M data line blocks. and a video signal voltage is applied to the last data line of the (k-1) th data line block. The image signal voltage applied to the last data line of the (k-1) th data line block, wherein the image signal voltage supply source is the (k-1) th data of the M data line blocks. And applying the image signal voltage to the line block, the same as the image signal voltage applied to the last data line of the (k-1) th data line block. The method of claim 10, wherein the applying of the image signal voltage to the last data line of the (k-1) th data line block when the image signal voltage is applied to the k-th data line block comprises: Storing an image signal voltage applied to the last data line of the (k-1) th data line block in a memory when the image signal voltage is applied to the (k-1) th data line block, and the stored image And applying a signal voltage to the last data line of the (k-1) th data line block.