KR20050122099A - Liquid crystal display - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to a liquid crystal display device which improves a poor image quality caused by a distortion input of a common voltage.

Such a liquid crystal display device includes: a common voltage generator for outputting a common voltage; A common electrode is formed, a first common voltage input terminal electrically connected to the common electrode and inputting the common voltage, and a second common voltage input terminal receiving a common voltage from the first common voltage input terminal and applying the common voltage to the common electrode. A liquid crystal panel having a; Comprising a compensation voltage output unit for applying the first and second compensation voltage to the first and second common voltage input terminal, respectively, due to the residual ripple voltage component included in the common voltage applied to the large-area liquid crystal display device There is an advantage of offsetting the effect to achieve the best image quality.

Description

Liquid crystal display

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to a liquid crystal display device which improves a poor image quality caused by a distortion input of a common voltage.

A TFT-LCD is a display device that obtains a desired image signal by applying an electric field to a liquid crystal material having an anisotropic dielectric constant injected between two substrates, and controlling the amount of light transmitted through the substrate by adjusting the intensity of the electric field.

On the substrate of such a TFT-LCD, a plurality of gate lines parallel to each other and a plurality of data lines insulated from and intersecting the gate lines are formed, and an area surrounded by the gate lines and the data lines defines one pixel. TFTs are formed at portions where the gate lines and the data lines of each pixel cross each other.

In order to drive such a TFT-LCD, the gate line is sequentially driven and at the same time, a data voltage to be applied to the source terminal of the TFT connected to the driving gate line is applied through the data line. At this time, the polarity of the data voltage is inverted with respect to the common voltage every frame in order to prevent deterioration of the liquid crystal generated as the electric field in the direction is continuously applied to the pixels formed in the TFT. The TFT-LCD driving method for inverting the polarity of the data voltage is called an inversion driving method.

FIG. 1 is a diagram illustrating a conventional active matrix liquid crystal display device, in which a liquid crystal cell is arranged in a matrix form between two transparent substrates, and gate lines GL1 of the liquid crystal panel 2. Gamma voltage generator 8 connected to gate driver 6 connected to GLm), data driver 4 connected to data lines DL1 to DLn of liquid crystal panel 2, and data driver 4; ). The gamma voltage generator 8 is usually included in the data driver 4.

In such a liquid crystal display, a liquid crystal panel is formed by forming a thin film transistor (TFT) array and a pixel electrode on a first substrate, a color filter and a common electrode on a separate second substrate, and then joining two substrates together. 2 is an exploded perspective view illustrating a general configuration of such a liquid crystal display panel.

As shown, the liquid crystal display panel 2 is composed of two transparent substrates 15 and 17 with the liquid crystal 13 interposed therebetween, and the first substrate 15 of the liquid crystal panel 2 has a color. The filter 21 and the common electrode 19 are stacked, and the second substrate 17 bonded to the first substrate 15 at a predetermined interval is configured to correspond to the plurality of pixels P and each pixel. The thin film transistor T, which is a switching element, is formed. In addition, a gate line 29 and a data line 31 connected to a gate electrode (not shown) and a source electrode (not shown) constituting the thin film transistor are formed to cross each other.

An upper polarizer 23 and a lower polarizer 25 are formed on each outer surface of the first substrate 15 and the second substrate 17.

Here, the common voltage applied to the common electrode 19 is supplied through a conductive contact (dot) formed at one or more positions on the liquid crystal panel from a power supply device (not shown).

In the general structure as described above, the common electrode formed on the liquid crystal panel is applied to the common electrode 19 through the conductive first contact point 50 formed in the liquid crystal panel as shown in FIG. 3. The common voltage and the common voltage at the second contact 60 which are reapplied to another area of the panel through the gate drive 6 having the common voltage extension line 20 formed at the first contact 50 are different from each other. What happens?

In the case of the large screen panel, the common voltage applied to the first contact point 50, which is the first application point of the common voltage, is connected to the other contact point of the panel through the gate driver 6 or a separately configured common voltage line. The ripple voltage component is included while extending to the contact point 60 and applied to the common electrode 19 inside the panel, thereby distorting the common voltage applied to the common electrode 19. This is mainly caused by the internal resistance and capacitance components of the common voltage extension line 20 that transmits the common voltage to other contacts. As such, the difference in the common voltage input between the upper and lower ends of the panel or between the left and right ends of the panel is entirely different. This results in an imbalance in image quality.

FIG. 4 is a graph illustrating a ripple voltage component included in a common voltage according to a common voltage application position in the panel illustrated in FIG. 3.

In the graph shown, the ripple components of the common voltage applied to the first contact point 50 are represented by (A +) and (A−), and the ripple components of the common voltage reapplied to the second contact point 60 are ( It is denoted by B +) (B-). Positive and negative signs indicate that the component is increasing or decreasing based on the rated common voltage (Vcom).

As can be seen from the magnitude of the ripple voltage through the graph, the magnitude of the ripple voltage included in the common voltage applied to the first contact point 50 and the magnitude of the ripple voltage included in the common voltage at the second contact point 60 are It can be seen that it is very large compared to the ripple component at the first contact point 50, which is more affected by the wiring at the second contact point 60 receiving the common voltage through the common voltage extension line 20. Because.

This ripple component is converted into a root mean square (RMS) value for the rated common voltage and is included in the common voltage, causing a common voltage to be distorted.

As such, the unevenness of the common voltage due to the ripple voltage difference between the upper, lower, or left and right portions of the liquid crystal panel is more prominent in a large area liquid crystal display device. This results in a non-uniform representation of the image across the entire panel.

The present invention has been made to solve the above problems, and an object of the present invention is to compensate for the difference in common voltages input through multiple points of the liquid crystal panel to express uniform image quality in the entire panel.

To this end, an object of the present invention is to provide a liquid crystal display device which uniformly expresses image quality in the entire panel by canceling the DC ripple voltage included in each common voltage input to the common electrode at a plurality of points of the liquid crystal panel.

In order to achieve the above object, a common voltage generator for outputting a common voltage; A common electrode is formed, a first common voltage input terminal electrically connected to the common electrode and inputting the common voltage, and a second common voltage input terminal receiving a common voltage from the first common voltage input terminal and applying the common voltage to the common electrode. A liquid crystal panel having a; A liquid crystal display device comprising a compensation voltage output unit configured to apply first and second compensation voltages to the first and second common voltage input terminals, respectively.

The liquid crystal display according to the present invention may include at least one gate driver configured to output a scan signal to the liquid crystal panel; And at least one data driver for outputting video data to the liquid crystal panel according to the scan signal.

The compensation voltage output unit may be configured in one of the gate driver and the data driver.

The first and second compensation voltages have an absolute value equal to the RMS average value of the ripple voltage included in the common voltage applied to the first and second common voltage input terminals, respectively.

The first and second compensation voltages have a polarity that cancels the difference between the RMS average value of the ripple voltage included in each common voltage applied to the first and second common voltage input terminals and the common voltage.

The liquid crystal panel is characterized by having two or more common voltage input terminal.

Hereinafter, a liquid crystal display according to the present invention will be described with reference to the accompanying drawings.

5 is a diagram illustrating a configuration of a liquid crystal display according to the present invention.

In the configuration, the liquid crystal panel 110 having the common electrode 102 formed thereon, the gate driver 120 outputting the scan signal to the liquid crystal panel 110, and the data outputting video data to the liquid crystal panel 110. Driver 130 is configured. Each of the drivers 120 and 130 is one or more, and each of the drivers 120 and 130 may be configured as a tape carrier package (TCP) to the liquid crystal panel 110 to transmit a signal.

The liquid crystal panel 110 includes first and second common voltage input terminals 142 and 144 for inputting a common voltage to the common electrode 102. Each common voltage input terminal 142 or 144 may be a conductive contact, and may be configured inside the gate driver 120 or the data driver 130 to extend to the common electrode 102 of the liquid crystal panel 110. have.

The common voltage input to the first common voltage input terminal 142 is retransmitted to the second common voltage input terminal 146 through a separate common voltage extension line 146. In this case, the common voltage extension line 146 may be formed in the liquid crystal panel 110 or may be configured using the gate driver 120 or the data driver 130 as shown.

The common voltage generator 150 generates a rated common voltage Vcom to be used for driving the liquid crystal panel 110, and the generated rated common voltage Vcom is output to the first common voltage input terminal 142.

The compensation voltage output unit 160 generates and outputs separate compensation voltages to be input to the first and second common voltage input terminals 142 and 144, respectively. The compensation voltage includes a first compensation voltage Vcom1 to be input to the first common voltage input terminal 142 and a second compensation voltage Vcom2 to be input to the second common voltage input terminal 144. Each of the output compensation voltages is of a fixed size, and is set in advance when the LCD is manufactured to be output.

The compensation voltage output unit 160 may be configured in a driving circuit unit (not shown) of the liquid crystal display, and may be included in the gate driver 120 or the data driver 130.

Here, a method of determining the respective compensation voltages Vcom1 and Vcom2 output through the compensation voltage output unit 160 will be described using the first compensation voltage Vcom1 as an example.

 First, as shown in FIG. 6, the common voltage Vcom output from the common voltage generator 150 is measured by measuring the common voltage at the first common voltage input terminal 142 to which the first compensation voltage Vcom1 is applied. The ripple voltage (A +) (A-) included in the signal is detected.

The ripple voltage may be caused by various factors, and is mainly caused by the internal resistance of the wiring and the capacitance component, causing a shift of the common voltage.

Then, the root mean square value RMS of the detected ripple voltage is obtained, and the shifted voltage VS1 as much as the shifted voltage from the rated common voltage Vcom is obtained through comparison with the rated common voltage Vcom. The reason for calculating the root mean square RMS of the ripple voltage is that the ripple voltage characteristic has a waveform characteristic in which the rising and falling forms are repeated based on the rated common voltage Vcom.

Finally, the compensation voltage output unit 160 has the same absolute value as the shift voltage VS1 in order to compensate for the common voltage shifted by the shift voltage VS1 generated by the ripple component. Output the compensating voltage Vcom1 of the polarity capable of moving the output graph back to the rated common voltage Vcom, that is, canceling the influence of the shift voltage due to the ripple voltage, to the first common voltage input terminal 142. do.

Accordingly, the total voltage input from the first common electrode input terminal 142 to the common electrode 102 by the first compensation voltage Vcom1 eventually has a rated common voltage Vcom value.

Hereinafter, the common voltage compensation at the second common electrode input terminal 144 is also performed in the same manner so that the second compensation voltage Vcom2 is input through the compensation voltage output unit 160.

In the above-described example, the common voltage compensation method for the two points of the first and second common voltage input terminals 142 and 144 has been described. However, in a large-area display device, a plurality of common voltage input terminals may be further configured and input as required. The compensation voltage input of the common voltage may be performed.

The liquid crystal display according to the present invention as described above has the advantage of realizing the best image quality by canceling the influence of the ripple voltage component included in the application of the common voltage of the large-area liquid crystal display device.

1 is a view showing a conventional active matrix liquid crystal display device

2 is an exploded perspective view showing the configuration of a conventional liquid crystal display panel;

3 illustrates a common voltage input to a common electrode formed in a conventional liquid crystal panel.

4 is a graph illustrating the ripple voltage components included in accordance with the common voltage application position of the liquid crystal panel shown in FIG.

5 is a diagram illustrating a configuration of a liquid crystal display device according to the present invention.

6 is a graph illustrating a common voltage compensation method by a liquid crystal display according to the present invention.

<Brief description of the main parts of the drawing>

102: common electrode 110: liquid crystal panel

120: gate driver 130: data driver

142: first common voltage input terminal 144: second common voltage input terminal

146: common voltage extension line 150: common voltage generator

160: compensation voltage output unit

Claims (6)

A common voltage generator for outputting a common voltage; A common electrode is formed, a first common voltage input terminal electrically connected to the common electrode and inputting the common voltage, and a second common voltage input terminal receiving a common voltage from the first common voltage input terminal and applying the common voltage to the common electrode. A liquid crystal panel having a; Compensation voltage output unit applying first and second compensation voltages to the first and second common voltage input terminals, respectively. Liquid crystal display comprising a The method according to claim 1, At least one gate driver configured to output a scan signal to the liquid crystal panel; At least one data driver to output video data to the liquid crystal panel according to the scan signal Liquid crystal display further comprising The method according to claim 1 or 2, And the compensation voltage output unit is configured in one of the gate driver and the data driver. The method according to claim 1, The first and second compensation voltages are voltages having an absolute value equal to the RMS average value of the ripple voltages included in each common voltage applied to the first and second common voltage input terminals. The method according to claim 4, The first and second compensation voltages have a polarity that cancels the difference between the RMS average value of the ripple voltage included in each common voltage applied to the first and second common voltage input terminals and the common voltage. Display The method according to claim 1, The liquid crystal panel includes two or more common voltage input terminals.