KR100223861B1 - Crosstalk compensation device of liquid crystal display element - Google Patents

Abstract

The present invention relates to a liquid crystal display device, and to provide a crosstalk compensation device having a simple circuit configuration by compensating for an error by comparing a common voltage signal applied to a common voltage signal applied inside an actual panel. In as due to the difference of the crosstalk compensation apparatus is V _COM signal and the V _COM signal of the internal TFT-LCD panel is the liquid crystal display element for this compensation of crosstalk generated, and V _COM generating unit for generating a V _COM signal A buffer unit for amplifying an output signal of the V _COM generating unit and preventing feedback of a distorted signal generated inside the TFT-LCD panel, a V _COM signal applied to the TFT-LCD panel and the V _COM generating unit The voltage detection unit continuously detects the difference in the output signal and generates a voltage corresponding to the difference, and the voltage detection unit continuously adds the output of the voltage detection unit and the V _COM signal applied to the TFT-LCD panel for continuous voltage compensation. And a voltage adder configured to output a compensated V _COM signal.

Description

Crosstalk Compensation Device for Liquid Crystal Display Devices

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device. In particular, the present invention compares a common electrode voltage to be applied with a common electrode voltage applied to an actual panel, and compensates for the error. A crosstalk compensator for a liquid crystal display device is provided.

In general, crosstalk is divided into horizontal crosstalk and vertical crosstalk. Horizontal crosstalk is caused by capacitor coupling between the common electrode and the source electrode, and vertical crosstalk is caused by the electrostatic discharge between the source electrode and the drain electrode. The dose is the cause.

Hereinafter, a crosstalk compensator for a conventional liquid crystal display will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a crosstalk compensator of a conventional liquid crystal display device.

The conventional crosstalk compensator of a liquid crystal display device integrates a current detector 11 that detects a current applied to a common electrode and converts it into a voltage, and integrates an output signal of the current detector 11 and compensates for a distorted signal. The switch control unit 13 adjusting the time for the sum, and the Ether unit 15 for adding the signal output from the switch control unit 13 and the signal applied to the common common electrode and output the summed signal to the common electrode. It is configured to include).

The current detector 11 includes an amplifier 11a that detects a current value and amplifies it to a predetermined width, and a current / voltage converter 11b that replaces the amplified current value with a voltage value.

In addition, the switch controller 13 may include a first switch 13a for selectively switching a voltage that is converted into a voltage by the current detector 11 and output, and a voltage applied when the first switch 13a is turned on. A capacitor 13b for charging a battery; a second switch 13c selectively switched to discharge a charged voltage when the capacitor 13b is fully charged; and a turn of the second switch 13c. And a third switch 13d which is selectively switched to transfer the voltage discharged in accordance with the ON to the Ether section 15.

And the ether unit 15 is composed of a voltage adjusting unit 15a for outputting a suitable voltage to the ether unit 15 by adjusting the amount of voltage output from the switch control unit 13.

The operation of the crosstalk compensator of the conventional liquid crystal display device configured as described above will be described with reference to FIGS. 1 and 2.

2 is a signal timing diagram according to a crosstalk compensator of a conventional liquid crystal display device.

First, as shown in FIG. 1, R _SCN of the current detector 11 detects a current input to the common electrode terminal.

Since the magnitude of the current detected by the R _SCN is weak, it is amplified to a certain size through the first OP amplifier 12a.

The current amplified by the first 0P amplifier 12a is converted into a voltage value by the resistors connected to the second 0P amplifier 12b and its input terminal.

After that, when the first switch 13a is turned on, the voltage output from the current detector 11 is charged in the capacitor 13b.

At this time, the first switch 13a maintains an off state while detecting a current input from the current detector 11 to the common electrode terminal, and then turns on when the current detection is completed.

In addition, as another condition for layering the voltage on the capacitor 13b, the second switch 13c and the third switch 13d should be kept off.

Here, the waveform of FIG. 2B illustrates a waveform applied to the common electrode, and the waveform of FIG. 2C shows a common waveform having a compensation time of a distorted signal for a predetermined time after detecting a current input to the common electrode terminal as described above. The waveform of the electrode is shown

That is, the waveform of FIG. 2B shows a waveform when the third switch 13d is turned off and FIG. 2C shows a waveform when the third switch 13d is turned on.

Subsequently, when lamination of the capacitor 13b is completed, the second switch 13c and the third switch 13d are turned on, and the capacitor 13b is provided through the second and third switches 13c and 13d. ) Is applied to the voltage adjusting unit 15a.

The voltage adjusting unit 15a adjusts an appropriate voltage to be sent to the ether unit 15 from the input voltage and outputs the voltage to one terminal of the ether unit 15.

Therefore, the ether unit 15 adds the common signal and the signal output from the voltage adjusting unit 15a and outputs the common signal to the common electrode terminal.

FIG. 2D illustrates a waveform in which the distorted signal is compensated and finally applied to the common electrode terminal.

However, the crosstalk compensator of the conventional liquid crystal display device as described above has the following problems.

First, the distortion of V _COM caused by the RC delay generated between the black matrix and the common electrode cannot be compensated.

Secondly, a separate sampling clock is required, which complicates the circuit configuration and does not compensate for distortion other than that generated at the moment of sampling.

The present invention has been made to solve the above problems, and provides a crosstalk compensation device having a simple circuit configuration since distortion is compensated by directly comparing a common electrode voltage to be applied with a common electrode voltage applied to an actual panel. There is a purpose.

1 is a circuit configuration diagram of a crosstalk compensator of a conventional liquid crystal display device.

2A to 2D are signal timing diagrams according to a crosstalk compensator of a conventional liquid crystal display device.

3 is a block diagram of a crosstalk compensator of a liquid crystal display of the present invention;

4 is a detailed circuit diagram of FIG.

5 is a view comparing the normal V _COM signal and the V _COM signal in the case of severe distortion

6 is a view comparing the normal V _COM signal and the V _COM signal when the distortion is not severe

7 is a view comparing a normal V _COM signal with a V _COM signal when distortion is compensated using the crosstalk compensator of the present invention.

* Explanation of symbols for main parts of the drawings

31: V _COM generating section 32: buffer section

33: voltage detector 34: voltage-adder

According as the cross-SAT compensation him is generated by the difference of V _COM signal and the V _COM signal of the internal TFT-LCD panel that crosstalk compensation apparatus of a liquid crystal display device of the present invention for achieving the above object it is applied, V _COM signal and V _COM generating unit for generating, and a buffer unit which amplifies the output signal of the V _COM occurs, and avoid feedback of the distortion signal generated in the inside of the TFT-LCD panel, V being applied to the TFT-LCD panel A voltage detector for continuously detecting a difference between a _COM signal and an output signal of the V _COM generator and generating a voltage corresponding to the difference, and a V _COM signal applied to the output of the voltage detector and the TFT-LCD panel. And the voltage is added to the voltage outputting the compensated V _COM signal by continuous voltage compensation.

Hereinafter, a crosstalk compensator of the present invention will be described with reference to the accompanying drawings.

3 is a block diagram illustrating a crosstalk compensator of a liquid crystal display of the present invention, and FIG. 4 is a detailed circuit diagram of FIG. 3.

First, V _COM generator 31 for generating the V _COM signal as shown in Fig. 3, and the V _COM distortion signals in the amplifier the output signal of the V _COM generator 31 current, and the panel and the V _The buffer unit 32, which blocks feedback from the _COM generator 31, and the V _COM signal inside the panel and the output signal of the V _COM generator 31 are compared with each other to obtain a voltage corresponding to the difference. Subsequently, the voltage detector 33, the voltage detector 33, and the output signal of the voltage detector 33 and the V _COM signal inside the panel are continuously summed to output the final V _COM signal compensated for. It is configured to include.

Here, the voltage detector 33 and the voltage ether unit 34 are constituted by a 0P amplifier.

The operation of the crosstalk compensator of the present invention configured as described above will be described with reference to FIGS. 3 and 4.

First, when the V _COM signal is generated by the V _COM generator 31, the V _COM generator 31 is applied into the panel while passing through the buffer unit 32.

At this time, the signal applied to the panel is simultaneously input to one terminal of the voltage detector 33, and the other terminal of the voltage detector 33 is input to the output signal of the V _COM generator 31.

Accordingly, the voltage detector 33 compares the output signal of the V _COM generator 31 and the signal applied to the panel (that is, the signal output from the buffer unit 32) to compare the voltage corresponding to the difference. Occurs.

For example, when the output voltage of the V _COM generator 31 is 5V and is applied inside the panel and the distorted voltage is 3V, the output voltage of the voltage detector 33 becomes -2V.

That is, as shown in Fig. 4, the voltage across the positive input terminal of the voltage detector 33 is 1.5V.

This means that since the resistors R ₁ and R ₂ have the same value, the voltage applied to the positive input terminal by the voltage division becomes 1.5V due to voltage division.

Therefore, the same voltage as the positive input terminal is applied to the negative input terminal of the voltage detector 33.

As a result, the output voltage of the voltage detector 33 becomes -2V.

Here, -2V means that the difference between the output signal of the V _COM generator 31 and the V _COM signal applied to the panel is 2V.

The voltage detector 33 outputs a negative voltage when the output voltage of the V _COM generator 31 is greater than the voltage applied to the panel, and conversely, an output voltage of the V _COM generator 31 is applied to the panel. If the voltage is less than the applied voltage, a positive voltage is output.

The output voltage (-2V) of the voltage detector 33 obtained through the above process is applied to the negative input terminal of the voltage adder 34 as shown in FIG.

In addition, a V _COM signal (3V) applied to the inside of the panel is input to the positive input terminal of the voltage adder 34.

Since the resistors R ₃ and R ₄ of the (+) input terminal have the same value, 1.5 V is applied to the (+) input terminal by voltage distribution.

Therefore, the same voltage (1.5V) as that of the (+) input terminal is applied to the (−) input terminal of the voltage adder 34.

As a result, since the output voltage of the voltage detector 33 is -2V and the voltage of the negative input terminal of the voltage adder 34 is 1.5V, the current flowing through the resistor R ₅ therebetween is to be .

Therefore, the resistance R ₆ between the negative input terminal of the voltage ether unit 34 and the output terminal of the voltage ether unit 34 is The voltage of is induced.

Therefore, a voltage of 5 V (1.5 V + 3.5 V) is induced between the negative input terminal of the voltage adder 34 and the output terminal of the voltage adder 34.

As a result, the voltage applied to the panel is initially compensated to 5V through the above process from 3V.

Meanwhile, FIG. 5 illustrates waveforms of a V _COM signal when severe distortion occurs compared to a normally applied V _COM signal, and FIG. 6 illustrates a case where distortion is not severe.

7 illustrates waveforms of a V _COM signal when distortion is compensated for using the crosstalk compensator of the present invention.

As shown in FIG. 7, unlike the waveforms shown in FIGS. 5 and 6, the crosstalk compensator of the present invention can obtain a signal almost without distortion as compared to a signal (square wave) normally applied.

As described above, the crosstalk compensator of the liquid crystal display device of the present invention has the following effects.

First, the V _COM signal is compensated analog immediately, reducing the time it takes to compensate.

Second, the circuit configuration for compensation is simple.

Claims (3)

In applying that V _COM signal and the TFT-LCD panel inside the compensation of crosstalk caused by the difference of V _COM signals, and V _COM generating unit for generating a V _COM signal, and amplifying the V _COM generating unit output signal The difference between the buffer unit for preventing feedback of the distorted signal generated inside the TFT-LCD panel and the output signal of the V _COM signal applied to the TFT-LCD panel and the output signal of the V _COM generation unit is continuously detected. And a voltage detector for generating a corresponding voltage, and a voltage detector for outputting the voltage detector and the voltage applied to the TFT-LCD panel and continuously summed to continuously compensate the voltage to output the compensated V _COM signal. A crosstalk compensating device for a liquid crystal display device. The crosstalk compensation device of claim 1, wherein the buffer unit receives an output of the V _COM generating unit and amplifies the current. The crosstalk compensating device of a liquid crystal display device as claimed in claim 1, wherein the voltage detector and the voltage adder are configured by a 0P amplifier.