KR100666446B1 - Drive device for LCD - Google Patents

Abstract

The present invention relates to a driving device of a liquid crystal display device capable of supplying a stable voltage irrespective of distortion or voltage drop of an external power supply. The driving device according to the present invention controls a level of a supply power supply voltage applied from the outside of the driving device. Compensation apparatus is provided.

According to the present invention, the driving device can be stably operated, and the occurrence of a block phenomenon that can occur between the driving devices can be suppressed, and the signal line and the power line can be formed together on the glass. This has the advantage of simplifying the process.

Description

Drive device for LCD device

1 is a view for explaining a method of forming a signal line in the glass and the power line is transmitted through the FPC as shown in FIG.

2 is a view showing a state in which a source driving device and a gate driving device are mounted on a glass of a liquid crystal display device;

FIG. 3 is a schematic diagram showing an internal circuit of a source driving device used for column line driving of a liquid crystal display. FIG.

4 is an embodiment of a source drive with an adjustment device in accordance with the present invention.

FIG. 5 is a diagram showing a wiring relationship between a plurality of source driving devices mounted on a glass; FIG.

6 is another embodiment of a source drive device having an adjustment device according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive device for a liquid crystal display device, and more particularly to a drive device for a liquid crystal display device capable of supplying a stable voltage regardless of distortion or voltage drop of an external power supply.

In general, a method of mounting a source driver IC used for column line driving of an active matrix liquid crystal display on glass is to mount a chip on a TCP film and bond the film to the glass. There is a COF method that uses a thinner and transparent film than the film, and a COG method that mounts the chip itself directly on the glass.

In particular, the COG method, in which only the chip is mounted on the glass and a signal line or power line is connected to the FPC, is mainly used. Recently, as shown in FIG. 1, the signal line is formed on the glass and the power line is transmitted through the FPC. The method of making it is used.

Here, the reason why the power line is not formed on the glass is that a large amount of current flows in the power supply terminal, so when the line is formed on the glass, a large wire resistance causes a voltage drop, which causes an abnormal operation of the driving device. This is because a deterioration of screen quality, such as a block, may occur. (For reference, in the related art, signal lines and power lines necessary for a source driving device used for driving a column line of a liquid crystal display are formed on a PCB. In this case, since the PCB's resistance is small, the voltage drop of the power supply line or the delay in the signal line hardly occurs, etc. However, in order to achieve this, there is a continuous demand for light and thin, low cost, and the like of the liquid crystal display. A technology for mounting a driving device (chip) on glass is essential.)

As can be seen from the above, in the conventional case, only the driving chip is mounted on the glass, but the burden of adding another process or FPC for power supply still remains due to voltage drop and damage to screen quality. there was.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above-mentioned problems, and to provide a driving apparatus capable of mounting a power supply line on glass and compensating for a drop in power supply voltage.

In addition, even if the power line is formed on the glass by adding a constituent means for compensating for the voltage drop caused inside the source driving device used for column line driving in the liquid crystal display device, An object of the present invention is to provide a driving device for preventing abnormalities in screen quality.

In addition, in the present invention, a linear regulator function is added to the inside of the driving device to compensate for the voltage drop generated when the power supply line is formed on the glass, so that a constant voltage is always output inside the driving device. It aims to stabilize the operation and not affect the screen quality.

The present invention for achieving the above object is a driving device of a liquid crystal display device mounted on the glass of the panel, and including a shift register, a latch, a digital analog converter and an output buffer, the level of the power supply voltage applied from the outside And adjusting means for supplying the shift register, the latch, the digital analog converter, and the output buffer to an internal supply voltage.

In the present invention, when there are two or more supply power voltages applied from the outside of each drive device, the number of correction devices is also two or more correspondingly.

In the present invention, when the supply power supply voltage applied from the outside of each driving device is one, and the internal supply power supply voltage used in each of the driving devices is two or more, the number of correction devices is correspondingly two or more (1 , 2, .., i-1, i, .. n), in which case the i th correction device uses the output signal of the i th correction device.

In the present invention, the correction device receives the supply power voltage applied from the outside and converts it to an internal supply power supply voltage used inside the driving device.
In addition, the correction means is a first correction means for supplying a first internal power supply voltage to the digital analog converter and the output buffer by adjusting the level by receiving a first supply power voltage applied from the outside, the second applied from the outside And a second correction means for receiving a supply power supply voltage and adjusting a level to supply a first internal supply power supply voltage to the shift register and the latch.
In addition, the correction means is a first correction means for supplying the first power supply voltage supplied to the digital analog converter and the output buffer to the digital analog converter and the output buffer by receiving the supply power voltage applied from the outside, the first internal supply power supply voltage And a second correction means for adjusting the level and supplying the level to the shift register and the latch.
In addition, the correction means is preferably a linear regulator for outputting a constant voltage when a voltage of a predetermined range is applied.

(Example)

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating a state in which a source driving device and a gate driving device are mounted on a glass of a liquid crystal display device. In this case, signal lines and power lines input from the control board to the panel are input through the FPC.

FIG. 3 is a diagram schematically illustrating an internal circuit of a source driving device used for driving a column line of a liquid crystal display. As shown, the source driving device is largely composed of a shift register, a latch, a D / A converter, and an output buffer, and their operation relations are well known to those skilled in the art, and are not related to the subject matter of the present invention. Is omitted.

In general, a signal applied to a driving device used in a liquid crystal display is a data signal, a control signal, and a power line for driving the same. In particular, the type of power source includes a digital power supply VDD2 for driving a driving device and an analog power supply VDD1 for driving a liquid crystal.

As in the conventional method, when the power is applied through the PCB, since the resistance component of the PCB is very small, a voltage drop hardly occurs and thus does not affect the operation of the driving device. However, when the driving device is formed on the glass, the wiring resistance is large. Therefore, a voltage drop occurs and the operation of the driving device becomes unstable.

In this case, in order to restore the original voltage state when the voltage drop occurs, it is necessary to include an adjusting device capable of compensating the inside of the driving device.

4 shows an embodiment of a source drive device having such an adjustment device.

As shown, the drive device according to the present invention is a correction device having a function of converting the external supply power voltage applied from the outside of the drive device to the internal supply power voltage used in the internal configuration means in addition to the conventional configuration means (A, B) is further provided. That is, even when the external digital power supply VDD1 'and the analog power supply VDD2' applied from the outside of the driving device are not suitable as the internal supply power of the driving device due to a voltage drop, the corresponding correcting devices A and B are applicable. Respectively outputs and uses voltages VDD1 and VDD2 suitable for use as internal supply power voltages of the driving apparatus.

The correction device preferably uses a linear regulator that outputs a constant voltage when a voltage of a predetermined range is applied. Here, the range of the input voltage may vary depending on the circuit configuration, the linear regulator is implemented so that it is hardly affected even if the external input power is changed. When a correction device having such a function is used in the driving device of the present invention, the voltage drop caused by the resistance component of the glass can be compensated for to normally operate the driving device and to prevent screen deterioration such as block generation of the screen.

In connection with the operation of FIG. 4, a voltage drop occurs to receive the input VDD1 ′ voltage as an input of the linear regulator B. Then, the linear regulator B outputs a stable voltage VDD1 for operating the driving device.

In addition, a voltage drop occurs to receive the input VDD2 'voltage to the input of the linear regulator (A). Then, the linear regulator A outputs a stable voltage VDD2 for operating the driving device.

The VDD2 voltage is a power supply that operates the logic circuit portion of the source driving device. If a voltage drop occurs, the voltage drop may cause a fatal malfunction because the logic circuit itself does not operate.

Next, the VDD1 voltage is a power source used in the D / A converter, and if the voltage drop occurs, the driving device may be damaged, and it may cause the deformation of the Gamma reference voltage, causing block between source driving devices. It causes the deterioration.

5 is a diagram showing a wiring relationship between a plurality of source driving devices mounted on a glass.

In the drawing, the structure of each source driving device is the same as that of FIG. 4, but the supply power voltage applied to each driving device may be different due to a voltage drop during transmission. That is, as clearly seen in FIG. 5, VDD1 'and VDD2', which are external supply power voltages applied to the Nth source driving device, and VDD1 '' and VDD2 ', which are external supply power voltages applied to the N + 1th source driving device, are provided. May differ from each other due to the voltage drop on the wiring, but the voltages used through the linear regulator will be stable voltages VDD1 and VDD2. Here, preferably, the external supply power supply voltages VDD1 ', VDD2', VDD1 ", and VDD2 " need to be greater than or equal to the internal supply power supply voltages VDD1 and VDD2.

6 shows another embodiment of a source drive with an adjustment device.

The difference from the embodiment of FIG. 4 is that when there is one supply power supply voltage applied from the outside of the driving device and two internal supply power supply voltages used in the driving device (or the same applies to more than that), correction is performed. The number of devices is correspondingly two (corresponding to the number of internal supply power supply voltages), in which case the second correction device uses the output signal of the first correction device.

That is, when the internal supply power supply voltage used in the driving device is the voltage of VDD2 voltage for driving the logic circuit of the driving device and VDD1 which is the voltage for driving the liquid crystal, the external supply power supply voltage VDD is input through the linear regulator B. An internal supply power supply voltage VDD1 is generated and an internal supply power supply voltage VDD1 is applied to the linear regulator A to generate another internal supply power supply voltage VDD2. Here, it is preferable that the external supply power supply voltage VDD is greater than or equal to the internal supply power supply voltage VDD1.

Although the present invention has been described mainly with respect to the source driving device, the same may be applied to the gate driving device.

As described above, it can be seen that stable operation is possible by installing a compensation device inside each driving device to compensate for the voltage drop of the power supply which may occur when the source and gate driving devices are mounted on the glass.

In addition, it is possible to suppress the occurrence of a block phenomenon that can occur between the driving devices, thereby ensuring the reliability of the product.

Finally, since the signal line and the power line can be formed together on the glass, the process is simplified.

Claims (7)

A drive device for a liquid crystal display mounted on a glass of a panel and including a shift register, a latch, a digital analog converter and an output buffer: And correction means for controlling a level of a supply power voltage applied from the outside to supply the shift register, the latch, the digital analog converter, and the output buffer as an internal supply power voltage. Driving device of liquid crystal display device. The method of claim 1, When the supply power voltage applied from the outside is two or more, the number of the correction means is correspondingly two or more. Driving device of liquid crystal display device. The method of claim 1, When the supply power voltage applied from the outside is one and the internal supply power voltage is two or more, The number of the correction means is also two or more (1, 2, ..., i-1, i, ... n) correspondingly, in which case the i th correction means is an output signal of the i-1 th correction means. Using Driving device of liquid crystal display device. The method according to any one of claims 1 to 3, And the correction means receives the supply power supply voltage applied from the outside and converts the supply power supply voltage into an internal supply power supply voltage used inside the driving device. The method of claim 1, wherein the correction means First correction means for receiving a first supply power voltage applied from the outside and adjusting a level to supply the first analog power supply voltage to the digital analog converter and the output buffer as a first internal supply power voltage; A second correction means for receiving a second supply power voltage applied from the outside to adjust a level to supply the shift register and the latch to a first internal supply power voltage; Driving device of liquid crystal display device. The method of claim 1, wherein the correction means First correction means for receiving the supply power voltage applied from the outside and adjusting a level to supply the first analog power supply voltage to the digital analog converter and the output buffer; And a second correction means for receiving the first internal supply power supply voltage and adjusting a level to supply the shift register and the latch to the shift register and the latch. Driving device of liquid crystal display device. The method according to claim 5 or 6, The correction means is a linear regulator for outputting a constant voltage when a voltage of a predetermined range is applied Driving device of liquid crystal display device.

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