KR101030539B1 - The liquid crystal display device - Google Patents

Abstract

The present invention relates to a liquid crystal display device that can reduce the electromagnetic interference of the overdriving drive unit, LVDS receiver for converting the LVDS type image signal input from an external system into a TTL image signal and outputs; A frequency converter for reducing and outputting a frequency of the TTL image signal output from the LVDS receiver; And an overdriving driver for receiving and overdriving the TTL image signal outputted from the frequency converter.

Liquid Crystal Display, Electromagnetic Interference (EMI), LVDS, TTL, Spread IC

Description

Liquid crystal display device

1 is a block diagram of a liquid crystal display device using a conventional spread IC.

2 is a block diagram of a liquid crystal display according to an exemplary embodiment of the present invention.

3 is a block diagram of the frequency converter of FIG.

* Explanation of symbols on the main parts of the drawings

110: system 120: LVDS receiver

130: frequency conversion unit 140: overdriving driving unit

140a: overdriving controller 140b: second memory

150: data drive IC

The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device capable of reducing electromagnetic interference (EMI) in an overdriving driver.

Recently, flat panel display devices have been developed to have high frequency and high resolution in order to realize a more satisfactory screen.

As a flat panel display device, a liquid crystal display device may be described as a representative example. A liquid crystal display device having an XGA level or more is difficult to implement high resolution due to EMI problem, noise problem through transmission medium, and limitation of data transmission number.

In the conventional liquid crystal display, data is transmitted at the TTL level, and in such an environment, an EMI problem occurs because the image signal has a high frequency and the voltage level is changed at the corresponding frequency.

In addition, a method of transmitting data or clock signals at the TTL level requires a large number of transmission lines. The greater the number of cables or connectors, the greater the probability of exposure to an external noise source. Therefore, when a transmission medium such as a cable or a connector is exposed to a noise source, noise affects normal data and a clock signal, thereby adversely affecting an abnormally formed screen.

In addition, the number of data transmission bits supported by a graphics controller commonly used to implement full color high resolution is limited. Therefore, it is not easy to implement a high resolution having more than 260,000 colors using a bi-division driving method that actually uses two channels.

Therefore, in order to solve such a problem, a technique for reducing EMI of the TTL type image signal using a spread IC has been developed.

Hereinafter, a liquid crystal display using a conventional spread IC will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a liquid crystal display device using a conventional spread IC.

As shown in FIG. 1, a liquid crystal display using a conventional spread IC includes an LVDS receiver 20 for converting an LVDS method image signal transmitted from an external system 10 into a TTL method and outputting the TDS method. An overdrive driver 30 that receives the TTL image signal output from the receiver 20 and overdrives the output signal, and a clock signal CLK for synchronizing the TTL image signal from the overdrive driver 30. A spread IC (50) for receiving and spreading the data; and storing the overdriven TTL image signal, and receiving the spread clock signal (CLK`) and spreading the stored TTL image signal. The first memory unit 40 outputs in synchronization with the clock signal CLK`, and the TTL-type image signal outputted from the first memory unit 40 is timing-formatted and outputted. Received from the controller 70 and the timing controller 70 inputs the image signal of the TTL scheme is configured to include a data drive IC (60) for driving the liquid crystal panel.

Here, the overdriving driver 30 reads the data of the second memory unit 30b and the second memory unit 30b in which data for overdriving is stored, and is input from the LVDS receiving unit 20. And an overdriving controller 30a for overdriving and outputting the image signal based on the data.

Referring to the operation of the conventional liquid crystal display device configured as described above in detail as follows.

First, the LVDS receiver 20 converts an LVDS type image signal input from the external system 10 into a TTL type image signal and outputs the converted TTL type image signal. The LVDS receiver 20 outputs the overdriving driver 30 ) Is input to the overdriving controller 30a. Thereafter, the overdriving controller 30a reads the data from the second memory unit 30b, and overdrives the output TTL image signal based on the data.

Next, the TTL image signal output from the overdriving controller 30a is stored in the first memory unit 40. At this time, the clock signal CLK of the TTL-type image signal is input from the overdriving controller 30a to the spread IC 50. The spread IC 50 spreads and outputs the clock signal CLK, and the spread clock signal CLK` is input to the first memory unit 40 in which the TTL image signal is stored. In this case, the first memory unit 40 outputs the TTL image signal in synchronization with the spread clock signal CLK`. The TTL image signal outputted in synchronization with the spread clock signal CLK` is reduced in frequency. Therefore, EMI of the TTL image signal output from the first memory unit 40 is reduced.

On the other hand, since the TTL type image signal input to the overdriving driver 30 formed at the front end of the first memory unit 40 still has a high frequency, the problem due to the EMI still remains.

The present invention has been made to solve the above problems, by providing a frequency conversion unit between the LVDS receiver and the overdriving driver to reduce the frequency of the image signal input from the LVDS receiver to the overdriving driver, the over It is an object of the present invention to provide a liquid crystal display device which can minimize the occurrence of EMI in the driving driver.

According to an aspect of the present invention, there is provided a liquid crystal display device comprising: an LVDS receiver configured to convert an LVDS image signal input from an external system into a TTL image signal and output the converted signal; A frequency converter for reducing and outputting a frequency of the TTL image signal output from the LVDS receiver; And an overdriving driver for receiving and overdriving the TTL image signal outputted from the frequency converter.

Hereinafter, a liquid crystal display according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a liquid crystal display according to an exemplary embodiment of the present invention, and FIG. 3 is a block diagram of a frequency converter of FIG.

As shown in FIG. 2, the liquid crystal display according to an exemplary embodiment of the present invention includes an LVDS receiver 120 for converting an LVDS method image signal transmitted from an external system 110 into a TTL method and outputting the TDS method. A frequency converter 130 that receives the TTL image signal output from the receiver 120 and expands the frequency so as to decrease the frequency thereof, and a TTL image signal output from the frequency converter 130; And an overdriving driver 140 for receiving and overdriving the output signal, a timing controller 170 for timing-formatting and outputting a TTL image signal output from the overdriving driver 140, and the timing controller 170. And a data drive IC 150 that receives a TTL-formatted image signal of a timing format and drives the liquid crystal panel.

Here, as shown in FIG. 3, the frequency converter 130 includes a spread IC 130b for receiving and spreading a clock signal CLK for synchronizing the TTL image signal, and outputting the spread signal. A first memory unit 130a for storing a driven TTL image signal and receiving the spread clock signal CLK` and outputting the stored image signal in synchronization with the spread clock signal CLK`; It is configured to include. Here, the first memory unit 130a is embedded in the timing controller 170, and the spread IC 130b is provided outside the timing controller 170.

The spread IC 130b of the frequency converter 130 spreads the clock signal CLK by applying a spread spectrum method, and spreads the TTL image signal by the spread clock signal ( By outputting in synchronism with CLK`), the frequency band of the TTL system image signal can be widened to spread the frequency. Ultimately, the frequency converter 130 serves to prevent a phenomenon in which data of the TTL type image signal is concentrated at a specific frequency band and exceeds an EMI standard.

The overdriving driver 140 reads the second memory unit 140b and the second memory unit 140b, which store data for overdriving, and inputs the data from the first memory unit 130a. And an overdriving controller 140a for overdriving and outputting the TTL image signal based on the data of the second memory unit 140b.

The operation of the liquid crystal display according to the exemplary embodiment of the present invention configured as described above will be described in detail.

First, the LVDS receiving unit 120 converts an LVDS type image signal input from the external system 110 into a TTL type image signal and outputs the converted TTL type image signal, and the output TTL type image signal is the first memory unit 130a. ) At this time, the clock signal CLK of the TTL image signal is input from the LVDS receiver 120 to the spread IC 130b. The spread IC 130b spreads and outputs the clock signal CLK, and the spread clock signal CLK` is input to the first memory unit 130a in which the TTL image signal is stored. In this case, the first memory unit 130a outputs the TTL image signal in synchronization with the spread clock signal CLK`. The TTL image signal outputted in synchronization with the spread clock signal CLK` is reduced in frequency. Therefore, EMI of the TTL image signal output from the first memory unit 130a is reduced.

Next, the TTL type image signal output from the first memory unit 130a and reduced in EMI is input to the overdriving controller 140a of the overdriving driver 140. Thereafter, the overdriving controller 140a reads data from the second memory unit 140b and overdrives the TTL image signal input from the first memory unit 130a based on the data. do.                     

Subsequently, the TTL-type image signal of the overdriving controller 140a is timing-formatted and output through the timing controller 170, and then the timing-formatted TTL-type image signal is outputted through the data drive IC 150. Is applied to.

Here, since the frequency of the TTL-type image signal is already reduced before being applied to the overdriving driver 140, it is possible to prevent generation of EMI in the overdriving driver 140.

The liquid crystal display according to the present invention as described above has the following effects.

The liquid crystal display according to the present invention includes a frequency converter between the LVDS receiver and the overdriving driver. Therefore, EMI according to the frequency of the TTL type image signal applied from the LVDS receiver to the overdriving driver can be prevented.

Claims (4)

An LVDS receiving unit converting an LVDS type image signal input from an external system into a TTL type image signal and outputting the converted image signal; A frequency converter for reducing and outputting a frequency of the TTL image signal output from the LVDS receiver; And an overdriving driver for receiving and overdriving the TTL image signal outputted from the frequency converting unit and outputting the overdriven image signal; The frequency converter may include: a spread IC configured to receive and spread a clock signal for synchronizing the TTL image signal from the LVDS receiver; And a first memory unit configured to store a TTL image signal provided from the LVDS receiver and to receive the spread clock signal and to output the stored TTL image signal in synchronization with the spread clock signal. ; The overdriving driving unit may include a second memory unit in which data about overdriving is stored; And an overdriving controller configured to read data of the second memory unit and overdrive the TTL image signal input from the first memory based on the data. And the first memory unit is built in the timing controller, and the spread IC is provided outside the timing controller. delete delete delete

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