KR19990024908A - 3-color driving liquid crystal display and driving method - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-color driving liquid crystal display using three color back light. Applied to a display device, the timing margin of the driving circuit can be increased.

Description

3-color driving liquid crystal display and driving method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display, and more particularly, to a driving circuit and a driving method of a thin film transistor-liquid crystal display (TFT-LCD).

Liquid crystal display, which is a kind of flat panel display, uses the characteristics of liquid crystal whose light transmittance changes according to the voltage, and is widely used because it can be driven at low voltage and consumes little power. Devices are also being developed. In color liquid crystal displays, color filters are generally used. As liquid crystal panels are enlarged and high resolution, color processing is difficult to be processed, and alignment errors caused by bonding of substrates. And a decrease in aperture ratio due to the formation of a black matrix.

In order to solve this problem, a three-color driving method using a back light of three colors of red, green, and blue (R, G, B) has been used recently without using a color filter. Each back light used in the three-color driving method can operate independently, and turns on sequentially with a certain period. According to the image information input to the liquid crystal display, each of the R, G, and B data signals is sequentially transmitted to each pixel of the liquid crystal panel within one frame period, and each light source is turned on in synchronization with the transmission period. The color image is displayed on the liquid crystal panel. Here, the frame means the time for displaying one screen in the entire area on the panel capable of displaying an image, and the frame at 60 Hz is about 16.7 ms.

FIG. 1 is a block diagram of a driving circuit of a conventional three-color driving liquid crystal display. As shown in FIG. 1, the conventional three-color driving circuit receives the R, G, and B data signals and stores them in a frame memory 10. When the data signals of one frame are all stored, the data signals are transmitted to the video memory 20, and the data signals for the next frame are stored in the frame memory 10. The data signal stored in the video memory 20 is sequentially transmitted to the data driver 30 for each of R, G, and B, and the data driver 30 applies a voltage corresponding to the transmitted data signal to the liquid crystal panel. At this time, the controller 40 receives the synchronization signal and lights the appropriate back light according to the color of the data signal applied to the liquid crystal panel.

As described above, the R, G, and B data signals are simultaneously processed for one frame in the color filter method, but are sequentially processed in the three-color driving method. Therefore, three full screens must be displayed in one frame. Therefore, the timing margin of the timing signal required for driving is reduced to about one third. The reduction of the timing margin lowers the on and off characteristics of the thin film transistor, thereby reducing the time for charging the data signal to the pixel, thereby lowering the luminance ratio of the screen. In addition, as the frequency of the data signal increases, the frequency of the timing signals dealing with the data signal also increases, which may cause a problem of electromagnetic interference.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to increase the timing margin in a driving circuit of a three-color driving liquid crystal display device, thereby improving the luminance ratio of the screen, and It is to reduce electromagnetic interference by reducing the frequency.

1 is a block diagram showing a driving circuit of a conventional three-color driving type liquid crystal display device;

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

In order to achieve this problem, the present invention applies a multi-scan method to a three-color driving liquid crystal display. That is, the timing margin of the driving circuit can be increased by dividing the liquid crystal panel and simultaneously applying each data signal for each divided region.

The multi-scan three-color liquid crystal display device receives an image signal of three colors R, G, and B, stores data signals at frame periods, and matches R, G, and B 3 that match the color of the data signal applied to the liquid crystal panel. The multi-color driving unit which sequentially turns on the back light of the color, and the multi-scanning unit that stores the data signals transmitted from the three-color driving units in a frame period in a FIFO manner, divides the liquid crystal panel, and simultaneously applies data signals corresponding to the respective divided regions. It consists of a drive unit.

The three-color driving unit includes an analog to digital converter (A / D converter) for converting analog image signals of R, G, and B into digital data signals, a frame memory and a liquid crystal panel for storing data signals at frame periods. And a controller for controlling the back light driver to light the back light corresponding to the data signal applied to the liquid crystal panel.

The multi-scan driver includes a FIFO frame memory for storing the data signals output from the three-color driver in a first in first out (FIFO) method, an output buffer for dividing the data signals to be applied to the liquid crystal panel for each divided area, and a divided area. And a data driver for simultaneously applying the data signals divided into the liquid crystal panels and a gate driver for simultaneously applying the scan signals to the divided regions.

In the driving method of the three-color driving liquid crystal display, first, data signals of three colors R, G, and B are stored at a frame period, and when the three data signals of one color of R, G, and B are stored, the data signals are again FIFO type. After storing, the liquid crystal panel is divided, the data signals stored for each divided region are read and applied simultaneously to the liquid crystal panel, and the back light corresponding to the color of the data signal applied to the liquid crystal panel is sequentially turned on.

Hereinafter, preferred embodiments of the present invention will be described. However, the following examples are only preferred embodiments of the present invention and the present invention is not limited to the following examples.

2 illustrates a driving circuit of the liquid crystal display according to the exemplary embodiment of the present invention. As shown in FIG. 2, the liquid crystal display driving circuit according to the present invention includes a three-color driving unit 10 and a liquid crystal panel 30 driving the rear lights 33, 34, and 35 of three colors R, G, and B. The multi-scan driver 20 divides and drives the region 31 and the lower panel region 32.

The three-color driving unit 10 is an A / D converter 11 for converting an image signal of an analog form divided into R, G, and B into a digital data signal, respectively, and the A, D, When the R, G, and B data signals of one frame are all stored in the frame memory 12 and the frame memory 12 that receive and store each data signal, the video memory 13 receives the data signal from the frame memory 12. ), A back light driver 16 which drives respective back lights 33, 34, and 35 which are light sources of the liquid crystal panel 30, and a back light 33 corresponding to a color of a data signal applied to the liquid crystal panel 30. And a controller 15 for controlling the timing of the frame memory 12, the video memory 13, and the back light driver 16 so that the lights 35, 36 are turned on.

Here, the clock signal used in the A / D converter 11 is made in the phase-locked loop circuit 14 using the horizontal synchronization signal Hsync and the vertical synchronization signal Vsync. To the / D converter 11.

The multi-scan driver 20 receives the data signals from the FIFO frame memory 21 and the FIFO frame memory 21 which store the data signals stored in the video memory 13 in the FIFO method (the upper region of the liquid crystal panel 30). 31, an output buffer 22 for dividing the upper data signal to be applied to the lower data signal to be applied to the lower region 32 of the liquid crystal panel 30, and the upper data signal from the output buffer 22 to receive the upper data signal. The upper data driver 23 applied to the upper region 31 of the 30 and the lower data driver 24 receiving the lower data signal from the output buffer 22 and applied to the lower region 32 of the liquid crystal panel 30. The upper gate driver 28 applies a gate signal as a scan signal to the upper region 31 of the liquid crystal panel 30, and the lower gate driver 29 applies a gate signal to the lower region 32 of the liquid crystal panel 30. )

If the clock frequencies used for the video memory 13 and the FIFO frame memory 21 are different, a frequency divider may be inserted between them to adjust the frequency. The speed at which the data signal is stored in the FIFO frame memory 21 is controlled by a memory write controller 25, and the rate at which the data signal stored in the FIFO frame memory 21 is read is a memory read controller. controller). Since the memory read controller 26 receives a clock signal from an oscillator 27, the memory read adjuster 26 may read the data signal at a desired speed regardless of the speed at which the data signal is stored. If the number of horizontal lines of the liquid crystal panel 30 is n, a vertical start signal (STV) signal is simultaneously applied to the first horizontal line and the n / 2 + 1 horizontal line, so that the liquid crystal panel 30 is upper part. The region 31 and the lower region 32 are driven simultaneously.

The three-color driver 10 converts an analog image signal into a digital signal, stores each frame, and outputs the same to the multiple scan driver 20. In addition, by sequentially lighting the back light (33, 34, 35) corresponding to the color of the data signal applied to the liquid crystal panel 30, the color image is displayed on the liquid crystal panel (30).

The multi-scan driver 20 stores the data signals input from the three-color driver 10 in a FIFO manner so that they can be sequentially outputted, and the liquid crystal panel 30 is connected to the upper region 31 and the lower region 32. The data signals are divided and applied respectively. Therefore, an image is displayed simultaneously in the divided upper region 31 and lower region 32.

The driving method of such a liquid crystal display converts analog image signals of three colors R, G, and B into digital data signals and stores them in frame periods. When the R, G, and B tricolor data signals of one frame are stored, the data signals are stored again in FIFO mode. At this time, the frequency of the data signal may be distributed in accordance with the write speed of the memory for storing the data signal. In addition, the write speed and read speed of the memory to store the data signal can be adjusted independently.

Next, the liquid crystal panel is divided into upper and lower regions, and the stored data signals are read for each region and simultaneously applied to the liquid crystal panel. At this time, the back light corresponding to the color of the data signal applied to the liquid crystal panel is sequentially turned on to display a color image.

As described above, the pulse width of the gate signal may be doubled by applying the multi-scanning method to the three-color driving liquid crystal display. Therefore, the time for one horizontal line to charge the data signal is doubled, and a timing margin corresponding to two thirds of the color filter type liquid crystal display device is provided.

As described above, the liquid crystal display according to the present invention increases the timing margin of the driving circuit by applying the multiple scanning method to the driving circuit for the three-color driving method. Therefore, the luminance ratio of the liquid crystal display can be improved, and malfunction of the driving circuit due to electromagnetic wave interference can be reduced.

Although this invention has been described with reference to the most practical and preferred embodiments, the invention is not limited to the embodiments disclosed above, but also includes various modifications and equivalents which fall within the scope of the following claims.

Claims (9)

Three-color driving unit that receives the red, green, blue three-color image signal and outputs the data signal at the frame period, and turns on the red, green, blue three-color back light in order, And a multi-scan driver for storing the data signal transmitted from the three-color driver in a frame period in a FIFO manner, and dividing a liquid crystal panel to simultaneously apply the data signal corresponding to each divided area. Driving circuit for liquid crystal display device. In claim 1, Is inserted between the three-color driver and the multiple scan driver A frequency divider for matching the frequency of the data signal output from the three color driver and the memory write speed of the multiple scan driver further comprises. Driving circuit for liquid crystal display device. In claim 1, The three-color drive unit Analog / digital converter that converts analog image signals of red, green and blue colors into digital data signals, respectively A frame memory which receives the data signal from the analog / digital converter and stores the data signal at a frame period; A video memory which receives the data signal from the frame memory and stores the data signal and outputs the data signal to the multiple scan driver; A rear light driver for lighting the rear light source of the liquid crystal panel; A controller for synchronizing the frame memory and video memory with the back light driver; Driving circuit for liquid crystal display device. In claim 3, The clock signal of the analog / digital converter is Made of a phase-locked loop circuit that uses a vertical sync signal and a horizontal sync signal as input signals Driving circuit for liquid crystal display device. In claim 1, The multiple scan driver A FIFO frame memory for receiving the data signal output from the three color driver and storing the data signal in a FIFO method; An output buffer receiving the data signal output from the FIFO frame memory and outputting a data signal classified for each divided area of the liquid crystal panel; A data driver which receives the data signal from the output buffer and simultaneously applies a data signal for each divided area of the liquid crystal panel; The gate driver may include a gate driver configured to simultaneously apply a scan signal to each of the divided regions in the liquid crystal panel. Driving circuit for liquid crystal display device. In claim 5, The FIFO frame memory Controlled by memory write regulators and memory read regulators that use clock signals of different frequencies Driving circuit for liquid crystal display device. Converting the red, green, and blue analog image signals into digital data signals, respectively, Storing the digital data signal at a frame period; Storing the data signal in a FIFO method; Dividing the liquid crystal panel to which the data signal is to be applied and dividing and simultaneously applying the data signals for each divided region; Lighting a back light corresponding to a color of the data signal applied to the liquid crystal panel; Driving method of liquid crystal display device. In claim 7, Before storing the data signal in FIFO mode Adjusting a frequency of the data signal to a write speed of a memory to store the data signal; Driving method of liquid crystal display device. In claim 7, When storing the data signal in FIFO method Independently adjusting a write speed and a read speed of a memory to store the data signal Driving method of liquid crystal display device.