KR100229617B1 - Liquid crystal display device with multi-screen - Google Patents

Abstract

The aspect ratio of the display area of a general liquid crystal display device is 3: 4. This was known as the most convenient ratio for the human eye to receive information. However, as the expectations for high vision and wide broadcasting are raised, wide liquid crystal displays having an aspect ratio of 9:16 in the display area have been developed. In addition, there is an increasing demand for a multi-screen display device that realizes multiple independent images with a single wide liquid crystal display device.

Conventional LCDs divide the main screen into a main screen that occupies the largest area in the display area and a sub screen that is divided and displayed on a part of the remaining areas in order to realize the multi-screen. The signal line driver and the scan line driver connected to the pixel to be displayed and the pixel to display the sub-screen were separated. That is, there is a first signal line driver and a first scan line driver for displaying a main screen, and a second signal line driver and a second scan line driver for displaying a sub screen. This has the disadvantage that the structure is complicated, the manufacturing cost increases.

The present invention relates to a multi-screen liquid crystal display device capable of driving a pixel connected to a first signal line driver for displaying a main screen and a pixel connected to a second signal line driver for displaying a sub-screen with one scan line driver.

Description

Multi Screen Liquid Crystal Display

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to multi-screen processing of a liquid crystal display device, and more particularly, to a structure design and signal processing of a liquid crystal display device for processing multiple image information by implementing multiple screens on one liquid crystal panel. .

The CRT CRT used as a general display device uses a method of displaying an image by an RGB electron gun. However, the CRT CRT has a disadvantage in that it is necessary to increase the thickness in order to enlarge the display area. The reason is that an image can be displayed on the screen only when the distance between the electron gun and the surface of the CRT is sufficiently secured. Display devices are being developed to replace the CRT CRTs. Among them, the liquid crystal display device is a display device replacing the CRT CRTs.

As shown in FIG. 1, the liquid crystal display device is composed of a controller IC 13, a scan line driver IC 11, a signal line driver IC 10, and a thin film transistor 16. As shown in FIG. A plurality of scan lines 15 are connected to an output line of the scan line driver IC 11, and a plurality of signal lines 14 are connected to an output line of the signal line driver IC 10. At each intersection, a pixel 17 and a thin film transistor are formed. A thin film transistor (hereinafter referred to as TFT) 16 is connected to the pixel 17. In the TFT, a gate (not shown) is connected to the scan line 15, and a source (not shown) is connected to a signal line (not shown). 14, a drain (not shown) is connected to the pixel 17. Thus, when a voltage is applied to the gate of the TFT, the source and the drain of the TFT become conductive, and when the voltage is not applied to the gate of the TFT, the source and the drain of the TFT are disconnected.

The liquid crystal display device operates as follows. The image signal input from the outside is converted into a signal voltage by the controller IC 13 and applied to the signal line driver IC 10. The signal line driver IC simultaneously applies a signal voltage corresponding to one line to all the signal lines 14 according to a predetermined periodic signal. At this time, the scan line driver IC 11 applies the scan voltage to the scan line 15 of the first line according to a predetermined period signal to conduct all the TFTs 16 connected to the scan line of the first line so that the signal voltage is the first. It is applied to the pixel electrode of a line. When the signal line of the next line is applied to the signal line in the signal line driver IC, the scan line driver IC applies the scan voltage to the scan line of the second line so that the signal voltage is applied to the pixel electrode of the second line. Subsequently, when the signal voltage of the next line is applied from the signal line driver IC, the scan line driver IC conducts the TFT by applying a scan voltage to the scan line connected to the pixel electrode to which the signal voltage is to be applied. Then, the signal voltage applied to the signal line is applied to the pixel through the source and the drain of the TFT to display an image on the liquid crystal display.

The process of generating the signal voltage will be described with reference to the block diagram shown in FIG. The composite video signal s1 is externally applied to the chroma circuit 20. The composite image signal has two signal components, an RGB (red, green, blue) signal, which is a color signal to be applied to a pixel, and a control signal for driving the liquid crystal display.

First, the RGB signal is demodulated in a demodulation circuit (not shown) included in the chroma circuit 20 and applied to the signal line driver IC 10. The control signal is a signal extracted from the composite video signal by the chroma circuit as the synchronization signal component s3. The sync signal component s3 is generated by the controller IC 13 as a horizontal sync signal and a vertical sync signal.

The controller IC 13 converts the horizontal synchronization signal into signal line driver IC control signals s4 and s5, and applies the signal line driver IC control signal to the signal line driver IC, the scan line driver IC, and the chroma circuit to drive the signal line driver. Controls the operation of the IC, scan line driver IC, and chroma circuit. The controller IC converts the vertical synchronous signal into a scan line driver IC control signal s6, and applies the scan line driver IC control signal to the scan line driver IC to control a start point at which the scan line driver IC applies a scan voltage. .

The aspect ratio of a region (hereinafter referred to as a screen) for displaying an image in a liquid crystal display device is 3: 4, which is generally known as an optimal size ratio at which information can be obtained from a human perspective.

However, as the expectation for wide-broadcasting such as Hi-Vision and movies increases, a wide display device having a screen aspect ratio of 9:16 has been developed. In addition, a wide multi-vision capable of realizing multiple screens simultaneously with a single wide display device having an aspect ratio of 9:16 has appeared. This trend is no exception to liquid crystal displays.

Fig. 4 shows a wide liquid crystal display device proposed in Japanese Patent Laid-Open No. Hei 7-170470. The liquid crystal display of FIG. 4 first divides a liquid crystal panel having an aspect ratio of 9:16 into four in the signal line direction and three into a scan line direction to form twelve pixel blocks. In addition, the liquid crystal display of FIG. 4 displays one image by setting pixel blocks in which nine pixel blocks are arranged in a rectangular shape among the pixel blocks as a main screen, and displays the remaining three pixel blocks. Each sub-screen is set to display a different image from the main screen image. That is, the main screen is connected with a first signal line driving block 31 for applying a main video signal and a first scan line driving block 30 for displaying an image signal applied from the first signal line driving block on a pixel. The sub picture includes a second signal line driving block 33 for applying a separate sub picture signal independent of the first video signal, and a second scan line driving block for displaying a video signal applied from the second signal line driving block on a pixel. 32) is connected. In this case, the second signal line driving blocks 33 may be provided as many as the number of pixel blocks corresponding to the sub-screen. That is, if there are three pixel blocks displaying the sub-screen, the second signal line driving block and the second scan line driving block are three, respectively.

The liquid crystal display of FIG. 4 is operated as follows. The first TFT group connected to the first signal line receiving the signal voltage from the first signal line driving block 31 receives a gate voltage from the first scan line driving block 30. The first TFT group applies the signal voltage applied from the first signal line driving block 31 to the pixels of the main screen.

In addition, the second TFT group connected to the second signal line to which the signal voltage is applied by the second signal line driving block 33 receives the gate voltage from the second scan line driving block 32. The second TFT applies a signal voltage applied from the second signal line driving block to the pixels of the sub-screen.

However, the conventional multi-screen liquid crystal display device of Japanese Patent Laid-Open No. 7-170470 has a problem that a signal line driving block and a scanning line driving block for driving a sub-screen must be separately installed in addition to the signal line driving block and the scanning line driving block for driving a main screen. There is. That is, if the number of main screens and sub-screens is four, at least three scan line driving blocks connected to the sub-screens in addition to the scan line driving blocks connected to the main screens should be installed. This has the disadvantage that as the number of screens to be displayed increases, the structure of the liquid crystal display device becomes complicated and the manufacturing cost increases. Accordingly, there is a need for a liquid crystal display device capable of realizing multiple screens without increasing the number of scan line driving blocks.

1 shows a general schematic of a liquid crystal display.

2 is a block diagram illustrating a signal flow of a general liquid crystal display.

3 is a view showing an aspect ratio of a display area (screen) of a general display device.

4 is a view showing the structure of a conventional multi-screen liquid crystal display device.

5 is a block diagram showing an implementation of the multi-screen liquid crystal display of the present invention.

FIG. 6 is a diagram illustrating that a pixel representing a main screen and a pixel representing a subscreen are connected to one scan line.

* Explanation of Symbols on Drawing *

10: signal line driver IC 11: scan line driver IC 13: controller IC

14 signal line 15 scanning line 16 thin film transistor

17 pixel 20 chroma circuit 21 display area

30: first scan line driver 31: first signal line driver 32: second scan line driver

33: second signal line driver 100: chroma circuit 110: controller IC

120: first signal line driver 130: second signal line driver 140: multiplexer

150: first video processor 160: second video processor 170: third video processor

180: scan line driver 190: liquid crystal panel 195: main screen

197: first part screen 198: second part screen 199: third part screen

200: pixel of the first subscreen 210: pixel of the second subscreen

220: pixel of the third sub-screen 230: pixel of the main screen

s1, s'1: Composite video signal s2, s'2: RGB signal

s3, s'3: Synchronization signal component s4, s'4: Chroma circuit control signal

s5: signal line driver IC control signal s'5: first signal line driver IC control signal

s6, s'6: scan line driver IC control signal s'7: second signal line driver IC control signal

s'8: multiplexer control signal s'9: fourth video processor control signal

s'10: third video processor control signal s'11: second video processor control signal

s'12: Part 1 screen RGB signal s'13: Part 2 screen RGB signal

s'14: Part 3 screen RGB signal s'15: Multiplexer RGB signal

The present invention is a multi-screen wide liquid crystal display device having an aspect ratio of 9:16 that can drive a main screen and a sub-screen with one scan line drive block, and has a smaller scan line drive block structure than a conventional multi-screen wide liquid crystal display device. It is simple and low cost. FIG. 5 is a block diagram illustrating a circuit of the present invention for implementing a multi-screen in a wide liquid crystal display having an aspect ratio of 9:16. That is, the liquid crystal display of the present invention is composed of a composite signal input terminal, an image signal output terminal, a control signal input terminal and a control signal output terminal, and receives the composite image signal S'1 as the composite signal input terminal. The composite video signal is separated into an RGB signal S'2 and a synchronization signal S'3, and the RGB signal is output to the image signal output terminal, the synchronization signal is output to the control signal output terminal, and the chroma circuit control signal ( A chroma circuit (100) receiving S'4) as the control signal input terminal; And a synchronous signal input terminal connected to the control signal output terminal, a synchronous signal output terminal connected to the control signal input terminal, a first signal control output terminal, a second signal control output terminal, and a scan control output terminal. The synchronization signal applied to the terminal is converted into a first signal line drive signal S'5, a second signal line drive signal S'7, S'9, S'10, S'11, and a scan line drive signal S'6. A controller IC which converts the first signal line driving signal to the first signal control output terminal, applies the second signal line driving signal to the second signal control output terminal, and applies the scan line driving signal to the scan control output terminal. 110); A second signal including a second signal control input terminal connected to the second signal control output terminal and a first sub image output terminal, and a first signal applied to the second signal control input terminal with a first sub RGB signal S'12; A first video processor 150 applied to the first sub-image output terminal according to a pre-drive signal; A second signal including a second signal control input terminal connected to the second signal control output terminal and a second sub-image output terminal, and a second signal applied to the second signal control input terminal with a second sub RGB signal S'13; A second video processor 160 applied to the second sub-image output terminal according to a pre-drive signal; A second signal comprising a second signal control input terminal connected to the second signal control output terminal and a third sub image output terminal, and a third signal applied to the second signal control input terminal by applying a third sub RGB signal S'14; A third video processor (170) applied to the third sub-image output terminal according to a pre-drive signal; A first sub image input terminal connected to the first sub image output terminal, a second sub image input terminal connected to the second sub image output terminal, and a third sub image input terminal and sub image connected to the third sub image output terminal And a multiplex control terminal connected to an output terminal and the second signal control output terminal, wherein any one of the first sub-GB RGB signal, the second sub-GB RGB signal, and the third sub-GB RGB signal is applied to the multiplex control terminal. A multiplexer 140 selected according to a second signal line driving signal and applied to the sub-image output terminal; A first signal control input terminal connected to the video signal output terminal, a first signal control input terminal connected to the first signal control output terminal, and a first signal output terminal; A first signal line driver IC (120) applied to the first signal output terminal in accordance with a first signal line driver signal applied to a signal control input terminal; The sub-image signal applied to the sub-image input terminal comprising a sub-image input terminal connected to the sub-image output terminal, a second signal control input terminal connected to the second signal control output terminal, and a second signal output terminal; A second signal line driver IC (130) for applying S'15 to the second signal output terminal according to the second signal line driver signal applied to the second signal control input terminal; A scan line driver IC comprising a scan output terminal connected to the scan control output terminal and configured to apply a scan signal to the scan output terminal according to the scan line drive signal S'6 applied to the scan input terminal; 180); 3n first signal lines connected to the first signal output terminal, n second signal lines parallel to the first signal line and connected to the second signal output terminal, and connected to the scan output terminal and connected to the first signal line and the first signal line. A main screen area 195 composed of 3m scanning lines orthogonal to two signal lines, 3n x 3m pixels formed at the intersection of the first signal line and the scanning line, and n formed at the intersection of the second signal line and the scanning line A first sub-screen area 197 consisting of x m pixels, a second sub-screen area 198 consisting of n x m second pixels, and a third sub-screen area consisting of n x m second pixels ( It consists of a liquid crystal panel 190 composed of 199. At this time, the video processor group of the first video processor, the second video processor, and the third video processor is composed of the same number of video processors as the number of sub-screens. That is, if there are three sub-screens, the number of video processor groups is three. In fact, if the main screen is 9:12 in the display area having an aspect ratio of 9:16, three sub-screens having an aspect ratio of 3: 4 can be formed.

A liquid crystal panel having an aspect ratio of 9:16 is divided into four in the signal line direction and three in the scan line direction to form 12 pixel blocks. In this case, the main screen is set as pixel blocks in which nine pixel blocks adjacent to each other among the pixel blocks are formed in a rectangular shape, and each of the remaining three pixel blocks is a sub-screen. Is set.

The operation of the multi-screen wide liquid crystal display device will be described in detail as follows. First, when the composite video signal s'1 is applied to the chroma circuit 100, the composite video signal is converted from the demodulation circuit included in the chroma circuit to the first RGB signal s'2 to display the main picture. It is demodulated and applied to the first signal line driver 120. In order to display the sub-screen, the second RGB signal, the third RGB signal, and the fourth RGB signal are applied to the multiplexer 140 from the video processor group 150, 160, and 170, and the second RGB signal s'12. ) And the third RGB signal s'13 and the fourth RGB signal s'14 are demodulated and selected from the multiplexer 140 according to the control signal of the controller IC 110 and applied to the second signal line driver 130. The second signal line driver 130 includes a plurality of signal line driver ICs, and the signal line driver IC outputs an image signal to signal lines corresponding to the sub-screens 197, 198, and 199 according to a horizontal synchronization signal.

The synchronization signal component s'4 generated by the chroma circuit 100 is applied to the controller IC 110, and the controller IC 110 converts the synchronization signal component s'4 into a horizontal synchronization signal and a vertical synchronization signal. And generate signal line driver IC control signals s'5 and s'7 s'8 that control the signal line driver IC in synchronization with the horizontal synchronization signal. The first signal line driver IC control signal s'5 is applied to the first signal line driver 120 to control the first signal line driver connected to the pixel displaying the main screen. Also, the second signal line driver IC control signal s'7 is applied to the second signal line driver 130 to control the second signal line driver connected to the pixel displaying the sub-screen 197. In addition, the multiplexer control signal s'8 is applied to the multiplexer 140 and optionally the first sub-screen RGB signal s'12, the second sub-screen RGB signal s'13 and the third sub-screen RGB signal. Control the output of (s'14). Finally, the controller IC 110 generates a scan line driver IC control signal s'6 that controls the scan line driver IC in synchronization with the vertical synchronization signal. The scan line driver IC control signal s'6 is applied to the scan line driver 180 to scan a pixel connected to a signal line to which an image signal is applied from the first signal line driver 120 and the second signal line driver 130. The scan line driver which applies a voltage is controlled.

Conventionally, a scanning line for driving a pixel for displaying a main screen and a pixel for displaying a sub-screen is separated, and a plurality of scan line driver units are used to drive a scan line connected to a pixel for displaying a main screen and a pixel for displaying a sub-screen. I needed it.

However, the core of the present invention is the pixel 230 of the main screen to which the signal voltage output from the first signal line driver 120 is applied and the pixel of the sub-screen to which the signal voltage output from the second signal line driver 130 is applied. 200, 210, and 220 are connected to the same scan line as shown in FIG. Therefore, it is possible to drive both the main screen and the sub screen pixels with one scanning voltage.

Therefore, the present invention can simultaneously drive the main screen and the sub-screen with one scan line driver without the need to add a separate scan line driver for driving the sub-screen. That is, the present invention can manufacture a multi-screen liquid crystal display device with a simpler structure than in the related art.

Claims (3)

Image processing means for receiving a composite video signal and separating the data signal into a synchronization signal; Image control means for converting the synchronous signal separated by the image processing means into a first signal line drive signal, a second signal line drive signal, and a scan line drive signal; First sub image processing means for receiving the second signal line driving signal converted by the image control means and outputting a first sub data signal; Second sub image processing means for receiving the second signal line driving signal converted by the image control means and outputting a second sub data signal; Third sub image processing means for receiving the second signal line driving signal converted by the image control means and outputting a third sub data signal; The first sub data signal, the second sub data signal, the third sub data signal, and the second signal line driving signal are applied to the first sub data signal and the second sub data signal in synchronization with the second signal line driving signal. Sub-video output means comprising video selecting means for selecting and outputting any one of the third sub data signals; First signal line driving means for receiving a data signal separated by the image processing means and a first signal line driving signal converted by the image control means to generate a first signal voltage; A second signal generated from the first sub data signal, the second sub data signal, and the third sub data signal output from the sub image output means and the second signal line driving signal to generate a second signal voltage; Pre-drive means; Scanning line driving means for receiving the converted scanning line driving signal from the image control means and outputting a scanning voltage; A main screen region consisting of 3n × 3m pixels formed at the intersections of 3n first signal lines to which the first signal voltage is applied and 3m scanning lines to which the scan voltage is applied are orthogonal to each other; N sub-areas formed with n second signal lines receiving the second signal voltage and the 3m scanning lines receiving the scanning voltage are orthogonal to each other, and three regions composed of n x m pixels formed at intersections thereof are formed. Liquid crystal display device comprising a liquid crystal panel. 2. The apparatus of claim 1, wherein the image processing means receives a composite video signal and separates the main data signal, the sub data signal, and the synchronization signal, and the first signal line driving means receives the main data signal. And an image processing means, a second sub image processing means, and a third sub image processing means receive the sub data signal. The liquid crystal display device according to claim 1 or 2, wherein an aspect ratio of the sum of the main screen area and the sub-screen area is 9:16.

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