KR20110003156A - Liquid crystal display device - Google Patents

Abstract

PURPOSE: A liquid crystal display which selectively drives a plurality of liquid crystal panel by using one timing controller board is provided to reduce a manufacturing cost by using one control printed circuit board. CONSTITUTION: A plurality of gate lines and a plurality of data lines are respectively arranged in a plurality of liquid crystal panels(120). The control printed circuit board selectively controls and drives a plurality of liquid crystal panels. A plurality of LVDS receivers is provided data from the external system. In order to include a pair of fourth flexible cables is composed to score.

Description

Liquid crystal display device

The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device capable of selectively driving a plurality of liquid crystal panels using one timing controller board.

In general, a liquid crystal display device may be classified into a liquid crystal display panel displaying a video signal and a driving circuit applying a driving signal to the liquid crystal display panel from the outside.

The liquid crystal display panel has a liquid crystal layer formed between two transparent substrates (glass substrates) bonded to each other with a predetermined space. One of the two transparent substrates includes a plurality of gate lines arranged at regular intervals, and the gate lines. A plurality of data lines arranged at regular intervals in a vertical direction, and a plurality of thin film transistors formed in each pixel region in a matrix form defined by the gate lines and the data lines, the gate lines and the data lines intersect. Formed on the part.

Pixel electrodes and a common electrode for applying an electric field to each of the pixel regions are provided. The pixel electrodes are connected to any one of the data lines via the source and drain terminals of the thin film transistor, and the gate terminal of the thin film transistor is connected to any one of the gate lines. Therefore, when the turn-on signal is sequentially applied to the gate line, the data signal is applied to the pixel electrode of the corresponding line, thereby displaying an image.

The driving circuit includes a data driver for inputting a data signal to each data line of the liquid crystal display panel, a gate driver for applying a scan pulse to each gate line of the liquid crystal display panel, and a display input from a system of the liquid crystal display panel. A timing controller which receives data, vertical and horizontal synchronization signals, and a control signal such as a clock signal and formats and outputs each display data, clock, and control signal at a timing suitable for the gate driver and the data driver to reproduce a screen; A power supply unit supplying a voltage required to the panel and each unit, and a DC / DC conversion unit outputting a constant voltage, a gate voltage, a reference voltage, and a common voltage used in the liquid crystal display panel using the voltage output from the power supply unit. And inverters for driving backlights. It is configured in comparison.

The data driver includes a plurality of data driver integrated circuits and is mounted in a data tape carrier package. The data tape carrier package is connected between the liquid crystal display panel and the data printed circuit board. The gate driver includes a plurality of gate driver integrated circuits (ICs), and the gate driver integrated circuits (ICs) may be mounted on the liquid crystal panel. At this time, the remaining driving circuits of the driving circuits except for the gate driver and the data driver are mounted on the control printed circuit board.

Meanwhile, in order to drive one liquid crystal display panel, a data printed circuit board on which a plurality of data driver ICs are mounted and a control printed circuit board on which driving circuits for driving the liquid crystal display panel are mounted are required. For example, when driving a panel having a 2 × 2 tiling structure using four liquid crystal display panels having a resolution of 1920 * 1080, four liquid crystal display panels must be driven. A substrate and four control printed circuit boards are needed. Four control printed circuit boards must be manufactured, and the structure in which the four control printed circuit boards are arranged becomes complicated. In addition, it is difficult to cope with the existing individual control printed circuits for the up-and-down division driving to correspond to the 3840 * 2160 resolution liquid crystal display panel instead of the 2 × 2 tiling structure using the above four liquid crystal display panels. There is a need for an integrated control printed circuit board that can easily control up, down, left and right image signals.

An object of the present invention is to provide a liquid crystal display device that can control a plurality of liquid crystal display panels using one control printed circuit board, and in particular, can easily control a liquid crystal display panel having a resolution of 3840 * 2160.

In addition, an object of the present invention is to provide a liquid crystal display device capable of controlling up to four liquid crystal display panels with one control printed circuit board to reduce manufacturing costs.

According to an exemplary embodiment of the present invention, a liquid crystal display includes a plurality of liquid crystal panels each including a plurality of gate lines and a plurality of data lines, and a plurality of liquid crystal panels connected to one side of each of the plurality of liquid crystal panels. A plurality of data printed circuit boards having data driver integrated circuits for driving data lines of the data lines; and resolutions of corresponding liquid crystal panels formed on the plurality of data printed circuit boards and connected to the plurality of data printed circuit boards. A plurality of memories storing information, a control printed circuit board for selectively controlling and driving the plurality of liquid crystal panels, and a plurality of cables for selectively connecting the plurality of data printed circuit boards and the control printed circuit board. And the control printed circuit board includes whether the plurality of flexible cables are connected. Recognizes via a plurality of the memory formed in the data printed circuit board connected to the cables and the electrical and controls and drives a plurality of the liquid crystal panel connected to a plurality of reading information from the memory, the group control printed circuit board of the connection.

The present invention includes a control printed circuit board capable of controlling a liquid crystal display panel having a resolution of up to 3840 * 2160, and recognizes the number of liquid crystal display panels using the EEPROM of the liquid crystal display panel connected to the control printed circuit board. The controller may recognize resolution information stored in an EEPROM of a liquid crystal display panel connected to the control printed circuit board and process data corresponding to the overall resolution of the liquid crystal display panel connected to the control printed circuit board. In addition, the present invention can reduce manufacturing costs by controlling and driving a plurality of liquid crystal display panels using a single control printed circuit board.

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

1 is a view schematically showing a state in which a control printed circuit board according to the present invention is connected to four liquid crystal display panels.

As shown in FIG. 1, four liquid crystal display panels 110a to 110d are connected to one control printed circuit board 120. Each of the four liquid crystal display panels 110a to 110d includes data printed circuit boards 131a to 131d, and each of the data printed circuit boards 131a to 131d includes first to fourth flexible cables (FFC). Flat cable (200 ~ 230) is connected to the control printed circuit board 120. In this case, the four liquid crystal display panels 110a to 110d have a resolution of 1920 * 1080.

As shown in FIG. 2, the first liquid crystal display panel 110a among the four liquid crystal display panels 110a to 110d includes a thin film transistor array in which a plurality of gate lines GL and a plurality of data lines DL are arranged. An image display unit 113 provided at an area where the substrate 111, the plurality of gate lines GL, and the data lines DL intersect to display an image, and one edge region of the thin film transistor array substrate 11; A plurality of gate tape carrier packages 122 connected to the plurality of gate tape carrier packages, a gate driver integrated circuit 123 mounted on the gate tape carrier package 122, and other edge regions of the thin film transistor array substrate 111. A plurality of data tape carrier packages 132 connected between one data printed circuit board 131a and a data driver integrated circuit 133 mounted on the data tape carrier package 132, respectively.

In addition, the first liquid crystal display panel 110a may further include a color filter substrate 12 facing the thin film transistor array substrate 111 with a predetermined cell-gap, and the color of the thin film transistor array substrate 111. The liquid crystal layer is formed between the filter substrates 12.

One short side and one long side of the thin film transistor array substrate 111 protrude from the color filter substrate 112, and a gate pad part and a data pad part are provided in the protruding region of the thin film transistor array substrate 111. In addition, an image display unit 113 is provided in an area where the thin film transistor array substrate 111 and the color filter substrate 112 face each other.

In the image display unit 113 of the thin film transistor array substrate 11, a plurality of gate lines GL are arranged in a horizontal direction and connected to the gate pad unit, and a plurality of data lines DL are arranged in a vertical direction. It is connected to the said data pad part. Accordingly, the gate line GL and the data line DL cross each other, and pixels having the thin film transistor TFT and the pixel electrode are formed at the intersection thereof.

The image display unit 113 of the color filter substrate 12 includes a red, green, and blue color filter separated and applied to each pixel by a black matrix, and a pixel electrode included in the thin film transistor array substrate 111. The common electrode is formed in the electric field.

Line-on-glass lines 141 are formed at an edge region where one short side and one long side of the thin film transistor array substrate 111 meet, and control signals and driving voltages provided from the control printed circuit board 120 are formed. Are supplied to the gate driver integrated circuit 123 through the first data printed circuit board 131a.

A data driver integrated circuit 133 is mounted on the data tape carrier package 132, and input pads and output pads electrically connected to the data driver integrated circuits 133 are formed. The input pad of the data tape carrier package 132 is electrically connected to the first data printed circuit board 131a, and the output pad is electrically connected to the data pad of the thin film transistor array substrate 111. Therefore, the data driver integrated circuits 133 convert image information, which is a digital signal, into an analog signal and supply the converted data to the data lines DL of the first liquid crystal display panel 110a.

Gate signal transmission lines are further formed on the data tape carrier package 132, and gate signal transmission lines formed on the first data tape carrier package 132 among the data tape carrier packages 132 are thin film transistor array substrates. It is electrically connected to the line-on-glass line 141 mounted at 111.

The first data printed circuit board 131a includes a first EEPROM (134, Electrically Erasable Programmable Read-Only Memory). The first EEPROM 134 performs I2C communication with a master formed on the control printed circuit board 120 to provide information of the first liquid crystal display panel 110 to the control printed circuit board 120. The information of the first liquid crystal display panel 110 includes basic display variables and characteristics such as display resolution, horizontal frequency, vertical frequency, color information, maximum image size, and frequency range limitation of the monitor.

In this case, the second to fourth liquid crystal display panels 110b to 110d also have the same configuration as the first liquid crystal display panel 110a as described above. Accordingly, a second EEPROM is mounted on the second data printed circuit board 131b of the second liquid crystal display panel 110b and a third data printed circuit board 131c of the third liquid crystal display panel 110c. The EEPROM is mounted, and the fourth EEPROM is also mounted on the fourth data printed circuit board 131d of the fourth liquid crystal display panel 110D.

The first data printed circuit board 131a formed on one side of the first liquid crystal display panel 110a is connected to the control printed circuit board 120 through the first flexible cable 200. The second data printed circuit board 131b formed at one side of the second liquid crystal display panel 110b is connected to the control printed circuit board 120 through the second flexible cable 210. The third data printed circuit board 131c formed on one side of the third liquid crystal display panel 110c is connected to the control printed circuit board 120 through the third flexible cable 220 and the fourth liquid crystal display panel 110d. The fourth data printed circuit board 131d formed at one side of the s) is connected to the control printed circuit board 120 through the fourth flexible cable 230.

The first to fourth flexible cables 200 to 230 are configured to have a pair of cables. The first flexible cable 200 includes a pair of cables 200a and 200b, the second flexible cable 210 also includes a pair of cables 210a and 210b, and the third flexible cable 220 also includes a pair. The cables 220a and 220b are provided, and the fourth flexible cable 230 is also provided with a pair of cables 230a and 230b.

Each of the first to fourth data printed circuit boards 131a to 131d is provided with a connection terminal (not shown) to which one end of the first to fourth flexible cables 200 to 230 is connected. Similarly, the control printed circuit board 120 is provided with a connection terminal (not shown) to which the other end of the first to fourth flexible cables 200 to 230 is connected. The control printed circuit board 120 provides a clock signal, a control signal, and an image signal to the first to fourth liquid crystal display panels 110a to 110d through the first to fourth flexible cables 200 to 230. do.

The control printed circuit board 120 may include whether the first to fourth flexible cables 200 to 230 are connected to first to fourth ends of which one end of the first to fourth flexible cables 200 to 230 is connected. The first through fourth EEPROMs formed on the data printed circuit boards 131a to 131d are recognized. Conductive patterns are formed on the first to fourth data printed circuit boards 131a to 131d to electrically connect the first to fourth flexible cables 200 to 230 and the first to fourth EEPROMs, respectively.

For example, if only the second flexible cable 210 is connected to the control printed circuit board 120, the control printed circuit board 120 may include a first end of which one end of the second flexible cable 210 is connected. 2 Information such as the resolution stored in the second EEPROM formed on the data printed circuit board 131b is read. Accordingly, the control printed circuit board 120 may control and drive the second liquid crystal display panel 110b using information stored in the second EEPROM.

In addition, if all of the first to fourth flexible cables 200 to 230 are connected to the control printed circuit board 120, the control printed circuit board 120 may include the first to fourth flexible cables 200 to 230. Read information of the corresponding liquid crystal display panel stored in the first to fourth EEPROMs respectively formed on the first to fourth data printed circuit boards 131a to 131d to which one end of each end is connected. Accordingly, the control printed circuit board 120 may control and drive the first to fourth liquid crystal display panels 110a to 110d by using information stored in the first to fourth EEPROMs.

That is, the control printed circuit board 120 recognizes whether the first to fourth flexible cables 200 to 230 are connected and reads basic information of the corresponding liquid crystal display panel through the connected flexible cable to connect the liquid crystal display panel. Image information supplied from an external system is processed for each resolution.

To this end, as shown in FIG. 3, the control printed circuit board 120 includes data provided from the first to fourth LVDS receivers 160a to 160d and the first to fourth LVDS receivers 160a to 160d. A scaler 165 for data processing for each resolution, a control signal generator 175 for generating a control signal for the resolution using data processed for each resolution in the scaler 165, and the scaler A data alignment unit 170 for aligning the data processed in operation 165 according to the connected liquid crystal display panel, and an interface for supplying the data aligned in the data alignment unit 170 to the connected liquid crystal display panel, respectively. Perform I2C communication with the first through fourth Mini LVDS buffers 180a through 180d and the first through fourth EEPROMs 134 through 140 formed on the first through fourth data printed circuit boards 131a through 131d. It includes the I2C master 190.

Each of the first to fourth LVDS receivers 160a to 160d has two input lines and is provided with an external system (for example, a graphic module of a computer system or an image demodulation module of a television reception system, not shown). It is provided with data corresponding to full HD supplied from. First input lines of the first to fourth LVDS receivers 160a to 160d receive clock signals, and second input lines receive data. The first to fourth LVDS receivers 160a to 160d receive data corresponding to full HD from an external system and provide the data to the scaler 165.

At this time, four LVDS receivers (160a ~ 160d) exist to receive data corresponding to full HD (1920 * 1080), 120Hz clock and 297MHz clock frequency from external system.

The stair 165 performs data processing in accordance with the resolution of the liquid crystal display recognized by the I2C master 190 of the full HD data provided from the first to fourth LVDS receivers 160a to 160d.

The I2C master 190 may include an EEPROM of a corresponding data printed circuit board electrically connected to the first to fourth flexible cables 200 to 230, depending on whether the first to fourth flexible cables 200 to 230 are connected. I2C communication.

For example, when only the first flexible cable 200 of the first to fourth flexible cables 200 to 230 is connected to the control printed circuit board 120, the I2C master 190 is connected to the first flexible cable 200. Basic information including the resolution of the first liquid crystal display panel 110a of FIG. 2 is transmitted from the first EEPROM 134 of the first data printed circuit board 131a electrically connected to the flexible cable 200 through I2C communication. Read. The I2C master 190 provides the scaler 165 with information of the first liquid crystal display panel 110a read from the first EEPROM 134. The scaler 165 processes the full HD data provided from an external system to match the resolution of the first liquid crystal display panel 110a by using the information supplied from the I2C master 190. The data processed by the scaler 165 is supplied to the data alignment unit 170 and the control signal generator 175, respectively.

The data aligner 170 aligns the data to match the resolution of the first liquid crystal display panel 110a using the data, and the control signal generator 175 uses the data to form the first liquid crystal. Various control signals including gate and data control signals GCS and DCS are generated to match the resolution of the display panel 110a.

Data arranged from the data aligning unit 170 is provided to the first liquid crystal display panel 110a through the first Mini LVDS 180a. Similarly, the gate and data control signals GCS and DCS generated by the control signal generator 175 are provided to the first liquid crystal display panel 110a. Thus, the control printed circuit board 120 may control and drive the first liquid crystal display panel 110a having a resolution of 1920 * 1080.

In addition, when all of the first to fourth flexible cables 200 to 230 are connected to the control printed circuit board 120, the I2C master 190 may be connected to the first to fourth flexible cables 200 to 230. Basic including the resolution of the first to fourth liquid crystal display panels 110a to 110d from the first to fourth EEPROMs 134 to 140 of the electrically connected first to fourth data printed circuit boards 131a to 131d. Read information through I2C communication. The I2C master 190 provides the scaler 165 with information of the first to fourth liquid crystal display panels 110a to 110d read from the first to fourth EEPROMs 134. The scaler 165 processes data to match the resolution of the first to fourth liquid crystal display panels 110a to 110d by using the information supplied from the I2C master 190 to match full HD data provided from an external system. do. The data processed by the scaler 165 is supplied to the data alignment unit 170 and the control signal generator 175, respectively.

The data aligner 170 aligns the data to match the resolution of the first to fourth liquid crystal display panels 110a to 110d by using the data, and the control signal generator 175 uses the data. Accordingly, various control signals including gate and data control signals GCS and DCS are generated to match the resolution of the first to fourth liquid crystal display panels 110a to 110d.

Data arranged from the data aligning unit 170 is provided to the first to fourth liquid crystal display panels 110a to 110d through the first to fourth Mini LVDSs 180a to 180d. Similarly, the gate and data control signals GCS and DCS generated by the control signal generator 175 are provided to the first to fourth liquid crystal display panels 110a to 11d. As a result, the control printed circuit board 120 recognizes basic information of the four liquid crystal display panels 110a to 110d, combines four resolution information, and processes data corresponding to the full resolution to display the first to fourth liquid crystal displays. The panels 110a to 110d can be controlled and driven.

As a result, the control printed circuit board 120 includes the scaler 165 and the I2C master 190 to be electrically connected to the first to fourth flexible cables 200 to 230. The number of liquid crystal display panels connected to the control printed circuit board 120 may be sensed by recognizing the information, and the data of at least one to four liquid crystal display panels may be processed.

Accordingly, the liquid crystal display device according to the present invention includes a control printed circuit board capable of controlling a liquid crystal display panel having a resolution of up to 3840 * 2160, and uses the EEPROM of the liquid crystal display panel connected to the control printed circuit board. The number of display panels may be recognized, and resolution information stored in an EEPROM of a liquid crystal display panel connected to the control printed circuit board may be recognized to process data corresponding to the overall resolution of the liquid crystal display panel connected to the control printed circuit board. . In addition, the liquid crystal display device according to the present invention can reduce the manufacturing cost by controlling and driving a plurality of liquid crystal display panels using a single control printed circuit board.

1 is a view schematically showing a state in which a control printed circuit board according to the present invention is connected to four liquid crystal display panels.

FIG. 2 is a schematic view of the first liquid crystal display panel of FIG. 1. FIG.

3 illustrates driving circuits formed on the control printed circuit board of FIG. 1;

<Brief description of the main parts of the drawing>

110a to 110d: first to fourth liquid crystal display panels

111: thin film transistor array substrate 112: color filter substrate

113: image display unit 120: control printed circuit board

122: gate tape carrier package 123: gate driver integrated circuit

131a to 131d: first to fourth data printed circuit boards

132: data driver integrated circuit 133: data tape carrier package

134: first EEPROM 136: second EEPROM

138: Third EEPROM 140: Fourth EEPROM

141: line-on-glass line

160a to 160d: first to fourth LVDS receiver

165: scaler 170: data alignment unit

175: control signal generator 190: I2C master

180a to 180d: first to fourth Mini LVDS buffers

Claims (8)

A plurality of liquid crystal panels each having a plurality of gate lines and a plurality of data lines arranged thereon; A plurality of data printed circuit boards having data driver integrated circuits connected to one side of each of the plurality of liquid crystal panels and driving a plurality of data lines arranged in the plurality of liquid crystal panels;  A plurality of memories formed on the plurality of data printed circuit boards and storing information including resolutions of corresponding liquid crystal panels connected to the plurality of data printed circuit boards; A control printed circuit board for selectively controlling and driving the plurality of liquid crystal panels; And And a plurality of cables for selectively connecting the plurality of data printed circuit boards and the control printed circuit board. The control printed circuit board recognizes whether the plurality of flexible cables are connected through a plurality of memories formed on a data printed circuit board electrically connected to the plurality of cables, and reads information from the connected plurality of memories. A liquid crystal display device for controlling and driving a plurality of liquid crystal panels connected to a control printed circuit board. According to claim 1, The control printed circuit board, A plurality of LVDS receivers receiving data from an external system; A master unit for selectively connecting to a plurality of memories formed on the plurality of data printed circuit boards and performing I2C communication; A scaler for processing data provided from the plurality of LVDS receivers according to the overall resolution of the liquid crystal panel corresponding to the number of the plurality of memories connected by using the I2C communication result of the master unit; A data alignment unit to align data according to the resolution of the liquid crystal panel by using the data processed by the scaler; And And a control signal generator configured to generate control signals according to the resolution of the liquid crystal panel by using the data processed by the scaler. According to claim 1, And the memory comprises an EEPROM. The method of claim 2, And the scaler of the control printed circuit board controls a liquid crystal panel having a resolution of up to 3840 * 2160. According to claim 1, And each of the plurality of liquid crystal panels has a resolution of 1920 * 1080. According to claim 1, And a plurality of connection terminals to which one end of the plurality of cables is connected to the control printed circuit board. According to claim 1, And a connection terminal for connecting the other end of the plurality of cables to each of the plurality of data printed circuit boards. According to claim 1, The cable comprises a flexible flat cable (FCC).

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