KR20110076015A - Liquid crystal display device - Google Patents

Abstract

PURPOSE: A liquid crystal display device is provided to accurately drive a liquid crystal panel regardless of a model by driving a data drive integrated circuit using a gamma reference voltage and a common voltage. CONSTITUTION: A liquid crystal panel displays an image. A plurality of data drive integrated circuit supplies image data to data lines of the liquid crystal panel. The liquid crystal display device includes one or more data drive integrated circuits and generates a plurality of gamma reference voltages(GMA1-GMAn). A gamma reference voltage generator(GG) supplies gamma reference voltages to each data drive integrated circuit(D-IC).

Description

[0001] LIQUID CRYSTAL DISPLAY DEVICE [0002]

The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device capable of accurately driving a liquid crystal panel.

In order to drive the liquid crystal panel to which the data drive integrated circuits are connected, a common voltage and a plurality of gamma reference voltages for driving the data drive integrated circuits are required. Conventionally, the common voltage and the plurality of gamma reference voltages have been provided from a gamma reference voltage generator mounted on a control printed circuit board.

However, since the common voltage and the gamma reference voltages provided from the gamma reference voltage generator mounted on the control printed circuit board are not optimized signals for data drive integrated circuits having different characteristics for each model of the liquid crystal display device, the conventional voltage and gamma reference voltages are not optimized. The gamma reference voltage generator of the present invention has a problem in that it is difficult to accurately drive the LCD for every model.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and includes a gamma reference voltage generator configured to generate a plurality of gamma reference voltages and a common voltage optimized therein in a data drive integrated circuit. An object of the present invention is to provide a liquid crystal display device capable of accurately driving a liquid crystal panel regardless of a model by driving data drive integrated circuits using gamma reference voltages and a common voltage from a reference voltage generator.

According to an aspect of the present invention, a liquid crystal display device includes: a liquid crystal panel displaying an image; A plurality of data drive integrated circuits supplying image data to data lines of the liquid crystal panel; And a gamma reference voltage generator configured to generate a plurality of gamma reference voltages and to supply the gamma reference voltages to each data drive integrated circuit.

The gamma reference voltage generator includes m gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each gamma circuit is embedded in each data drive integrated circuit; In addition, n / m gamma reference voltages output from each gamma circuit are supplied to each data drive integrated circuit.

The number of data drive integrated circuits and the number of gamma circuits are the same; In addition, one gamma circuit is embedded in each data drive integrated circuit.

The n gamma reference voltages include n / 2 positive gamma reference voltages greater than a common voltage and n / 2 negative gamma reference voltages less than the common voltage; The gamma circuit embedded in any one of the plurality of data drive integrated circuits receives the common voltage from the outside and transfers the common voltage to each of the other gamma circuits.

A control printed circuit board mounted with a timing controller for supplying image data to the data drive integrated circuits; At least one source printed circuit board connected by the control printed circuit board and at least one connection portion; Each of the plurality of data drive integrated circuits is mounted in a Tape Carrier Package; The source printed circuit board and the liquid crystal panel are connected to each other by the tape carrier packages; The common voltage is supplied to a gamma circuit of a data drive integrated circuit which is located closest to the connection unit among the data drive integrated circuits.

M data input pads for receiving n gamma reference voltages from the outside and m clock input pads for receiving a clock signal from the outside are further formed on the source printed circuit board; A pair of data input pads and clock input pads are connected to each gamma circuit through data transmission lines and clock transmission lines formed in each tape carrier package.

A common input pad is further formed on the source printed circuit board to receive a common voltage from the outside; The common input pad may be connected to a gamma circuit in a data drive integrated circuit located closest to the connection portion through a common transmission line formed in one tape carrier package.

In addition, the liquid crystal display device according to the present invention for achieving the above object, the liquid crystal panel for displaying an image; A plurality of data drive integrated circuits supplying image data to data lines of the liquid crystal panel; A control printed circuit board mounted with a timing controller for supplying image data to the data drive integrated circuits; A first source printed circuit board connected by the control printed circuit board and a first connection unit; A second source printed circuit board connected by the control printed circuit board and a second connection unit; A tape carrier package having each data drive integrated circuit mounted thereon; Some of the tape carrier packages connect the first source printed circuit board and the liquid crystal panel to each other, and the remaining tape carrier packages connect the second source printed circuit board and the liquid crystal panel to each other; At least one data drive connected to the first source printed circuit board, wherein a first gamma reference voltage generator generates a plurality of gamma reference voltages and supplies them to data drive integrated circuits connected to the first source printed circuit board. Embedded in integrated circuits; At least one data drive connected to the second source printed circuit board, wherein a second gamma reference voltage generator generates a plurality of gamma reference voltages and supplies them to data drive integrated circuits connected to the second source printed circuit board. Characterized in that integrated circuit.

The first gamma reference voltage generator includes m first gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each of the first gamma circuits is separately embedded in a data drive integrated circuit connected to the first source printed circuit board; The n / m gamma reference voltages output from each of the first gamma circuits are supplied to each data drive integrated circuit connected to the first source printed circuit board.

The second gamma reference voltage generator includes m second gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each of the second gamma circuits is separately contained in a data drive integrated circuit connected to the second source printed circuit board; The n / m gamma reference voltages output from each second gamma circuit are supplied to each data drive integrated circuit connected to the second source printed circuit board.

The liquid crystal display device according to the present invention has the following effects.

According to the present invention, a gamma reference voltage generator configured to generate a plurality of gamma reference voltages and a common voltage optimized therein in a data drive integrated circuit includes a gamma reference voltage and a common voltage from the embedded gamma reference voltage generator. By driving the data drive integrated circuits, the LCD panel can be driven accurately regardless of the model.

1 is a view showing a liquid crystal display device according to an embodiment of the present invention.

A liquid crystal display device according to an embodiment of the present invention, as shown in Figure 1, the liquid crystal panel (PN) for displaying an image; A plurality of data drive integrated circuits D-IC supplying image data to data lines DL of the liquid crystal panel PN; A control printed circuit board (C-PCB) mounted with a timing controller for supplying image data to the data drive integrated circuits (D-ICs); And a source printed circuit board S-PCB connected by the control printed circuit board C-PCB and a connection part CN.

Each of the plurality of data drive integrated circuits (D-ICs) is mounted in a tape carrier package (TCP), and the source printed circuit board (S-PCB) and the data carrier are connected by tape carrier packages (TCP). The liquid crystal panel PN is connected to each other.

The liquid crystal panel PN includes a plurality of gate lines GL and a plurality of data lines DL that cross each other. Pixels are formed in pixel areas defined by regions where each data line DL and gate line GL intersect.

The data drive integrated circuits D-IC convert the digital image data from the timing controller into analog pixel voltages corresponding thereto and supply them to the data lines DL. To this end, each data drive integrated circuit D-IC is supplied with gamma reference voltages and divides the gamma reference voltages using an internal resistance string to generate a plurality of gray voltages. The gray voltage corresponding to the digital image data among the generated gray voltages is selected as a pixel voltage and supplied to the data line DL.

FIG. 2 is a diagram illustrating one data drive integrated circuit D-IC in FIG. 1.

According to the present invention, a gamma reference voltage generator (GG) for generating gamma reference voltages is embedded in the data drive integrated circuit (D-IC). 2 illustrates an example in which a gamma reference voltage generator GG is embedded in one data drive integrated circuit D-IC.

The gamma reference voltage generation unit GG generates a plurality of gamma reference voltages GMA1 to GMAn, and supplies these gamma reference voltages GMA1 to GMAn to each data drive integrated circuit D-IC. For example, the gamma reference voltage generation unit GG generates n gamma reference voltages GMA1 to GMAn and n generates gamma reference voltages GMA1 to GMAn. Supply to all data drive integrated circuits (D-IC). These n gamma reference voltages GMA1 to GMAn include n / 2 positive gamma reference voltages and n / 2 negative gamma reference voltages. The positive gamma reference voltage means a voltage larger than the common voltage Vcom, and the negative gamma reference voltage means a voltage smaller than the common voltage Vcom. The gamma reference voltage generator (GG) needs a common voltage (Vcom) to generate positive and negative gamma reference voltages. For this purpose, the gamma reference voltage generator (GG) uses a common voltage ( Vcom) is supplied more.

A data input pad DTP for receiving n gamma reference voltages GMA1 to GMAn from the outside and a clock input pad CKP for receiving a clock signal from the outside are formed on the source printed circuit board S-PCB. It is. The data input pad DTP is connected to the gamma reference voltage generator GG through a data transmission line DTL formed on a tape carrier package TCP, and the clock input pad CKP is connected to the tape carrier package TCP. Is connected to the gamma reference voltage generator GG through a clock transmission line CKL formed at In addition, the source printed circuit board S-PCB is provided with a common input pad CVP for receiving a common voltage Vcom from the outside, and the common carrier pad TCP is provided with the common input pad CVP. Is connected to the gamma voltage generation unit GG to form a common input line CVL.

Gamma reference voltages GMA1 to GMAn optimized for this data drive integrated circuit D-IC from the outside through the data input pad DTP, the clock input pad CKP, and the common input pad, and the common voltage Vcom. May be supplied to the gamma reference voltage generator (GG). The optimized gamma reference voltages GMA1 to GMAn and the common voltage Vcom are digitized values.

FIG. 3 is a diagram showing data drive integrated circuits (D-ICs) according to a first embodiment of the present invention. As shown in FIG. Only the first data drive integrated circuit (D-IC) located has a gamma reference voltage generator (GG). The gamma reference voltage generation unit GG supplies n gamma reference voltages and a common voltage Vcom to the first to fourth data drive integrated circuits D-IC.

4 is a diagram illustrating data drive integrated circuits (D-ICs) according to a second exemplary embodiment of the present invention.

The data drive integrated circuits D-ICs according to the second embodiment of the present invention include a plurality of gamma circuits GC, as shown in FIG. 4. The number of gamma circuits GC and the number of data drive integrated circuits D-IC are the same. The gamma circuits GC are generated by dividing n gamma reference voltages GMA1 to GMAn. That is, assuming that the gamma circuits GC are m, each gamma circuit GC generates n / m gamma reference voltages. For example, as shown in FIG. 4, when the gamma circuits GC are four and the gamma reference voltages are twelve, each gamma circuit GC generates three different gamma reference voltages. Here, the twelve gamma reference voltages include six positive gamma reference voltages and six negative gamma reference voltages.

In particular, the gamma circuit GC in the data drive integrated circuit D-IC closest to the connection CN among the gamma circuits GC is further supplied with the common voltage Vcom. Each gamma circuit GC supplies gamma reference voltages generated therefrom to other gamma circuits GC. In addition, the gamma circuit GC further receiving the common voltage Vcom among the gamma circuits GC supplies the common voltage Vcom to the remaining gamma circuits GC. Accordingly, all gamma circuits GC receive n gamma reference voltages GMA1 to GMAn and a common voltage Vcom. Each gamma circuit GC supplies n gamma reference voltages GMA1 to GMAn to the data drive integrated circuit D-IC therein. Each data drive integrated circuit D-IC generates a plurality of gray voltages using the n gamma reference voltages GMA1 to GMAn.

The source printed circuit board S-PCB has m data input pads DTP for receiving n gamma reference voltages GMA1 to GMAn and m clock input pads for receiving a clock signal from the outside. As the CKPs are formed, a pair of data input pads DTP and clock input pads CKP are connected to each other through a data transmission line DTL and a clock transmission line CKL formed in each tape carrier package TCP. It is connected to the gamma circuit (GC). In addition, a common input pad CVP is further formed on the source printed circuit board S-PCB, and the common input pad CVP is disposed closest to the connection part CN. Connected to the gamma circuit GC in the IC). In this case, the common input pad CVP is connected to the gamma circuit GC through a common transmission line formed in the tape carrier package TCP.

5 is a diagram illustrating data drive integrated circuits (D-ICs) according to a third exemplary embodiment of the present invention.

The liquid crystal display according to the third embodiment of the present invention has two source printed circuit boards S-PCB1 and S-PCB2 separated from each other. That is, the first and second data drive integrated circuits D-IC1 and D-IC2 are connected to the first source printed circuit board S-PCB1, and the second source printed circuit board S-PCB2 is connected to the first source printed circuit board S-PCB1. The third and fourth data drive integrated circuits D-IC3 and D-IC4 are connected. The first source printed circuit board S-PCB1 is connected to the control printed circuit board C-PCB through the first connection part CN1, and the second source printed circuit board S-PCB2 is connected to the second connection part. It is connected to the control printed circuit board (C-PCB) through (CN2).

The first gamma reference voltage generator GG1 is built in only one of the plurality of data drive integrated circuits D-IC1 and D-IC2 connected to the first source printed circuit board S-PCB1. The second gamma reference voltage generator GG2 is built in only one of the plurality of data drive integrated circuits D-IC3 and D-IC connected to the second source printed circuit board S-PCB2. The first and second gamma reference voltage generators GGG1 and GG2 have the same function as the gamma reference voltage generator GG shown in FIG. 2. That is, the first and second gamma reference voltage generators GG1 and GG2 generate n gamma reference voltages GMA1 to GMAn, respectively. Specifically, the first gamma reference voltage generator GG1 generates n gamma reference voltages GMA1 to GMAn and a common voltage Vcom, and connects them to the first source printed circuit board S-PCB1. It is supplied to the data drive integrated circuits D-IC1 and D-IC2. The second gamma reference voltage generator GG2 generates n gamma reference voltages GMA1 to GMAn and a common voltage Vcom, and connects them to the second source printed circuit board S-PCB2. Supply to integrated circuits D-IC3 and D-IC4. The first and second source printed circuit boards S-PCB1 and S-PCB2 are provided with a data input pad DTP, a clock input pad CKP and a common input pad CVP as described above.

6 is a diagram illustrating data drive integrated circuits (D-ICs) according to a fourth exemplary embodiment of the present invention.

As shown in FIG. 6, a gamma circuit GC is embedded in each of the data drive integrated circuits D-IC connected to the first and second source printed circuit boards S-PCB1 and S-PCB2. . Each gamma circuit GC in the m data drive integrated circuits D-IC connected to the first source printed circuit board S-PCB generates n / m gamma reference voltages and a second source printed circuit board. Each gamma circuit GC in m data drive integrated circuits D-IC connected to (S-PCB2) generates n / m gamma reference voltages. At this time, the gamma circuits GC in the data drives commonly connected to one source printed circuit board supply their respective gamma reference voltages. Accordingly, the gamma circuits GC connected to the first source printed circuit board S-PCB1 generate n gamma reference voltages. In addition, the gamma circuits GC connected to the second source printed circuit board S-PCB2 also generate n gamma reference voltages.

In particular, the gamma circuit in the data drive integrated circuit D-IC closest to the first connection part CN1 among the data drive integrated circuits D-IC connected to the first source printed circuit board S-PCB ( GC) is further supplied with a common voltage Vcom. The common voltage Vcom is supplied to the gamma circuit GC in another data drive integrated circuit D-IC connected to the first source printed circuit board S-PCB.

Similarly, the gamma circuit GC in the data drive integrated circuit D-IC closest to the second connection part CN2 among the data drive integrated circuits D-IC connected to the second source printed circuit board S-PCB2. ) Is further supplied with a common voltage (Vcom). The common voltage Vcom is supplied to the gamma circuit GC in another data drive integrated circuit D-IC connected to the second source printed circuit board S-PCB2.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a view showing a liquid crystal display device according to an embodiment of the present invention.

FIG. 2 illustrates one data drive integrated circuit in FIG. 1. FIG.

3 illustrates data drive integrated circuits according to a first embodiment of the present invention.

4 illustrates data drive integrated circuits according to a second embodiment of the present invention.

5 illustrates data drive integrated circuits according to a third embodiment of the present invention.

6 illustrates data drive integrated circuits according to a fourth embodiment of the present invention.

Claims (10)

A liquid crystal panel for displaying an image; A plurality of data drive integrated circuits supplying image data to data lines of the liquid crystal panel; And a gamma reference voltage generator configured to generate a plurality of gamma reference voltages and to supply the gamma reference voltages to each data drive integrated circuit. The method of claim 1, The gamma reference voltage generator includes m gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each gamma circuit is embedded in each data drive integrated circuit; And, And n / m gamma reference voltages output from each gamma circuit are supplied to each data drive integrated circuit. The method of claim 2, The number of data drive integrated circuits and the number of gamma circuits are the same; And, LCD device, characterized in that one gamma circuit is built into each data drive integrated circuit. The method of claim 2, The n gamma reference voltages include n / 2 positive gamma reference voltages greater than a common voltage and n / 2 negative gamma reference voltages less than the common voltage; And, And a gamma circuit built in any one of the plurality of data drive integrated circuits receives the common voltage from the outside and transfers the common voltage to each of the other gamma circuits. The method of claim 4, wherein A control printed circuit board mounted with a timing controller for supplying image data to the data drive integrated circuits; At least one source printed circuit board connected by the control printed circuit board and at least one connection portion; Each of the plurality of data drive integrated circuits is mounted in a Tape Carrier Package; The source printed circuit board and the liquid crystal panel are connected to each other by the tape carrier packages; And, And the common voltage is supplied to a gamma circuit of a data drive integrated circuit which is located closest to the connection of the data drive integrated circuits. The method of claim 5, M data input pads for receiving n gamma reference voltages from the outside and m clock input pads for receiving a clock signal from the outside are further formed on the source printed circuit board; And a pair of data input pads and clock input pads are connected to each gamma circuit through data transmission lines and clock transmission lines formed in each tape carrier package. The method of claim 6, A common input pad is further formed on the source printed circuit board to receive a common voltage from the outside; And the common input pad is connected to a gamma circuit in a data drive integrated circuit located closest to the connection through a common transmission line formed in one tape carrier package. A liquid crystal panel for displaying an image; A plurality of data drive integrated circuits supplying image data to data lines of the liquid crystal panel; A control printed circuit board mounted with a timing controller for supplying image data to the data drive integrated circuits; A first source printed circuit board connected by the control printed circuit board and a first connection unit; A second source printed circuit board connected by the control printed circuit board and a second connection unit; A tape carrier package having each data drive integrated circuit mounted thereon; Some of the tape carrier packages connect the first source printed circuit board and the liquid crystal panel to each other, and the remaining tape carrier packages connect the second source printed circuit board and the liquid crystal panel to each other; At least one data drive connected to the first source printed circuit board, wherein a first gamma reference voltage generator generates a plurality of gamma reference voltages and supplies them to data drive integrated circuits connected to the first source printed circuit board. Embedded in integrated circuits; At least one data drive connected to the second source printed circuit board, wherein a second gamma reference voltage generator generates a plurality of gamma reference voltages and supplies them to data drive integrated circuits connected to the second source printed circuit board. Liquid crystal display device, characterized in that embedded in the integrated circuit. The method of claim 8, The first gamma reference voltage generator includes m first gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each of the first gamma circuits is separately embedded in a data drive integrated circuit connected to the first source printed circuit board; And, And n / m gamma reference voltages output from each first gamma circuit are supplied to each data drive integrated circuit connected to the first source printed circuit board. The method of claim 8, The second gamma reference voltage generator includes m second gamma circuits for generating n gamma reference voltages of n (n is a natural number of two or more) by n / m; Each of the second gamma circuits is separately contained in a data drive integrated circuit connected to the second source printed circuit board; And, And n / m gamma reference voltages output from each second gamma circuit are supplied to each data drive integrated circuit connected to the second source printed circuit board.

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