KR100551728B1 - Liquid crystal display device can automatic of manufacturing of liquid crystal monitor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device that can automate the manufacture of a liquid crystal monitor. Standardized parts irrespective of the size of the liquid crystal display or the characteristics of the panel when manufacturing the liquid crystal monitor by controlling the control signals necessary for driving the liquid crystal display by loading the contents stored in the memory into the multi-scan circuit. It is possible to improve productivity through automation at the time of production.

Description

Liquid crystal display that can automate the manufacture of liquid crystal monitors {LIQUID CRYSTAL DISPLAY DEVICE CAN AUTOMATIC OF MANUFACTURING OF LIQUID CRYSTAL MONITOR}

1 is a block diagram schematically showing the configuration of a conventional liquid crystal monitor device;

Figure 2 is a block diagram schematically showing the configuration of another conventional liquid crystal monitor device

3 is a block diagram schematically showing the configuration of a liquid crystal display device capable of automating the manufacture of a liquid crystal monitor of the present invention;

4 is a circuit diagram illustrating a configuration of a reference voltage and a driving voltage generator shown in FIG. 3.

5 is a flow chart briefly showing the manufacturing procedure of the LCD monitor device of the present invention.

Explanation of symbols on the main parts of the drawings

100: liquid crystal monitor unit 110: external program supply unit

120: interface circuit

122: analog and digital signal conversion circuit

124: multi-scan circuit section 126: memory section

128: power supply circuit

130: source and gate drive driving circuit unit

132: timing controller

134: reference voltage and driving voltage generator 140: liquid crystal display panel

142: source drive unit 144: gate drive unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device capable of automating the manufacture of a liquid crystal monitor. Particularly, the production of liquid crystal monitors can be standardized regardless of the size of the liquid crystal display or the characteristics of the panel. The present invention relates to a liquid crystal display device capable of automating the manufacture of a liquid crystal monitor capable of improving the quality of the liquid crystal display.

In general, the liquid crystal display device is configured with an interface circuit for converting a signal input from the liquid crystal module and the computer system according to the liquid crystal module.

1 is a block diagram schematically showing the configuration of a conventional liquid crystal monitor device.

As shown in the drawing, a conventional liquid crystal monitor device includes a liquid crystal display panel 11 and a source drive 9 and a gate drive 10 capable of driving the display panel. And a reference voltage for generating a reference voltage and a driving voltage to the timing controller 7 driving the source drive 9 and the gate drive 10, and the source drive 9 and the gate drive 10. And a source and gate drive driving circuit section 6 composed of a driving voltage generating section 8.

In addition, an interface circuit 2 for converting a signal input from the computer system 1 to the liquid crystal module is further provided. The interface circuit section 2 is composed of an analog and digital signal conversion circuit section 3 for converting an analog signal into a digital signal, a multiscan circuit section 4 and a power supply circuit section 5.

2 is a block diagram schematically showing the configuration of another conventional liquid crystal monitor device.

The conventional liquid crystal monitor device shown in FIG. 2 is composed of a computer system 21, an interface circuit section 22, a source drive 29, a gate drive 30, and a liquid crystal display panel 31. As shown in FIG. At this time, the source drive 29 and the gate drive 30 are controlled to drive the liquid crystal display panel 31.

The interface circuit 22 may include a timing controller 27 for driving the source drive 29 and the gate drive 30, and a reference voltage between the source drive 29 and the gate drive 30. A reference voltage and a driving voltage generator 28 for generating a driving voltage, an analog and digital signal conversion circuit part 3 for converting a signal input from the computer system 1 into a liquid crystal module, and a multi-scan circuit part ( 4) and a power supply circuit section 5 are provided.

In the conventional liquid crystal display device configured as described above, the reference voltage and the driving voltage are applied in accordance with the size and characteristics of the liquid crystal display panel by changing the component values of the circuit configured in the reference voltage and the driving voltage generator 8.

However, in this case, according to the size and characteristics of the liquid crystal display panel, the components of the circuit constituting the reference voltage and the driving voltage have different disadvantages. In addition, when a problem occurs when manufacturing a liquid crystal monitor, there are disadvantages in that a plurality of circuit diagrams configured differently according to the size and characteristics of the liquid crystal display panel are checked, and the accuracy of parts is checked again based on the checked circuit diagram. Due to these drawbacks, there is a problem that the productivity is lowered when manufacturing the liquid crystal monitor.

Accordingly, an object of the present invention is to solve the above problems, and an object of the present invention is to provide a control device (AVDD, Von, Voff, Vcom, GMA, etc.) necessary for driving a liquid crystal display in the process of manufacturing a liquid crystal monitor. Is stored in the memory of the driving circuit in the same way as the in-system program (ISP), and the contents stored in the memory are loaded into the multi-scan circuit (hereinafter, referred to as a 'scaler') to drive the LCD. By controlling the necessary control signals at the time of manufacture, it is possible to standardize the components regardless of the size of the liquid crystal display device or the characteristics of the panel in manufacturing the liquid crystal monitor, and to automate the production of liquid crystal monitors that can improve productivity through automation during production. It is to provide a liquid crystal display device that can be.

A liquid crystal display device capable of automating the manufacture of a liquid crystal monitor according to the present invention for achieving the above object,

A liquid crystal display panel composed of a plurality of liquid crystal cells;

A gate driver and a source driver for controlling the liquid crystal display panel to be driven;

A source and gate drive driver circuit unit controlling the gate drive unit and the source drive unit to be driven;

An external program supply unit that contains a program for controlling a control signal for driving the liquid crystal display panel; And

An interface circuit unit converting a signal received from the external program supply unit to a liquid crystal module and outputting the signal to the source and gate drive driving circuit unit;

Here, the interface circuit unit,

The analog and digital signal conversion circuit unit converting the analog signal received from the external program supply unit into a digital signal suitable for a liquid crystal module and outputting the digital signal to the source and gate drive driving circuit unit;

A memory unit for receiving a program from the external program supply unit and storing the program;

A multi-scan circuit unit which retrieves a control program from the memory unit, calculates it, and outputs a control signal to the analog and digital signal conversion circuit unit; And

And a power supply circuit unit for supplying power to the analog and digital signal conversion circuit unit, the multi-scan circuit unit, and the memory unit.

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

In addition, in all the drawings for demonstrating an embodiment, the thing with the same function uses the same code | symbol, and the repeated description is abbreviate | omitted.

3 is a block diagram schematically showing a liquid crystal monitor device and an external device according to the present invention.

The liquid crystal monitor device 100 according to the present invention includes an interface circuit unit 120, a source and gate drive driving circuit unit 130, a source drive unit 142, a gate drive unit 144, and a liquid crystal display panel 140. It is configured to include an external program supply unit 110.

First, the external program supply unit 110 includes a program for controlling a control signal required to drive the liquid crystal display panel 140.

The interface circuit unit 120 converts a signal received from the external program supply unit 110 to match the liquid crystal module. The interface circuit unit 120 having such a function includes an analog and digital signal conversion circuit unit 120, a multiscan circuit unit 124, a memory unit 126, and a power supply circuit unit 128.

Here, the analog and digital signal conversion circuit unit 120 converts the analog signal received from the external program supply unit 110 into a digital signal suitable for the liquid crystal module, thereby timing the source and gate drive driving circuit unit 130. Send to the controller unit 132.

The memory unit 126 receives a program from the external program supply unit 110 and stores the program.

In addition, the multi-scan circuit unit 124 retrieves a control program from the memory unit 126, calculates the control program, and sends a control signal to the analog and digital signal conversion circuit unit 120.

Finally, the power supply circuit unit 128 supplies power required for driving the analog and digital signal conversion circuit 120, the multiscan circuit unit 124, and the memory unit 126.

The source and gate drive driver circuit 130 includes a timing controller 132, a reference voltage, and a driving voltage generator 134.

Here, the timing controller 132 receives a signal from the analog and digital signal conversion circuit 122 and generates a signal for driving the source drive unit 142 and the gate drive unit 144.

The reference voltage and driving voltage generator 134 generates a reference voltage and a driving voltage to the source drive 29 and the gate drive 30.

The source drive 142 and the gate drive 144 control to drive the liquid crystal display panel 140.

As in the above configuration, the liquid crystal monitor device 100 of the present invention is composed of a liquid crystal display panel 140, a source drive unit 142 and a gate drive unit 144 capable of driving the display panel, the source drive unit 142, a timing controller 132 for driving the gate driver 144, and a reference voltage and a driving voltage generator 134 for generating a reference voltage and a driving voltage.

In addition, the analog and digital signal conversion circuit unit 120 and the multi-scan circuit unit 124 for converting the signal input from the computer system according to the timing control signal for converting the liquid crystal module, and the analog and digital signal A power supply circuit unit 128 for driving the conversion circuit unit 120 and the multi-scan circuit unit 124 is provided.

In addition, an external program supply unit 110 incorporating a program necessary to control a control signal required to drive the liquid crystal display panel 140 and a memory unit 126 capable of receiving and storing a program from the apparatus 110 are provided. Equipped.

In addition, a circuit capable of generating a control signal from an output of the multi-scan circuit unit 124 by calculating a control program from the memory unit 126 and calculating the multi-scan circuit unit 124.

4 is a circuit diagram illustrating the configuration of the reference voltage and driving voltage generator 134 shown in FIG. 3.

The reference voltage and driving voltage generator 134 includes an IC chip 301 having a PWM output for outputting a pulse waveform, and a resistor connected between an output terminal of the IC chip 301 having the PWM output and a node Nd1. 302, a capacitor 303 connected between the node Nd1 and the ground potential GND, a reference voltage generator 304 for generating a reference voltage, and an output from the reference voltage generator 304. The operational amplifier 305 for receiving the reference voltage and the pulse waveform transmitted to the node Nd1 and amplifying and outputting the signal by the difference, and a resistor connected between the terminal for receiving the input voltage and the node Nd2. 307, an NPN type bipolar transistor 306 connected between the node Nd2 and the ground potential GND and switched by an output signal of the operational amplifier 305, and driven with the node Nd2. A diode 308 connected between an output terminal for outputting a voltage and the output terminal and a ground potential ( And a capacitor 309 connected between the GNDs.

As shown, the reference voltage and driving voltage generator 134 is turned on / off in accordance with the inductance 307 to prevent the reverse current to the input terminal and the voltage applied to the base NPN type bipolar transistor 306 is provided.

The pulse waveform generated by the switching operation of the NPN-type bipolar transistor 306 is rectified by the rectifier circuit using the diode 308 and the capacitor 309 to generate a driving voltage necessary for the liquid crystal display.

The output of the IC chip 301 having the PWM output is made into a DC voltage by using the resistor 302 and the capacitor 303. The DC voltage is input to the operational amplifier 305 together with the waveform generated by the reference voltage generator 304, and the operational amplifier 305 compares these two signals and amplifies the signal amplified by the difference. It is applied to the base of the NPN type bipolar transistor 306. The difference is equal to the absolute value of the difference obtained by subtracting the magnitude of the DC voltage from the magnitude of the reference voltage.

At this time, by controlling the IC chip 301 having the PWM output to output a pulse waveform to adjust the reference voltage of the operational amplifier 305, the switching waveform of the NPN-type bipolar transistor 306 is adjusted Can be. Thereby, the output drive voltage can be adjusted.

5 is a flow chart briefly showing the manufacturing procedure of the liquid crystal monitor device of the present invention.

First, a component is mounted on a standardized driving board regardless of the size and characteristics of the liquid crystal display (step S401) and a necessary control program is input using an external device (step S402). After reading the input data to check the accuracy of the input control program, if it is correct, proceed to the next process, and if it is incorrect, input the control program again (step S403).

Using the identified driving board, the required liquid crystal display device is driven, and the power required for driving is again checked.

In addition, at this time, it is determined whether the required power supply is correct to determine passing and reworking (S404). Passing the driving board is assembled with the liquid crystal display to produce a liquid crystal monitor (S405 step).

As described above, according to the liquid crystal display device capable of automating the manufacturing of the liquid crystal monitor according to the present invention, the control elements (AVDD, Von, Voff, Vcom, GMA) required to drive the liquid crystal display in the process of manufacturing the liquid crystal monitor Etc.) is stored in the memory of the driving circuit through the same method as an in-system program (ISP) from an external device, and the contents stored in the memory are loaded into a multi-scan circuit (hereinafter, referred to as a 'scaler'). By controlling the control signals required for driving the display device, the parts can be standardized regardless of the size of the liquid crystal display device or the characteristics of the panel at the time of manufacturing the liquid crystal monitor, and the productivity can be improved through automation during production.

In addition, preferred embodiments of the present invention are disclosed for the purpose of illustration, those skilled in the art will be able to various modifications, changes, additions, etc. within the spirit and scope of the present invention, these modifications and changes should be seen as belonging to the following claims. something to do.

Claims (3)

A liquid crystal display panel composed of a plurality of liquid crystal cells; A gate driver and a source driver for controlling the liquid crystal display panel to be driven; A source and gate drive driver circuit unit controlling the gate drive unit and the source drive unit to be driven; An external program supply unit that contains a program for controlling a control signal for driving the liquid crystal display panel; And An interface circuit unit converting a signal received from the external program supply unit to a liquid crystal module and outputting the signal to the source and gate drive driving circuit unit; Here, the interface circuit unit, The analog and digital signal conversion circuit unit converting the analog signal received from the external program supply unit into a digital signal suitable for a liquid crystal module and outputting the digital signal to the source and gate drive driving circuit unit; A memory unit for receiving a program from the external program supply unit and storing the program; A multi-scan circuit unit which retrieves a control program from the memory unit, calculates it, and outputs a control signal to the analog and digital signal conversion circuit unit; And And a power supply circuit unit for supplying power to the analog and digital signal conversion circuit unit, the multi-scan circuit unit, and the memory unit. The method of claim 1, The source and gate drive driving circuit unit, A timing controller unit receiving a signal from the analog and digital signal conversion circuit unit and generating a signal for driving the source drive unit and the gate drive unit; And And a reference voltage and a driving voltage generator for generating a reference voltage and a driving voltage to the source drive unit and the gate drive unit. The method of claim 2, The reference voltage and the driving voltage generator, An IC chip having a PWM output for outputting a pulse waveform; A resistor connected between an output terminal of the IC chip and a first node; A first capacitor connected between the first node and a ground potential GND; A reference voltage generator for generating a reference voltage; The reference voltage output from the reference voltage generator and the pulse waveform are transmitted to the first node to receive the DC voltage generated by the resistor and the first capacitor, and subtract the magnitude of the DC voltage from the magnitude of the reference voltage. An operational amplifier for amplifying and outputting the signal by the absolute value of the difference; A second resistor connected between the terminal receiving the input voltage and the second node; An NPN type bipolar transistor connected between the second node and a ground potential GND and switched by an output signal of the operational amplifier; A diode connected between the second node and an output terminal for outputting a driving voltage; And And a second capacitor connected between the output terminal and the ground potential (GND).

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