KR101178713B1 - Liquid crystal display device and driving circuit thereof for note-sized personal computer - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a driving circuit thereof, and more particularly to a liquid crystal display device for a notebook computer and a driving circuit thereof for supplying power to each memory of the liquid crystal display driving circuit portion of a notebook computer to perform normal image display. will be.

 To this end, the present invention is a driving circuit of a liquid crystal display device that exchanges data and receives a first power through a computer system and a connector, and performs operation of storing screen adjustment data to be transmitted to the computer system and receiving a first power. A timing controller having a register; A first memory configured to receive the first power and operate to store screen adjustment data provided to the register; A driving circuit of a liquid crystal display device for a notebook computer and a liquid crystal display device having the same, the second power source is operated under the first power and stores the EDID data provided to the computer system. By providing the information required for the screen display at the initial startup to the notebook computer system smoothly, it provides the advantage of performing the normal screen display at the initial startup of the notebook computer.

Description

Liquid crystal display device and driving circuit thereof for notebook computer

1 is a block diagram showing the configuration of a liquid crystal display drive circuit 1 for a notebook computer.

2 is a block diagram showing the configuration of a liquid crystal display driving circuit 100 for a notebook computer according to a first embodiment of the present invention.

3 is a block diagram showing the configuration of a liquid crystal display driving circuit 200 for a notebook computer according to a second embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

110: first memory 120: timing controller

122,124: first and second circuit section 126: register

130: second memory 140: connector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a driving circuit thereof, and more particularly to a liquid crystal display device for a notebook computer and a driving circuit thereof for supplying power to each memory of the liquid crystal display driving circuit portion of a notebook computer to perform normal image display. will be.

Recently, notebook computers (hereinafter, referred to as notebook computers) have been widely used due to the thinner and lighter display devices.

The notebook computer is small but its function is the same as that of the desktop computer, and it has an advantage of displaying a high quality image compared to the CRT monitor by mounting a liquid crystal display device.

Such notebook computers are gradually miniaturized and thinned, and accordingly, researches on the accessories embedded in the notebook computers and the thinning of the liquid crystal display device are actively conducted.

Liquid crystal display devices widely used as display devices for notebook computers use thin film transistors (TFTs) as switch elements, and have advantages of small size, thinness, and low power consumption. , Audio / video equipment.

FIG. 1 is a block diagram showing the configuration of a liquid crystal display drive circuit 1 for a notebook computer, and shows a connection configuration with a power supply line and a data communication line.

According to the configuration, in driving the liquid crystal display, a first memory 10 storing data necessary for implementing an adaptive dynamic image control (AI) function, and image data input from an external device are processed. A timing controller 20 having a plurality of circuits 22 and 24 for generating a plurality of control signals and a register 26 for storing data retrieved from the first memory 10; Extended Display Identification Data) includes a second memory 30 for providing display information.

The drive circuit 1 is connected to the notebook computer system through the connector 40 to receive data communication and power.

The first memory 10 and the second memory 30 are electrically erasable and programmable read only memory (EEPROM), respectively, and the first memory 10 performs I2C communication with the timing controller 20 when power is applied. The adjustment data stored and executed are provided to the register 26, and the adjustment data provided to the register 26 is transmitted to the notebook computer system through the connector 40. The illustrated MSDA (multi-serial data) and MSCL (multi-serial clock) respectively represent data and clock signals transmitted from the first memory 10 to the timing controller 20 via I2C communication, and SDA (serial data) and SCL, respectively. (Serial Clock) indicates data and clock signals transmitted through the connector 40 between the register 26 and the second memory 30 and the notebook computer system.

The second memory 30 provides EDID display information stored to the notebook computer system through the connector 40 when power is applied, and the notebook computer system provided with the EDID display information refers to the transmitted EDID display information. Set the resolution, display timing, and so on.

The liquid crystal display driving circuit unit 1 for the notebook computer having the above-described configuration is designed such that power applied to the timing controller 20 and the second memory 30 is applied from different power sources. When the timings are different from each other, the timing controller 20 and the second memory 30 are driven at different timings during initial startup of the notebook computer.

That is, the first memory 10 and the timing controller 20 are supplied with power from the (VCC) terminal and the second memory 30 is supplied with power from the (Vedid) terminal. When on), power is supplied to the first memory 10 and the timing controller 20 through the (VCC) stage after power is applied to the second memory 30 through the (Vedid) stage. At this time, the notebook computer system should receive the data stored in the register 26 and the second memory 30 and use it as data for screen display. The timing controller 20 has a time interval in which power is not applied. Due to this, data stored in the first memory 10 is not transmitted from the register 26, so an abnormal screen is displayed when the initial screen is displayed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and performs normal screen display during initial startup of a notebook computer through simultaneous application of a timing controller and a memory element used in a drive circuit of a notebook computer liquid crystal display device. The purpose is to.

The present invention to achieve the above object,

A drive circuit for a liquid crystal display device that exchanges data and receives a first power through a computer system and a connector, the timing including a register for storing screen adjustment data to be transmitted to the computer system and operating under a first power supply. Controller; A first memory configured to receive the first power and operate to store screen adjustment data provided to the register; The present invention provides a driving circuit for a liquid crystal display device for a notebook computer, which is operated under the first power source and includes a second memory for storing EDID data provided to the computer system.

The first memory and the second memory are EPIROM.

The first power source is characterized in that the voltage between 1.8 ~ 6.0 volts.

The first memory may perform I2C communication with the timing controller to provide data to the register.

The register and the second memory may each perform serial communication with the computer system to provide data.

The timing controller may further include a plurality of circuit units receiving the first power or the second power applied through the connector.

The plurality of circuit units may include a memory for storing image data, a clock generation circuit, and a control signal generation circuit.

The present invention also provides a timing controller having a register for receiving data exchange and a first power supply through a computer system and a connector, storing data for screen adjustment to be transmitted to the computer system, and operating with a first power supply. A first memory for operating the first power and storing the screen adjustment data provided to the register, and a second memory for operating the first power and storing the EDID data provided to the computer system. A driving circuit for a liquid crystal display device comprising; A liquid crystal display device for a notebook computer including a liquid crystal panel in which a plurality of liquid crystal pixels are formed and an image is displayed on each liquid crystal pixel through the driving circuit for the liquid crystal display device is provided.

FIG. 2 is a block diagram showing a configuration of a liquid crystal display driving circuit 100 for a notebook computer according to a first embodiment of the present invention, and shows a connection configuration between a power supply line and a data communication line.

According to the configuration, in driving the liquid crystal display, a first memory 110 storing data necessary for implementing an adaptive dynamic image control (AI) function and image data input from an external device are processed and output. And a plurality of circuit parts 122 and 124 for generating a plurality of control signals for controlling the operation of the driver IC for driving the liquid crystal panel and a register 126 for storing data loaded from the first memory 110. One timing controller 120 and a second memory 130 for providing Extended Display Identification Data (EDID) display information to a computer system.

The driving circuit 100 is connected to the notebook computer system through the connector 140 to receive data communication and power.

The first memory 110 and the second memory 130 are electrically erasable and programmable read only memory (EEPROM), respectively, and the first memory 110 performs I2C communication with the timing controller 120 when power is applied. Performing adjustments and storing the stored adjustment data to the register 126, and the adjustment data provided to the register 126 is transferred to the notebook computer system through the connector 140. The illustrated MSDA (multi-serial data) and MSCL (multi-serial clock) represent data and clock signals transmitted from the first memory 110 to the timing controller 120 through I2C communication, respectively, SDA (serial data) and SCL. (Serial Clock) indicates data and clock signals transmitted through the register 140 between the register 126 and the second memory 130 and the notebook computer system.

The second memory 130 provides EDID display information stored to the notebook computer system through the connector 140 when power is applied, and the notebook computer system provided with the EDID display information refers to the transmitted EDID display information. Set the resolution, display timing, and so on.

The liquid crystal display device driving circuit for a notebook computer according to the first embodiment of the present invention having the above configuration uses only one first power supply (Vedid) supplied from the notebook computer system through the connector 140. It is characteristic to operate each component of ().

In particular, the first and second memories 110 and 130 and the first and second circuit units 122 and 124 and the register 126 of the timing controller 120 all have a same voltage level because the required driving voltages are similar voltage levels. Even if it is driven by using, there is no problem in operation. At this time, the first power source (Vedid) is used within a voltage of 1.8V ~ 6.0V, in particular 3.3V.

As such, when each component of the driving circuit 100 is simultaneously supplied with power from the same power source, all the component circuits are driven at the same time. Therefore, the screen adjustment-related data stored in the first memory 110 at the initial startup of the notebook computer are The EDID display information stored in the second memory 130 is also transmitted to the notebook computer system through the connector 140 while being transferred to the register 126 and delivered to the notebook computer system through the connector 140. The notebook computer system has an advantage in that it is possible to smoothly acquire information required for display at the time of initial start-up at the required timing so that driving for display is normally performed.

FIG. 3 is a block diagram showing the configuration of a liquid crystal display driving circuit 200 for a notebook computer according to a second embodiment of the present invention, showing a connection configuration between a power supply line and a data communication line. In addition, for the same configuration as in FIG. 2 of the above-described first embodiment, the first embodiment is referred to, and detailed description thereof is omitted.

A liquid crystal display driving circuit for a notebook computer according to a second embodiment of the present invention having the above configuration includes a first power supply (Vedid) supplied from the notebook computer system through the connector 240 and a second power supply through the connector. Each component of the driving circuit 200 is operated by using a power supply VCC, and in particular, the first and second memories 210 and 230 and the register 226 of the timing controller 220 are the same power source (that is, the first power source). It is characterized by driving with one power source (Vedid). In particular, since the driving voltages of the first and second memories 210 and 230 and the register 226 of the timing controller 220 are all at similar voltage levels, the operation of the first and second memories 210 and 230 may be performed using a single power source. The first power supply (Vedid) is used within a voltage of 1.8V ~ 6.0V, in particular 3.3V.

In addition, the illustrated first and second circuit units 222 and 224 are circuit units that provide functions such as processing image data input from an external device and generating a plurality of control signals, and do not store data for image display. Therefore, even if the power is applied late at the initial startup, the initial screen display is not affected.

As such, when the configuration related to data transmission among the configuration of the driving circuit 200 is configured to receive power simultaneously from the same power source, the registers of the first and second memories 210 and 230 and the timing controller 220 are used. In operation 226, the notebook computer operates simultaneously at the initial startup of the notebook computer, and thus, the screen adjustment related data stored in the first memory 210 is transferred to the register 226 and is transferred to the notebook computer system through the connector 240. At the same time, EDID display information stored in the second memory 230 is also transferred to the notebook computer system through the connector 240, so that the notebook computer system can smoothly acquire information necessary for screen display at the initial start-up at the required timing. In this way, the driving for displaying the screen can be normally performed.

As described above, the liquid crystal display device driving circuit for a notebook computer according to the present invention described in the first and second embodiments is driven by simultaneously applying power to a circuit unit that provides data necessary for screen display during initial startup of the notebook computer. It provides the information required for the screen display during the initial startup of the notebook computer smoothly to the notebook computer system side, thereby providing the advantage of performing the normal screen display during the initial startup of the notebook computer.

Claims (8)

A driving circuit of a liquid crystal display device which receives data and receives a first power through a computer system and a connector, A timing controller having a register configured to store screen adjustment data to be transmitted to the computer system and operate under a first power source; A first memory configured to receive the first power and operate to store screen adjustment data provided to the register; A second memory configured to operate under the first power and store EDID data provided to the computer system; Driving circuit of the liquid crystal display device for a notebook computer comprising a The method according to claim 1, The first memory and the second memory drive circuit of the liquid crystal display device for a notebook computer, characterized in that the EEPROM (EEPROM) The method according to claim 1, The first power supply is a drive circuit of a liquid crystal display device for a notebook computer, characterized in that the voltage between 1.8 ~ 6.0 volts. The method according to claim 1, Wherein the first memory performs I2C communication with the timing controller to provide data to the register. The method according to claim 1, Wherein the register and the second memory each perform serial communication with the computer system to provide data. The method according to claim 1, The timing controller, And a plurality of circuit parts configured to receive the first power source or the second power source applied through the connector. The method of claim 6, The plurality of circuits include a driving circuit of a liquid crystal display device for a notebook computer, characterized in that it comprises a memory for storing image data, a clock generation circuit, a control signal generation circuit. A timing controller having a register for exchanging data and receiving a first power through a computer system and a connector, storing a screen adjustment data to be transmitted to the computer system, and operating with a first power; A liquid crystal display including a first memory configured to operate under the control of the electronic device and to store the screen adjustment data provided to the register, and a second memory configured to operate under the first power and to store the EDID data provided to the computer system. A driving circuit for; A liquid crystal panel in which a plurality of liquid crystal pixels are formed and an image is displayed on each liquid crystal pixel through the driving circuit for the liquid crystal display device. LCD display device including a

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