KR100476390B1 - Stn lcd driving circuit for low voltage element - Google Patents

Abstract

In the low-voltage element styrene LED driving circuit of the present invention, by using a basic voltage generator, the effective information is processed into a low voltage signal, and the valid information is added to the basic voltage and outputted, whereby the driving stage can be configured as a low voltage element. It is an object of the present invention to provide an styrene LED drive circuit for low voltage devices.

In order to achieve the above object, the present invention provides an image data storage and signal control unit for storing image data in frame units and outputting image data signals and position control signals; Adjusting means for a low voltage element for receiving an image data signal and a position control signal from the image data storage and signal control unit, and adjusts the image data signal and the position control signal to a segment drive signal and a common drive signal for a low voltage element ; A segment driving circuit which receives the segment driving signal from the adjusting means for low voltage element and outputs it as an image signal; A common driving circuit which receives the common driving signal from the adjusting means for low voltage element and outputs it as a positioning signal; And an LCD panel which displays the image signal received from the segment driving circuit at a position designated by the positioning signal in the common driving circuit.

Description

STN LCD DRIVING CIRCUIT FOR LOW VOLTAGE ELEMENT}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an acetylene LCD drive circuit for low voltage devices, and more particularly to an styrene LED drive circuit for low voltage devices for driving using only a low voltage device in driving an styrene panel requiring a high voltage.

In general, a high voltage is required to drive the styrene LED, which requires a booster circuit. However, such boost circuits require large size transistors.

1 is a circuit diagram showing a conventional Estee yen LCD panel, each cell (Cell) is provided with a capacitor (C _LC), both terminals of the capacitor (C _LC) has segments (SEGMENT) electrode and the common (COMMON) to the electrode The LCD panels are connected to each other by driving the electrode terminals.

FIG. 2 is a circuit diagram illustrating a conventional ESTIE LCD driver circuit, in which the source terminal is connected to a first voltage V0 and receives a first common signal through a gate terminal. A PMOS transistor, a source terminal connected to the second voltage V1, a second PMOS transistor receiving a second common signal through a gate terminal, a drain terminal connected to a drain terminal of the first PMOS transistor, and a gate terminal A third common signal is input, a source terminal is connected to a first NMOS transistor connected to a fifth voltage V4, a drain terminal is connected to a drain terminal of a second PMOS transistor, and a fourth common signal is input to a gate terminal; And a common driving circuit 201 having a plurality of output terminals including a second NMOS transistor, the source terminal of which is grounded, and the source terminal of which is connected to the first voltage V0 and the first terminal as a gate terminal. A first PMOS transistor receiving a signal; a source terminal connected to a third voltage V2; a second PMOS transistor receiving a second segment signal through a gate terminal; and a drain terminal of a drain terminal of the first PMOS transistor. The first NMOS transistor is connected to the gate terminal, and the source terminal is connected to the fourth voltage V3, and the drain terminal is connected to the drain terminal of the second PMOS transistor. A segment driving circuit 202 having a plurality of output terminals including a second NMOS transistor, wherein the source terminal receives a fourth segment signal and is grounded, and specifies a position to display image data through a common electrode. An LCD panel 203 receives a control signal and receives an image data signal through a segment electrode.

The operation of the above-described conventional ETI LCD drive circuit will be described below with reference to FIG. 3.

The driving of the LCD panel 203 is performed through the segment driving stages SEG0, SEG1 and SEG2 of the segment driving circuit 202 and the common driving stages COM0, COM1 and COM2 of the common driving circuit 201. Among the driving waveforms output through the stages SEG0, SEG1, SEG2, COM0, COM1, and COM2, the partial driving sections d1 to d4 are taken as an example, and the common driving stages COM0, COM1, and COM2 are formed from VSS to V1 ( In practice, the voltage is driven between a voltage of about 10 V and the segment driving stages SEG0, SEG1, SEG2 are driven between voltages from V2 to V0 (actually less than 5 V).

That is, in the above-described conventional LCD panel driving circuit, although the driving voltage ranges of the segment driving stages SEG0, SEG1, SEG2 and the common driving stages COM0, COM1, COM2 are different, Compared to the low voltage devices, they are driven by using a high voltage device having a large size and a relatively slow speed, so that a loss occurs in terms of speed and area. In addition, a booster circuit (Booster) is used to make a plurality of voltages (V0, V1, V2, V3, V4), and the boosted voltage is distributed and used, thereby requiring a device having a large area of high voltage. There is a problem.

In order to solve the above problems, the present invention uses a basic voltage generator to process the valid information into a low voltage signal, and adds the valid information to the basic voltage to output the low voltage device capable of forming the driving stage as a low voltage device. It is an object of the present invention to provide an acetylene LED driving circuit.

In order to achieve the above object, the low-voltage element styrene LED driving circuit of the present invention, the image data storage and signal control unit for storing the image data in the frame unit, and outputs the image data signal and the position control signal; Adjusting means for a low voltage element for receiving an image data signal and a position control signal from the image data storage and signal control unit, and adjusts the image data signal and the position control signal to a segment drive signal and a common drive signal for a low voltage element ; A segment driving circuit which receives the segment driving signal from the adjusting means for low voltage element and outputs it as an image signal; A common driving circuit which receives the common driving signal from the adjusting means for low voltage element and outputs it as a positioning signal; And an LCD panel which displays the image signal received from the segment driving circuit at a position designated by the positioning signal in the common driving circuit.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. .

First, FIG. 4 is a block diagram illustrating a low-voltage device styrene LED driving circuit according to an embodiment of the present invention, the low-voltage device styrene LED driving circuit of the present invention, the image data storage and signal control unit 410, A low voltage element adjusting means 420, a segment driving circuit 430, a common driving circuit 440, and an LCD panel 450.

The image data storage and signal control unit 410 stores the image data in units of frames and outputs the image data signal and the position control signal to the adjustment means 420 for low voltage elements described later.

In addition, the low voltage device adjustment means 420 receives an image data signal and a position control signal from the video data storage and signal control unit 410, and drives the segment to match the image data signal and the position control signal to the low voltage device. It adjusts and outputs the signal and the common driving signal. Here, the low voltage element adjusting means 420 includes a basic voltage step adjusting means 421, a polarity controlling means 422, an effective common driving signal generating means 423, a basic voltage generator 424, and an effective segment driving signal. Generating means 425, a first adder 426, and a second adder 427.

The basic voltage step adjusting means 421 mounted in the low voltage element adjusting means 420 serves to adjust the basic voltage step and output the adjusted step voltage to the basic voltage generator 424 described later.

In addition, the polarity control means 422 mounted in the adjustment means 420 for the low voltage element generates a polarity control signal to drive the effective common drive signal generation means 423, the basic voltage generator 424, and the effective segment drive described later. It serves to output to the signal generating means 425. When the LCD is driven with only one voltage, the polarity control signal may be generated even when no voltage is applied to the liquid crystal due to aging, thereby preventing the phenomenon. This polarity control method is a universal method for preventing the above phenomenon.

On the other hand, the effective common drive signal generation means 423 mounted in the adjustment means 420 for the low voltage element receives the position control signal from the image data storage and signal control unit 410 and uses the position control signal. As a result, an effective common driving signal having a polarity corresponding to the polarity control signal from the polarity control means 422 is generated and output to the first adder 426 to be described later.

In addition, the basic voltage generator 424 mounted in the low voltage element adjusting means 420 receives the step voltage from the basic voltage step adjusting means 421, and controls the polarity from the polarity control means 422. It generates a basic voltage using the step voltage according to the signal and outputs it to the first adder 426 and the second adder 427 which will be described later.

On the other hand, the effective segment drive signal generating means 425 mounted in the low voltage element adjusting means 420 receives the image data signal from the image data storage and signal control unit 410 and uses the image data signal. As a result, an effective segment driving signal having a polarity according to the polarity control signal from the polarity control means 422 is generated and output to the second adder 427 to be described later.

In addition, the first adder 426 mounted in the low voltage element adjusting means 420 outputs the effective common drive signal input from the effective common drive signal generating means 423 from the basic voltage generator 424. The basic voltage is added to generate a common driving signal, and outputs the common driving signal to the common driving circuit 440 which will be described later.

On the other hand, the second adder 427 mounted in the low voltage element adjusting means 420 outputs the effective segment driving signal input from the effective segment driving signal generating means 425 from the basic voltage generator 424. The segment driving signal is generated by adding a basic voltage and outputs the segment driving signal to the segment driving circuit 430 which will be described later.

In addition, the segment driving circuit 430 receives the segment driving signal from the low voltage device adjusting means 420 and outputs the segment driving signal as an image signal to the LCD panel 450 to be described later.

Meanwhile, the common driving circuit 440 receives the common driving signal from the low voltage device adjusting means 420 and outputs the common driving signal to the LCD panel 450 which will be described later as a positioning signal.

In addition, the LCD panel 450 displays the image signal input from the segment driving circuit 430 at a position designated by the positioning signal in the common driving circuit 440. Here, the LCD uses a supertwisted nematic (STN) panel, which is a liquid crystal cell in which an array of thin liquid crystal molecules is arranged at an angle of 180 ° between two glass substrates. There is also. The applied voltage-transmittance characteristic is sharper than that of a TN type liquid crystal having a structure that is suitable for a display panel having a large number of pixels and is arranged at 90 °. For this reason, contrast is ensured even in a panel of a large-capacity capacity where the difference between the on-off voltage (effective voltage) cannot be increased. Black and white panels of 640 × 480 pixels, color display panels combining black and white panels and color films are already installed in small portable computers such as laptops, and new display panels made by combining STN type liquid crystal cells and active matrix driving methods are also developed. Although the response speed is fast, the moving picture display which was not possible with the conventional TN type liquid crystal panel is made possible.

FIG. 5 is a timing diagram illustrating a common driving waveform of an styrene LED drive circuit for a low voltage device according to an embodiment of the present invention, and FIG. 6 is a segment of an styrene LED drive circuit for a low voltage device according to an embodiment of the present invention. As a timing chart showing a drive waveform, the operation of the low-voltage element styrene LED driving circuit of the present invention will be described with reference to this.

According to FIG. 5, the combination of waveforms is determined by the sum of the effective common drive signal and the basic voltage output from the second adder 427. At this time, the step of the base voltage can be adjusted by the base voltage step adjusting means 421, so that the base voltage is used as a substitute for V2 and V3 (shown from the bottom in the timing diagram), or the base voltage is V2 and V3. It can also be changed to (shown at bottom at timing diagram). This also applies to the segment drive waveform shown in FIG.

Since the driving voltage of the typical ESTIC LCD is 9 V to 13 V, the basic voltage is applied at a voltage of about 1/2 of this voltage, and a device capable of dealing with this breakdown voltage can be used.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited to.

The present invention processes the valid information into a low voltage signal using a basic voltage generator, adds the valid information to the basic voltage, and outputs the driven terminal to form a low voltage element. In the case where the boosted voltage is distributed and used, there is an advantage of solving the problem of requiring an element having a large area of high voltage.

1 is a circuit diagram showing a conventional ethienne LCD panel,

Figure 2 is a circuit diagram showing a conventional estien LCD drive circuit,

3 is a timing diagram showing the operation of a conventional ETI LCD drive circuit;

FIG. 4 is a block diagram showing an styrene LED driving circuit for a low voltage device according to an embodiment of the present invention; FIG.

FIG. 5 is a timing diagram showing a common driving waveform of an styrene LED drive circuit for a low voltage device according to an embodiment of the present invention; FIG.

FIG. 6 is a timing diagram illustrating segment driving waveforms of an styrene LED driving circuit for a low voltage device according to an exemplary embodiment of the present invention. FIG.

Explanation of symbols on the main parts of the drawings

410: Image data storage and signal controller

420: adjustment means for low voltage devices

430: segment drive circuit

440: common drive circuit

450: LCD panel

Claims (2)

An image data storage and signal controller for storing image data in frame units and outputting an image data signal and a position control signal; Basic voltage step adjusting means for adjusting a basic voltage step and outputting the adjusted step voltage; A basic voltage generator for generating a basic voltage according to the step voltage; Polarity control means for generating and outputting a polarity control signal; Effective common drive signal generation means for generating an effective common drive signal suitable for a low voltage element using the position control signal in accordance with the polarity control signal; Valid segment drive signal generation means for generating an effective segment drive signal suitable for a low voltage element using the image data signal in accordance with the polarity control signal; A first adder generating a common driving signal by adding the effective common driving signal and the basic voltage; A second adder generating a segment driving signal by adding the effective segment driving signal and the basic voltage; A common driving circuit which receives the common driving signal and outputs it as a positioning signal; A segment driving circuit which receives the segment driving signal and outputs the segment driving signal as an image signal; And An LCD panel driven according to the positioning signal and the image signal; Ethiene LCD drive circuit for a low-voltage device comprising a. delete