KR19980045990A - LCD panel drive circuit - Google Patents

Abstract

The present invention relates to an LCD panel driving circuit, and receives a most significant bit of a driving channel required to implement each graphics mode in a signal output from a decoder, and determines a graphics mode to which a graphics mode selection signal is to be output. If the graphics mode selection circuit outputs the most significant bit of the driving channel required for the graphics mode to be implemented among the most significant bits inputted from the decoder, the output signal of the graphics mode selection circuit and the reset signal and clock inputted from the outside. It consists of an internal reset signal generation circuit that receives a signal as an input and generates an internal reset signal for resetting the counter, and includes a driving channel for driving an LCD panel in various graphics modes, and each graphics mode. Required to implement By resetting the counter by selecting the signal of the most significant bit in the channel signal center, it is possible to drive the LCD panel having the graphic mode of the selected driving channel.

Description

LCD panel drive circuit

1 is a block diagram showing a conventional LCD panel driving circuit.

2 is a block diagram showing an LCD panel driving circuit of the present invention.

3 is a circuit diagram showing a graphic mode selection circuit of the present invention.

Explanation of symbols on the main parts of the drawings

110, 210: counter 120, 220: decoder

130, 230: level shifter 140, 240: LCD panel

250: graphics mode selection circuit 260: internal reset signal generation circuit

INV1 to INV3: Inverter T1 to T6: Transmission gate

The present invention relates to an LCD panel driving circuit, and more particularly, to an LCD panel driving circuit including a graphic mode selecting circuit and allowing each graphic mode of an LCD panel capable of outputting multiple graphics modes to be selected and driven. will be.

In general, the LCD panel driving circuit includes a row driver driving a horizontal line of the LCD panel and a column driver driving a vertical line.

The row driver is connected to the gate terminal of the thin film transistor (TFT) constituting the LCD panel, and is configured to sequentially drive each TFT.

An example of such a conventional low driver will be described with reference to FIG.

1 is a block diagram showing a conventional LCD panel driving circuit.

As shown in FIG. 1, the counter 110 is connected to a clock signal CLK and a reset signal RESET, and an output of the counter 110 is input to the decoder 120 through a 9-bit bus line. To be connected.

The 9-bit signal input to the decoder 120 is decoded and output so that the 480-bit signal is input to the level shifter 130. The level shifter 130 is connected to the input panel of the 480-bit signal. Level conversion is made to be driven is connected to be input to the LCD panel 140.

Referring to the operation of the LCD panel driving circuit as follows.

The counter 110 performs a sequential counting operation and outputs a 9-bit signal having a predetermined value to the output terminal.

The 9-bit signal output from the counter 110 is input to the decoder 120 and decoded into 512 bits. Among the decoded 512 bits, the signal of the lower 480 bits necessary to drive the LCD panel 140 is higher than the lower bits. It is output to the level shifter 130 in the order of the bits.

Since the 480-bit signal input to the level shifter 130 is not suitable for driving the gate terminals of the transistors constituting the LCD panel 140, an appropriate level of conversion is performed in the level shifter 130, followed by the LCD panel 140. Is output.

In this case, the transistor driven in the LCD panel 140 is sequentially driven from the horizontal line to which the lower bit signal is input to the horizontal line to which the upper bit is input in accordance with the order of the signals output from the decoder 120. The screen is formed.

However, since the LCD panel driven by the conventional LCD panel driving circuit is limited to one graphic mode, a decoder and a level shifter may be added to the LCD panel to output different graphics modes, or extremely a driver. Because of the redesign of the circuit, there is a problem in that the additional cost of producing the product is required.

Accordingly, the present invention includes a drive channel for driving an LCD panel in various graphic mode selection circuits, and a drive channel selected by selecting the most significant bit of the drive channel signals required to implement each graphic mode and resetting the counter. The purpose is to enable the drive of the LCD panel having a graphic mode of.

The present invention for this purpose is to receive the most significant bit of the drive channel required to implement each graphics mode to the signal output from the decoder as input and the graphics mode selection signal is input to determine the graphics mode to output from the decoder The graphics mode selection circuit which outputs the most significant bit of the driving channel required for the graphics mode to be implemented among the most significant bits inputted, and the output signal of the graphics mode selection circuit and the reset signal and the clock signal input from the outside are input. And an internal reset signal generation circuit for generating an internal reset signal for resetting the counter.

An embodiment of the present invention made as described above will be described with reference to FIGS. 2 to 3.

2 is a block diagram showing an LCD panel driving circuit of the present invention.

As shown in FIG. 2, the output of the counter 210 is connected to be input to the decoder 220 via a 10-bit bus line.

The 10-bit signal input to the decoder 220 is decoded and output so that the 1024-bit signal is output to the level shifter 230, and the level shifter 230 inputs the 1024-bit signal to drive the LCD panel. Level conversion is made so that the input to the LCD panel 240 is connected.

In addition, among the 1024-bit signals output from the decoder 220, each graphics mode is required to implement a VGA mode of 640 × 480, SVGA of 800 × 600, XGA mode of 1024 × 768, and EWS mode of 1280 × 1024. The 480, 600, and 768th bit signals and the reset signal RESET, which are driving signals of the most significant bit, are input to the graphic mode selection circuit 250.

The graphics mode selection circuit 250 is connected to input a 2-bit selection signal to select a graphics mode.

The internal reset signal generation circuit 260 is connected to the NAND gate G1 such that an output signal OUT of the graphic mode selection circuit 250 and a clock signal CLK are input.

In addition, the reset signal RESET inverted by the inverter INV1 and the output signal of the NAND gate G1 are connected to the NAND gate G2.

An output signal of the NAND gate G2, which is an output signal of the internal reset signal generation circuit 260, is connected to be input as a reset signal RESET of the counter 210, and a clock signal CLK is provided to the counter 210. Is connected to be input.

3 is a circuit diagram showing a graphic mode selection circuit of the present invention.

As shown in FIG. 3, transmission gates T1, T2, T3, and T4 formed by interconnecting the gate terminal and the source terminal of the PMOS transistor and the NMOS transistor are connected in parallel.

That is, the gate terminal of the NMOS transistor constituting the transmission gate T1 and the gate terminal of the PMOS transistor constituting the transmission gate T2 are interconnected, and the gate terminal and the transmission gate of the NMOS transistor constituting the transmission gate T2. The gate terminals of the PMOS transistors constituting T3 are interconnected, and the gate terminals of the NMOS transistors constituting the transmission gate T3 and the gate terminals of the PMOS transistors constituting the transmission gate T4 are interconnected.

The graphics mode selection signal MODE 1 is provided on the gate terminal of the PMOS transistor constituting the transmission gate T1, the gate terminal of the PMOS transistor constituting the transmission gate T4 and the gate terminal of the NMOS transistor constituting the transmission gate T4. ) Is connected to the input.

The graphics mode selection signal MODE A is connected to the gate terminal of the PMOS transistor constituting the transmission gate T2 and the gate terminal of the PMOS transistor constituting the transmission gate T4 so as to be inverted and input by the inverter INV2. .

The reset signal RESET is connected to the transmission gate T1, and the 768th bit output from the decoder 220 is input to the transmission gate T2, and the decoder (T3) is connected to the transmission gate T3. The 600th bit output from the 220 is connected to be input, and the 480th bit output from the decoder 220 is connected to the transmission gate T4.

The output signals of the transmission gates T1 and T2 are shorted to each other and connected to be input to the transmission gate T5, and the output signals of the transmission gates T3 and T4 are shorted to each other and connected to the transmission gate T6. do.

The gate terminal of the PMOS transistor constituting the transmission gate T5 and the gate terminal of the NMOS transistor constituting the transmission gate T6 are connected so that the graphic mode selection signal MODE B is input, and constitutes the transmission gate T5. The graphics mode selection signal MODE B is connected to the gate terminal of the NMOS transistor and the gate terminal of the PMOS transistor constituting the transmission gate T6 so as to be inverted and input by the inverter INV3.

The output signal of the transmission gates T5 and T6 becomes the output signal OUT of the graphic mode selection circuit 250.

Referring to the operation of the present invention configured as described above are as follows.

When the reset signal RESET is generated and the entire circuit is initialized and the counter 210 starts counting, the counter 210 sequentially generates 10 bits of different signals and outputs the signals.

The 10-bit signal output from the counter 210 is decoded by the decoder 220 to output a 1024-bit signal.

The 1024-bit signal output from the decoder 220 is input to the level shifter 230 and converted into a level capable of driving the LCD panel 240 to be input to the LCD panel 240 to form the LCD panel 240. The LCD panel 240 is driven by driving the gate of the TFT.

The output graphic mode of the LCD panel 240 driven as described above is determined by the following process.

The 480th, 600th, and 768th bits and the reset signal RESET output from the decoder 220 are input to the graphic mode selection circuit 250.

At this time, each transmission gate is turned on or off in accordance with the combination of the graphic mode selection signal MODE A (MODE B) inputted to output the signal OUT.

For example, when driving the LCD panel 240 in the SVGA graphic mode of 800 × 600, the graphic mode selection signal MODE A inputs a low level signal, and the graphic mode selection signal MODE B is a high level signal. Enter.

The transmission gate T1 (T3) is turned on by the input low level graphic mode selection signal MODE A, and the transmission gate T5 is turned on by the low level graphic mode selection signal MODE B. The SVGA mode signal is output.

The output signal OUT corresponding to the combination of the graphic mode selection signals MODE A and MODE B is shown in the following table.

[Table 1] Output mode according to combination of graphic mode selection signal

That is, when the graphics mode selection signal MODE A (MODE B) is (0, 0), respectively, the EWS mode is set and the reset signal (RESET) becomes the output signal OUT, and when (0, 1) When the SVGA mode is set and the 600th bit becomes the output signal (OUT), when (1, 0), the XGA mode is set and the 768th bit becomes the output signal (OUT), and when it is (1, 1) The VGA mode is set so that the 480th bit becomes the output signal OUT.

When the high level output signal OUT of the graphic mode selection circuit 250 is input to the NAND gate G1 of the internal reset signal generation circuit 260, the NAND gate (together with the high level period of the clock signal CLK) may be used. Make the output signal of G1) low.

The low level output signal of the NAND gate G1 is input to the NAND gate G2 to make the output signal of the NAND gate G2 high level regardless of the level of the remaining input signals.

The high level output signal of the NAND gate G2 is input to the reset terminal of the counter 210 to reset the counter 210.

Therefore, the counter 210 counts until the number of bits output from the decoder 220 is 768, is reset, and the output of the first bit is resumed.

The reset operation of the counter 210 is appropriately made according to the graphic mode set in the graphic mode selection circuit 250 and output to the LCD panel 240 in the graphic mode.

Therefore, the present invention includes a drive channel for driving an LCD panel in various graphic modes, and selects the most significant bit signal in the drive channel signal center required to implement each graphic mode, and resets the counter. There is an effect that enables the operation of the LCD panel having a graphics mode.

Claims (3)

An LCD panel driving circuit comprising a decoder for receiving an output signal of a counter as an input, decoding the output signal, and a level shifter for receiving the output signal of the decoder as an input and converting the output signal of the counter into a driving level of the LCD panel. When the graphics mode to be output is determined by receiving the most significant bit of the driving channel required for implementing each graphics mode to the signal output from the decoder, and the graphics mode selection signal is inputted, each input from the decoder A graphics mode selection circuit for outputting the most significant bit of the driving channel required for the graphics mode to be implemented among the most significant bits; And an internal reset signal generation circuit configured to receive an output signal of the graphic mode selection circuit, an externally input reset signal and a clock signal as inputs, and generate an internal reset signal for resetting the counter. Panel drive circuit. The circuit board of claim 1, wherein the graphic mode selection circuit comprises: And a multiplexer to which a signal output from the decoder is input and one of the signals input from the decoder is selected and output by a graphic mode selection signal. The circuit of claim 1, wherein the internal reset signal generation circuit comprises: A first NAND gate configured to receive an output signal and a clock signal of the graphic mode selection circuit as inputs and perform a NAND operation; An inverter for inverting a reset signal input from the outside; And a second NAND gate configured to receive an output signal of the first NAND gate and an output signal of the inverter as an input, and perform a NAND operation.