KR20000013504A - Character type liquid crystal driving device - Google Patents

Abstract

PURPOSE: A character type liquid crystal driving device is provided to decrease a size of integrated circuit and reduce cost of production and consumption of current and simplify circuit design of mask ROM. CONSTITUTION: The character type liquid crystal driving device comprises two of liquid crystal driving integrated circuit(IC) at least, and a liquid crystal panel. In the character type liquid crystal driving device, the liquid crystal driving integrated circuit(IC) has a memory with a specific size, wherein a font data is stored in the memory. Liquid crystal driving ICs shares the stored font data and drives the liquid crystal panel in respectively. Liquid crystal driving ICs also interfacing a clock signal and the font data with other liquid crystal driving IC in respectively. At least, two of liquid crystal driving ICs forms a relationship of master-slave.

Description

Character LCD Drive

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display (LCD) driving apparatus, and more particularly, to a character type liquid crystal driving apparatus in which each integrated circuit can share font data stored in a plurality of integrated LCD (panel) driving integrated circuits. It is about.

Character type liquid crystal driving integrated circuits require about 2 Mbits of ROM in order to output a very large number of characters such as Korean and Chinese characters. However, as a result of the unification of the character codes around the world, in recent years, a very large font mask ROM of about 8 Mbits has been incorporated into the character type liquid crystal driving integrated circuit. In addition, in the communication service market, there is an increasing demand for a liquid crystal panel having a large size which greatly increases the number of characters that can be displayed in order to display a larger amount of information on one screen.

For the reasons described above, it is difficult to drive a liquid crystal panel having a required size with only one liquid crystal driving integrated circuit. In order to solve this problem, when a large amount of font data of more than several thousand characters is required, a separate dedicated ROM storage mask ROM should be provided outside the liquid crystal driving integrated circuit, or as much font data as necessary is needed for another liquid crystal driving integrated circuit. Should be stored in In this case, the font data stored in the mask ROM or the liquid crystal driving integrated circuit provided separately may not be shared with other liquid crystal driving integrated circuits.

In addition, when a large-capacity font data mask ROM is incorporated in one integrated circuit, the size of the integrated circuit increases, the manufacturing cost increases, the circuit design of the mask ROM becomes difficult, and the current consumption increases. A problem occurred.

The technical problem to be achieved by the present invention is to use a plurality of identical liquid crystal drive integrated circuits interfaced to drive a large size liquid crystal panel, and the liquid crystal drive integrated circuits can share font data stored in each liquid crystal drive integrated circuit. It is to provide a character type liquid crystal drive device.

1 is a block diagram for explaining a character type liquid crystal drive device according to the present invention.

FIG. 2 is a block diagram of a preferred embodiment of the present invention of the main and longitudinal liquid crystal drive integrated circuits shown in FIG.

3 is a view for explaining the apparatus shown in FIG.

4A to 4I are waveform diagrams of respective parts shown in FIG. 2.

Characterized liquid crystal drive device according to the present invention for achieving the above object is composed of at least two or more liquid crystal drive integrated circuits each having a predetermined size of memory for storing font data, the liquid crystal drive integrated circuits are each stored in the Font data is shared with each other to drive the liquid crystal panel, and each of the liquid crystal driving integrated circuits interfaces with clock signals and the font data with another liquid crystal driving circuit.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the character type liquid crystal drive device according to the present invention will be described as follows.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram for explaining a character type liquid crystal drive device according to the present invention. And a liquid crystal panel 5 and a liquid crystal panel 16 according to the present invention, which are composed of the fields 10, 12, ..., and 14.

Each liquid crystal drive IC included in the character type liquid crystal drive device 5 according to the present invention shown in FIG. 1 has a memory of a predetermined size for storing font data. At this time, the character type liquid crystal drive device 5 drives the liquid crystal panel 16 while allowing the liquid crystal drive integrated circuits to share the font data stored in each of the liquid crystal drive integrated circuits. In addition, each of the liquid crystal driving integrated circuits may have an interfacing port (not shown) for sharing clock signals and font data with a neighboring liquid crystal driving integrated circuit.

Seg of the liquid crystal panel 16 is driven by the first to M-th segment outputs SEG_OUT ₁ , SEG_OUT ₂ ,... And SEG_OUT _M , and the common of the liquid crystal panel 16 is the first to M-th common output. Driven by COM_OUT ₁ , COM_OUT ₂ , ... and COM_OUT _M.

At this time, the liquid crystal driving integrated circuits 10, 12,... And 14 shown in FIG. 1 form a master and slave relationship with each other. When the first liquid crystal drive integrated circuit 10 becomes a master and the second liquid crystal drive integrated circuit 12 becomes a slave, the main liquid crystal drive integrated circuit 10 and the longitudinal liquid crystal drive integrated The configuration and operation of a preferred embodiment of the circuit 12 according to the present invention will be described as follows.

FIG. 2 is a block diagram of a preferred embodiment of the present invention of the main and slave liquid crystal drive integrated circuits 10 and 12 shown in FIG. 1, wherein the first address counter 22, the first scan counter ( 24, a first line counter 26, a first random access memory (RAM) 28, a first read only memory (ROM) 30, a first register 34, a first line counter 26 A main liquid crystal driving integrated circuit 20 composed of two registers 36, first and second level converters 38 and 40, a second address counter 62, a second scan counter 64, a second; Consisting of a line counter 66, a second RAM 68, a second ROM 70, a third register 74, a fourth register 76, and third and fourth level converters 78 and 80. The vertical liquid crystal drive integrated circuit 60 is comprised.

The main and slave liquid crystal driving integrated circuits 20 and 60 illustrated in FIG. 2 correspond to the first and second liquid crystal driving integrated circuits 10 and 12 illustrated in FIG. 1, respectively, and perform the same function. The panel 16 is driven. Accordingly, it can be seen that the first and second ROMs 30 and 70 correspond to the above-described memory for storing font data.

The first address counter 22 of the main liquid crystal driving integrated circuit 20 shown in FIG. 2 is counted in from the first address ADD1 input as an initial value from an external micro-processor unit (MPU). The counting signal is counted in response to the enable signal EN, and the counted result is output to the first RAM 28 as an input address. At this time, the input address corresponds to an address to which data DATA1 input to the first RAM 28 is to be written, as will be described later.

The first scan counter 24 counts from the initial value '0' in response to the scan clock signal SCAN_CK having a period T, and outputs the counted result to the first RAM 28 as an output address. At this time, the output address corresponds to an address where data to be read from the first RAM 28 to the first ROM 30 is stored, as will be described later. The first line counter 26 counts from the initial value '0' in response to the line clock signal LINE_CK having NT (where N is the number of segments present in one line) and counts the counted result. Output to 1 ROM (30). Here, the value counted in the first line counter 26 has information about the line on which the current character is displayed. A timing generator (not shown) included in each of the liquid crystal driving integrated circuits 20 or 60 shown in FIG. 2 divides or multiplies the system clock signal to generate the above-described scan clock signal SCAN_CK and line clock signals LINE_CK. Can be. In addition, it can be seen that the frequency of the scan clock signal SCAN_CK is N times larger than the frequency of the line clock signal LINE_CK.

The first RAM 28 writes data DATA1 input from an external MPU to an input address output from the first address counter 22, and is stored in an output address output from the first scan counter 24. Read the data. Here, since the data DATA1 stored in the first RAM 28 corresponds to the address of the first ROM 30, font data to be output from the first ROM 30 may be designated as desired in the MPU. In this case, since the first RAM 28 must also simultaneously perform a write operation and a read operation, the first RAM 28 may be implemented as a dual port RAM.

On the other hand, the first ROM 30 corresponding to the mask ROM described above uses the data read from the first RAM 28 as upper bits, and the data output from the first line counter 26 as lower bits. The font data stored at the address of? Is outputted to the first and second multiplexers 30 and 70, respectively.

As a result, the main liquid crystal driving integrated circuit 20 shown in FIG. 1 stores the data DATA1 also designated in the MPU in the first RAM 28 corresponding to the address ADD1 designated in the MPU, and the first scan counter ( The data stored in the first RAM 28 is repeatedly read at regular intervals corresponding to the value counted in 24), and the desired font data is stored by concatenating the read data with the result counted in the first line counter 26. An address of the first ROM 30 is generated, and font data of a corresponding character stored in the generated address is read out from the first ROM 30.

The first address counter 22, the first scan counter 24, the first line counter 26, the first RAM 28 and the first ROM 30 described above are the second address counter 62 and the second. The scan counter 64, the second line counter 66, the second RAM 68, and the second ROM 70 perform the same operation. Accordingly, font data read out from the second ROM 70 is output to the first and second multiplexers 32 and 72.

The first multiplexer 32 shown in FIG. 2 selects one of font data read from the second ROM 70 and font data read from the first ROM 30 in response to the first selection signal S1. The selected data is output to the first register 34. In this case, the first selection signal S1 may be the most significant bit of data output from the first RAM 28 as the upper address of the first ROM 30, and may be separately stored as the data DATA1. It may be a value entered and stored in 28). That is, the first multiplexer 32 selects font data read from the first ROM 30 and outputs the font data read from the first ROM 30 to the first register 34 when the first selection signal S1 is at a "high" logic level. When the selection signal S1 is at the "low" logic level, font data read out from the second ROM 70 is selected and output to the first register 34.

At this time, the first register 34 shifts the data selected by the first multiplexer 32 in response to the first clock signal CK1, latches the shifted data in response to the second clock signal CK2, The latched result is output to the first level converter 38. In this case, the frequency of the first clock signal CK1 may be N times greater than the frequency of the second clock signal CK2, and the first clock signal CK1 may be the same as the frequency of the scan clock signal SCAN_CK. The first and second clock signals CK1 and CK2 may be generated from the above-described timing generator. At this time, the first level converter 38 converts the output of the first register 34 into an actual voltage for driving the liquid crystal panel, and converts the converted result into a first segment for driving a segment of the liquid crystal panel. Output as a segment output (SEG_OUT ₁ ). That is, since the value output from the first register 34 cannot drive the liquid crystal panel as a logic level, the first level converter 38 converts the logic level into a corresponding voltage value for driving the liquid crystal panel. Play a role.

Meanwhile, the second register 36 inputs the counted result from the first line counter 26, shifts the counted result in response to the second clock signal CK2, and shifts the shifted result to the second level. Output to the converter 40. Similar to the first level converter 38, the second level converter 40 converts the shifted result from the second register 36 into a voltage for driving the liquid crystal panel, and converts the converted result into a common of the liquid crystal panel. and outputs as a first common output (COM_OUT ₁₎ for driving the (COMMON).

Like the first multiplexer 32, the second multiplexer 72 illustrated in FIG. 2 has font data stored in the first ROM 30 and a font stored in the second ROM 70 in response to the second selection signal S2. One of the data is selected, and the selected font data is output to the third register 74. In this case, the second selection signal S2 may be the most significant bit of data output from the second RAM 68 as an upper address of the second ROM 70 similarly to the first selection signal S1, and the data DATA2. ) May be a value input and stored in the second RAM 68 separately from the outside. That is, the second multiplexer 72 selects the font data read from the first ROM 30 and outputs the font data read from the first ROM 30 to the third register 74 when the second selection signal S2 is at the "high" logic level. When the selection signal S2 is at the "low" logic level, font data read out from the second ROM 70 is selected and output to the third register 74.

The third and fourth registers 74 and 76 perform the same function as the first and second registers 34 and 36, respectively, and the third and fourth level converters 78 and 80 are the first and second registers. Each of the second level converters 38 and 40 performs the same function. In addition, the vertical liquid crystal driving integrated circuit 60 of the character type liquid crystal driving apparatus according to the present invention shown in FIG. 2 is provided between the IC 20 and the IC 60 with clock signals generated by the main liquid crystal driving circuit 20. The font data interface port (not shown) provided through the clock port (not shown), and the main and slave liquid crystal drive integrated circuits 20 and 60 provide font data stored in the opposite ROM between the IC 20 and the IC 60. Can be exchanged through

FIG. 3 is a view for explaining the apparatus shown in FIG. 2 and includes main and vertical liquid crystal driving integrated circuits 20 and 60 and a liquid crystal panel 90.

As shown in FIG. 3, when the size of the liquid crystal panel 90 is large and it is necessary to embed many font data such as Chinese characters, the character type liquid crystal driving apparatus according to the present invention shown in FIG. 2 is usefully used. Can be. If the liquid crystal panel 90 is driven by the common output COM_OUT ₁ output from the main liquid crystal driving integrated circuit 20, the first and second lines 92 and 94 and the vertical liquid crystal driving integrated circuit 60 may be used. Suppose it is divided into third and fourth lines 96 and 98 driven by a common output COM_OUT ₂ outputted from. In this case, each of the first and second RAMs 28 and 68 shown in FIG. 2 is divided into a main region and a longitudinal region, and when driving the liquid crystal panel 90 by the longitudinal liquid crystal driving integrated circuit 60. In the case where the required font data is stored in the first ROM 30 of the main liquid crystal driving integrated circuit 20 or vice versa, it serves to store the address of the corresponding ROM to find the required font data. In addition, the font data stored in the main liquid crystal driving integrated circuit 20 are segment outputs SEG_OUT ₁ and SEG_OUT ₂ output from the main and vertical liquid crystal driving integrated circuits 20 and 60 to drive the liquid crystal panel 90. Whether to generate from or from font data stored in the longitudinal liquid crystal drive integrated circuit 60 is determined by the above-described operation by the first and second multiplexers 32 and 72.

Meanwhile, a detailed operation of the apparatus shown in FIG. 2 will be described with reference to the waveform diagram as follows.

4 (a) to 4 (i) are waveform diagrams of the respective parts shown in FIG. 2, and FIG. 4 (a) shows a waveform diagram of the scan clock signal SCAN_CK, and FIG. 4 (b) shows a first or second waveform. Fig. 4 (c) shows data output from the first or second RAM 28 or 68, and Fig. 4 (d) shows the first or second RAM. A ROM address inputted from the main area of 28 or 68 to the first or second ROM 30 or 70 is shown, and FIG. 4E shows the first or second ROM 30 or 70 by the address of the main area. (F) shows an address input to the first or second ROM 30 or 70 from the longitudinal area of the first or second RAM 28 or 68, and FIG. (g) shows font data output from the first or second ROM 30 or 70 by the address of the slave area, and FIG. 4 (h) shows the first clock signal CK1. Fig. 4 (i) shows the data shifted in the first or third register 34 or 74, respectively.

The first scan counter 24 shown in FIG. 2 starts counting in synchronization with the falling edge of the scan clock signal SCAN_CK shown in FIG. 4A, and the counted result is shown in FIG. 4B. The output addresses are sequentially output to the first RAM 28. Therefore, the first RAM 28 outputs the data shown in FIG. 4 (d) stored at the output address as the address of the first ROM 30. Here, when the addresses 00 (h) to 1F (h) of the first RAM 28 are referred to as the main regions, and 20 (h) to 3F (h) are referred to as the vertical regions, the first scan counter 24 Reads the upper address of the first ROM 30 stored in the output address of the main region and the slave region in order.

At this time, the first ROM 30 shows the data output from the first RAM 28 as the upper address, and the result counted by the first line counter 26 as the lower address shown in FIG. 4 (d). The font data stored at the address is output to the first and second multiplexers 32 and 72. Here, it is assumed that the counted result of the first line counter 26 which is a lower address of the first ROM 30 is 4 bits. Therefore, it is possible to determine which line of the font data stored in the first ROM 30 is to be output by the lower 4 bits.

On the other hand, when the first and second segment outputs SEG_OUT ₁ and SEG_OUT ₂ are to be generated by font data stored in the main liquid crystal driving integrated circuit 20, as shown in FIG. And the font data read out from the first ROM 30 is input (* 1 and * 3) into the third registers 34 and 74, and the font data stored in the vertical liquid crystal driving integrated circuit 60 is used for the first. And when the second segment outputs SEG_OUT ₁ and SEG_OUT ₂ are to be generated, as shown in FIG. 4 (i), from the second ROM 70 to the first and third registers 34 and 74. The first and second selection signals S1 and S2 are output from the first and second RAMs 28 and 68, respectively, so that the read font data is input (* 2 and * 4).

As described above, the character type liquid crystal drive device according to the present invention increases the size of integrated circuits, increases manufacturing costs, and increases the design of mask ROMs by embedding a large amount of font data mask ROMs in one integrated circuit. Of the liquid crystal driving integrated circuits and the plurality of liquid crystal driving integrated circuits, which can avoid the increase in the current consumption and increase the current consumption, and use a plurality of liquid crystal driving integrated circuits. The font data stored in the liquid crystal driving integrated circuit can be output as segment data through the vertical (or main) liquid crystal driving integrated circuit. When the liquid crystal panel to be driven is large, one font is used to compensate for the insufficient output stage. Save / utilize twice the data with small ROM area There is an advantage that can provide an effect.

Claims (6)

At least two liquid crystal driving integrated circuits each having a predetermined size of memory for storing font data, The liquid crystal driving integrated circuits may drive the liquid crystal panel by sharing the font data stored in each other, and each of the liquid crystal driving integrated circuits may interface clock signals and the font data with another liquid crystal driving circuit. Character type liquid crystal drive device. The character type liquid crystal drive device of claim 1, wherein the at least two liquid crystal drive integrated circuits have a main and slave relationship with each other. 3. The main liquid crystal drive integrated circuit of claim 2, wherein the main liquid crystal drive integrated circuit is one of the liquid crystal drive integrated circuits. A first ROM for reading the font data stored at a first address; And First selection means for selectively outputting one of the font data output from the longitudinal liquid crystal drive integrated circuit, which is one of the liquid crystal drive integrated circuits, and the font data read out from the first ROM in response to a first selection signal; And the first ROM corresponds to the memory. The liquid crystal driving integrated circuit of claim 3, wherein A second ROM for reading the font data stored at a second address; And Second selecting means for selectively outputting one of said font data read out from said first ROM and font data read out from said second ROM in response to a second selection signal, wherein said second ROM comprises said memory; Characterized in that the liquid crystal drive device. The liquid crystal driving integrated circuit of claim 4, wherein each of the main and slave liquid crystal driving integrated circuits is formed. An address counter which sets the third address input from the outside as an initial value, counts in response to a counting enable signal, and outputs a counted result as an input address; A scan counter counting in response to a scan clock signal having a period T and outputting the counted result as an output address; A line counter that counts in response to a line clock signal having a period of NT (where N is the number of segments present in one line) and outputs a counted result; A RAM for writing data input from the outside to the input address and reading data stored at the output address; A first register for shifting, latching, and outputting data selected by the first or second selection means; And First level converting means for converting an output of the first register to a level for driving the liquid crystal panel, and outputting the converted result as a signal for driving a segment of the liquid crystal panel; And the RAM is a dual port RAM, and wherein the first or second address is a sum of a result counted at the line counter and data read from the RAM. 6. The liquid crystal display of claim 5, wherein each of the main and longitudinal liquid crystal drive integrated circuits comprises: A second register configured to shift and output a result counted by the line counter; And a second level converting means for converting the output of the second register into a level for driving the liquid crystal panel and outputting the converted result as a signal for driving the common of the liquid crystal panel. drive.