JPH0216218B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a kanji printer device in which a character generator is constituted by a RAM and a segment register is provided for accessing the RAM for the character generator.

Traditionally, kanji printers have been controlled using two methods: one has a buffer for only one line in the control circuit, and each time a kanji is printed, print data and patterns are sent from the main body, and the other is a ROM (read-only memory). It has a built-in CG (abbreviation for character generator) consisting of , and when printing kanji, a predetermined code is specified, and the print pattern in the ROM is also retrieved from the CG ROM at the address where this code is converted. There is a method. However, in the former case, print data must be transmitted from the main body each time printing is performed, which increases the transmission time required for one transmission, which poses a problem in terms of system efficiency. Further, the latter has disadvantages in that it is expensive, and since it is a ROM, patterns cannot be easily changed, and the types of characters that can be printed are limited. CG gets bigger,
For example, if a capacity exceeding 64K is required, there is a problem that addressing cannot be done using conventional methods.

In view of the above-mentioned points, the present invention consists of CG with RAM provided in the control circuit, and has a large capacity.
The purpose of this invention is to provide a kanji printer device that can realize CG memory. Therefore, the kanji printer device of the present invention includes a kanji printer mechanism section, a printer control circuit having a control memory that stores a control program and a microprocessor, and an interface that controls data transfer between the main device and the printer control circuit. an ace circuit, a RAM for a kanji generator having multiple segments for storing kanji dot patterns for one character, a character generator for alphanumeric and kana characters that stores character dot patterns for alphanumeric and kana characters, and a data generator. a segment register into which data on the bus is input and output data is supplied as an address to the Kanji generator RAM; a first shift code and an alphanumeric kana code string or second 2nd shift
a code storage section in which a code and a segment address string following the second shift code are stored, and the printer control circuit sequentially reads data from the code storage section, If the data is the first shift code, then
Recognizes that the following data is an alphanumeric kana code string, and retrieves the alphanumeric kana character dot pattern corresponding to the alphanumeric kana code read from the code storage unit from the alphanumeric kana character generator. If the data sent to the Kanji printer mechanism section and read from the code storage section is the second shift code, the data that follows is recognized as a segment address string and read from the code storage section. The segment address is set in the segment register, and the Kanji dot pattern corresponding to the segment address is retrieved from the Kanji generator RAM and sent to the Kanji printer mechanism. That is. Hereinafter, the present invention will be explained with reference to the drawings.

FIG. 1 is a block diagram of one embodiment of the present invention. In the figure, 1 is the main unit, 2 is the interface circuit, 2 is the microprocessor, 4 is the control memory, 5 is the RAM for work, 6 is the RAM for CG, 7
is the segment register, 8 and 9 are the decoders, 1
0 is an input port, 11 is an output port, 12 is a driver circuit, 13 is a mechanical mechanism section, 14 is an OR circuit, and 15 is a selector.

The main device 1 sends print data and control data to the printer control circuit. The interface control circuit 2 controls data transfer between the printer control circuit and the main device 1. The interface circuit 2 can set control data in the registers and memory of the printer control circuit according to instructions from the main unit. The printer control circuit is composed of the main unit 1, the interface circuit 2, and the mechanical mechanism section 13. The microprocessor 3 is, for example, an 8-bit microprocessor, and executes various operations according to programs stored in the control memory 4. In this control memory, CGs for alphanumeric characters and kana characters are provided. The work RAM 5 stores temporary data. The CG RAM 6 stores character dot patterns of Kanji characters.
The pattern of a single kanji character is represented by 24 x 24 dots. The segment register 7 generates an address for the CG RAM 6. This address can have a 3-byte configuration, for example.
The input side of segment register 7 is connected to the data bus. Decoder 8 decodes address information, and sends a data set signal to segment register 7 if the address information specifies segment register 7. Decoder 9 decodes address information and sends a decoded signal to input port 10 or output port 11. The driver circuit 12 amplifies a signal sent to the mechanical mechanism section 13 or a signal sent from the mechanical mechanism section 13. The output of the OR circuit 14 is connected to the set terminal of the segment register 7, and its input terminal is connected to the decoder 8 and the interface circuit 2.

FIG. 2 shows one line of print data sent from the main unit 1. As shown in FIG. ASC indicates that the data that follows is an alphanumeric or kana code, and KSC indicates that the data that follows is a segment address.

FIG. 3 shows the state of storage of kanji CG patterns in the CG RAM 6. The dot pattern of one Kanji character is 24 x 24 dots, so 72 bytes of area is required to store the dot pattern of one Kanji character. This 72-byte area is called a segment.

Next, the operation of the embodiment shown in FIG. 1 will be explained. For CG
In order to store the kanji dot pattern in the RAM 6, the following operations are performed. Main unit 1
sets an initial value in the segment register 7, and also sets other necessary information (information indicating that pattern data is to be written) in the printer control circuit. And RAM6 for CG
When the data to be written to is sent one byte at a time,
The data is written to the storage location of the CG RAM 6 specified by the address generated by the segment register 7. 1 byte of data is CG RAM
The address information output from segment register 7 is updated every time data is written to segment register 6. Although not shown, the segment register 7 has an internal 72-decimal counter. Once a predetermined number of kanji CG patterns are stored in the CG RAM 6, this RAM can be used as CG from now on.

When printing is performed, first, one line of print data as shown in FIG. 2 is stored in the work RAM 5. After that, when a print start command is received,
The corresponding program in the control memory 4 is executed,
Print data in the work RAM 5 is read out one by one. If the read print data is an alphanumeric code or kana code, the CG of control memory 4
The corresponding character dot pattern is read out from
It is then sent to the print head. Work RAM5
If the print data read from is a segment address, this segment address is set in segment register 7 and used for CG.
The first 1-byte column element of the corresponding Kanji CG pattern is read from the RAM 6. Each time a 1-byte column element is read, the address output by segment register 7 is incremented by 1. When all column elements belonging to the same kanji CG pattern are read out, the next print data is read out from the CG RAM 6.

As is clear from the above explanation, according to the present invention, even if the CG is configured with RAM and the address of this CG RAM exceeds the range that can be specified by a microprocessor, etc., the CG pattern can be processed via the segment register. Since it is possible to store and read
It is possible to configure the CG with RAM, realize a large capacity CG memory within the range that can be specified by the segment register, and provide a kanji printer device with excellent system efficiency.

[Brief explanation of drawings]

Figure 1 is a block diagram of a control device for a kanji printer showing an embodiment of the present invention, Figure 2 is a diagram showing one line of print data in the data buffer, and Figure 3 is the correspondence between segments and CG RAM. FIG. 1... Main unit, 2... Interface circuit,
3...Microprocessor, 4...ROM for storing microprograms, 5...RAM for work, 6
...RAM for CG, 7...Segment register,
8 and 9...address decoder, 10...input port, 11...output port, 12...driver circuit, 13...mechanical mechanism section.

Claims (1)

[Claims] 1. A kanji printer mechanism, a printer control circuit having a control memory that stores a control program, and a microprocessor, and an interface circuit that controls data transfer between the main unit and the printer control circuit. , a RAM for a kanji generator having multiple segments for storing kanji dot patterns for one character, a character generator for alphanumeric and kana characters that stores character dot patterns for alphanumeric and kana characters, and a data bus on the data bus. a segment register into which data is input and output data is supplied as an address to the RAM for the kanji generator, a first shift code and an alphanumeric kana code string following the first shift code or a second shift·
a code storage section in which a code and a segment address string following the second shift code are stored, and the printer control circuit sequentially reads data from the code storage section, If the data is the first shift code, then
Recognizes that the following data is an alphanumeric kana code string, and retrieves the alphanumeric kana character dot pattern corresponding to the alphanumeric kana code read from the code storage unit from the alphanumeric kana character generator. If the data sent to the Kanji printer mechanism section and read from the code storage section is the second shift code, the data that follows is recognized as a segment address string and read from the code storage section. The segment address is set in the segment register, and the Kanji dot pattern corresponding to the segment address is retrieved from the Kanji generator RAM and sent to the Kanji printer mechanism. Kanji printer device.