KR930004002B1 - Dot per inch changing circuit - Google Patents

Abstract

The circuit for converting the dot per inch by hardware comprises a parallel/serial converter converting the read pixel data synchronously to the first clock, a shifter shifting the converted data as much as one line synchronously to the second clock having N times frequency to the first clock, and a controller reading certain line of the page memory N times and providing them to the parallel/serial converter.

Description

Dot Per Inch Conversion Circuit

1 is a conventional facsimile diagram.

2 is a conventional data conversion diagram.

3 is a facsimile diagram according to the present invention.

4 is a concrete circuit diagram of a dot per inch conversion circuit in FIG.

5 is an operational waveform diagram according to the present invention.

6 is a flowchart illustrating a process of inputting dot per inch conversion data into a printer according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a memory operation technique for a facsimile, and more particularly, to a circuit for implementing dot per inch conversion in a general paper facsimile equipped with a page printer having a read resolution of 1/2 dpi (dot per inch) of recording resolution It is about.

Plain paper fax machines use line printing and page printing. Examples of page printers employing the latter method include laser, LED, and LCS printers, wherein the page printer is a device that stores at least one page of data to be recorded in memory and then writes a line-by-line pause. Say. Therefore, the page memory must be larger than the number of pixels constituting one page.

For example, for a 400 dpi, B4 printer, the B4 paper size is 10.2 inches x 14.5 inches, and the resolution is 400 pixels per inch, so the total number of pixels is 10.2 x 400 x 14.5 x 400, which is approximately 23.7 megabits (MBit). It consists of pixels. After all, you need about three megabytes of memory. That is, in the conventional case, 200 dpi data read or received by the G3 standard is converted into 400 dpi data by software, which is stored in a page memory of 3 mega capacity and then transferred to a printer for recording. Part 1 shows a configuration of a conventional facsimile performing such an operation, and the operation will be described in detail as follows.

The image data received by the reception modem 10 and the data to be copied from the reading device 20 are selectively transmitted to the central processing unit 40 through the multiplexer 30 according to the state of the fax. Since the image data received by the reception modem 10 is encoded according to the G3 standard, when the multiplexer 30 selects and outputs the image data, the central processing unit 40 once receives the image data. A few lines are first stacked in a static RAM (hereinafter referred to as S RAM) 50, and are sequentially read and decoded. The decoded data and the read data are image data that can be immediately printed as 200 dpi data based on the G3 standard. However, since the printer is for 400 dpi, the CPU 200 performs a software conversion of 200 to 400 dpi after the page memory. Stacked at 60. According to the 200 to 400dpi conversion, as shown in FIG. 2, the total number of data is increased four times and input to the page memory 60, so that the capacity of the page memory 60 needs to be increased about four times. For this reason, the installation of a large-capacity memory has led to an increase in the price of plain paper faxes and problems such as larger size and lower reliability.

Accordingly, an object of the present invention is to provide a dot per inch conversion circuit capable of reducing the capacity of a page memory.

In order to achieve the above object, the present invention reads pixel data stored in units of pages and performs parallel / serial conversion in synchronization with a predetermined first clock, and converts the serialized data into N times the frequency of the first clock. It is characterized in that it is configured to print a line N times by shifting line by line in synchronization with the second clock having.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

Figure 3 shows a partial configuration of the facsimile according to the present invention, by receiving and partitioning the receiving modem 10 for receiving image data transmitted from another facsimile and a picture or character to be transmitted to a remote location at regular intervals. A reading device 20 for converting into electric energy having contrast, a multiplexer 30 for selectively outputting data input from the reception modem 10 or the reading device 20 according to the state of the facsimile, and the facsimile of the facsimile machine. A central processing unit (40) for overall control of operation, a static ram (50) temporarily storing a plurality of lines of output of the multiplexer (30) under the control of the central processing unit (40), and the central processing unit Under the control of the device 40, a page memory 60 for storing one page of data and a pixel read from the page memory 60 are dots. Inch and converted dots per inch converter circuit 80 which is composed of a printer 70, which printer the dots per inch conversion data in a line unit.

FIG. 4 is a circuit diagram of a specific embodiment of the dot per inch conversion circuit 80 connected between the page memory 60 and the printer 70 in FIG. 3, in which pixel data read from the page memory 60 is input in parallel. A divider 82 for controlling output synchronization of the bottle / serial converter 81 by dividing the bottle / serial converter 81 outputted in series, the first predetermined clock CLK inputted in two; Inverter 85 for inverting one clock CLK and applying it to the printer 70 and the output of the bottle / serial converter 81 are stored line by line and then output from the inverter 85. The shift register 83 is transferred to the printer 70 in synchronization with a clock.

5 is an operating waveform diagram according to the present invention, where b is an output waveform of the divider 82, a is a data waveform output from the parallel / serial converter 81, and d is an inversion of the first clock CLK. Is an output waveform of the inverter 85, and e is a data waveform output from the shift register 83.

6 is a flowchart illustrating a process of inputting dot per inch conversion data to a printer according to the present invention, and illustrates a process of inputting a line of 200 dpi to a printer of 400 dpi.

An embodiment of the present invention will be described in detail based on the above-described configuration.

When the print start point is reached, the CPU 40 writes the parallel / serial converter 81 in units of bytes or words from the first data of the page memory 60, and stores the parallel data as described above. The input parallel / serial converter 81 outputs serial data (see a in FIG. 5) in synchronization with a clock (see b in FIG. 5) applied from the divider 82 to the clock stage.

This output is input to the shift register 83 for one line, and the shift register 83 is twice as high as the parallel / serial converter 81 to convert the horizontal direction to 400 dpi (see d in FIG. 5). The same data is controlled to be input to the shift register 83 in two successive operations. The clock having a frequency twice as high as that of the parallel / serial converter 81 is generated by inverting an externally input clock CLK using the inverter 85. As described above, 400 dpi data (see e in FIG. 5), which has been expanded twice horizontally, is passed to the printer 70 together with the clock output from the inverter 85 and the printer operation is started.

When the printing of one line is completed, the central processing unit 40 reads the data of the same content just outputted from the page memory 60 once more and outputs the data to the parallel / serial converter 81 to convert 400 dpi in the vertical direction. Will be realized. In other words, the doubling horizontally is performed by a clock of twice the frequency, and the doubling vertically is performed by the central processing unit 40 on the bottle / serial converter 81 of the same line twice. This is done by writing.

The vertical expansion process will be described in detail with reference to FIG. 6. In step (1), the central processing unit 40 first checks whether the printer 70 is in a good state. If the check result is not good, go to step (10) to perform a printer status check operation. On the other hand, when the printer 70 is found to be in good condition, the process proceeds to step (2) to reset the line counter and then sets the print memory address in step (3). After performing step (3), the process proceeds to step (4) to increase the line counter, then to increase the address in step (5) and to transmit the print data in step (6). That is, data to be printed from the page memory 60 is read out from the page memory 60 and written to the serial-to-serial converter 81. Then, the shift register 83 shifts one line of data to be transferred to the printer 70. do. Therefore, in step (7), it is checked whether the transmission is completed for one line, and if it is not completed, looping to step (5) and repeating the above-described operation process to transmit all data for one line. In this way, when it is found that data transmission for one line is completed, the process proceeds to step (8) to check whether the line counter is '2'. If the check result indicates that the line counter is not '2', looping is performed in step (3) to repeat the above-described operation. If the line counter is '2', two data transmissions are performed for the same line. As it means that it has been executed, go to step (9) and check whether data transmission work for one page is completed. As a result of the check, when the data transmission for one page is completed, the operation is terminated. If the data transmission for one page is not completed, the operation is repeated in step (2) to repeat the data transmission operation for the next line as described above. Perform.

As described above, the dot-per-inch conversion is implemented in hardware to reduce the memory capacity, thereby increasing the reliability and reducing the cost and size of the system.

Claims (3)

A fax having a page memory means for storing one page of data and a printer means having a recording resolution of N times the read resolution, wherein the pixel data read from the page memory means is synchronized with a predetermined first clock. Bottle / serial conversion means for bottle / serial conversion, and shift for transferring the serialized data to the printer means by shifting line by line in synchronization with a second clock having a frequency N times that of the first clock. Means and a control means for reading the same line N times from said page memory means and transferring it to said parallel / serial conversion means. A facsimile comprising a page memory means for storing one page of data and a printer means having a recording resolution of twice the read resolution, wherein the pixel data read from the page memory means is synchronized with a predetermined first clock. Bottle / serial conversion means for bottle / serial conversion, and shift for transferring the serialized data to the printer means by shifting line by line in synchronization with a second clock having twice the frequency of the first clock Means and a control means for reading the same line twice from said page memory means and transferring it to said parallel / serial conversion means. In a fax having a page circuit 60 and a printer 70 whose recording resolution is twice the read resolution, a parallel / serial converter for serially inputting and outputting the pixel data read out from the page memory 60 in parallel ( 81), a divider 82 for controlling the output synchronization of the bottle / serial converter 81 by dividing the predetermined first clock CLK by two, and inverting the first clock CLK. The printer 70 stores the inverter 85 applied to the printer 70 and the output of the bottle / serial converter 81 line by line, and synchronizes with the clock output from the inverter 85. And a central processing unit 40 for projecting the same line twice from the page memory 60 and transferring the same line twice from the page memory 60 to the bottle / serial converter 81. Inch conversion circuit.

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